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Marine Act 1986 - Marine (Fiji Maritime Code) Regulations 1990

FIJI

MARINE ACT, 1986
(Act No. 35 of 1986)

Legal Notice 83

MARINE (FIJI MARITIME CODE) REGULATIONS, 1990

IN exercise of the powers conferred upon me by sections 94, 143 and 212 of the Marine Act, 1986, I have made the following Regulations.

Citations

1.-(1) These Regulations may be cited as the Marine (Fiji Maritime Code) Regulations, 1990.

(2) The Code set out in the Schedule may be cited as the Fiji Maritime Code.

Purpose

2.-(1) The purpose of these Regulations is to set out in one document, called the Fiji Maritime Code, details of the law relating to safety of vessels (covered by Part IV of the Marine Act), and to give legal force to those provisions of that Code that do not otherwise have that force by virtue of the Marine Act, 1986 or regulations made under that Act.

(2) Parts IV and V of the Marine Act, 1986 do not apply to vessels that are less than 10 metres in length (details of the law relating to these vessels are contained in the Fiji Small Craft Code).

Fiji Maritime Code given force of law

3. Except to the extent that any provision of the Fiji Maritime Code -

(a) has the force of law by virtue of the Marine Act, 1986 or any other regulation made under that Act; or

(b) is inconsistent with any provision of the Marine Act, 1986 or any regulation made under that Act,

the provisions of the Fiji Maritime Code have the force of law.

Prescribed surveys and inspections

4.-(1) This regulation applies to vessels -

(a) to which Part IV of the Marine Act, No. 1986 applies; and

(b) which are registered or which upon completion of construction will be registered; and

(c) which are not, or upon completion of construction will not be Safety Convention ships.

(2) For the purpose of section 62 of the Marine Act, 1986 the prescribed surveys and inspections in respect of a vessel to which this regulation applies are those specified in section 14 of the Fiji Maritime Code.

Emergency procedures and safety navigation

5. A person must not fail to comply with an obligation or duty imposed upon him by virtue of section 15 of the Fiji Maritime Code.

Penalty: A fine not exceeding $2000.

Dated at Suva this 26th day of July 1990.

A.V. TORA

Minister for Infrastructure

Public Utilities

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SCHEDULE

THE FIJI MARITIME CODE

Arrangement of sections

Section 1 - Introduction, definitions and general requirements
Section 2 - Certificates of Competency
Section 3 - Safety Manning
Section 4 - Mercantile Marine
Section 5 - Construction and stability
Section 6 - Crew accommodation
Section 7 - Load lines
Section 8 - Tonnage measurement
Section 9 - Engineering
Section 10 - Life-saving appliances
Section 11 - Fire appliances
Section 12 - Radio equipment
Section 13 - Miscellaneous equipment
Section 14 - Surveys and Certificates of Survey
Section 15 - Emergency procedures and safety of navigation

SECTION 1

INTRODUCTION, DEFINITIONS AND GENERAL REQUIREMENTS

This Section is divided into five Parts as follows:

Part 1: Preliminary

Part 2: Definitions

Part 3: Operational Areas and Classification of Vessels

Part 4: General

Part 5: Submission of Information

PART 1 - PRELIMINARY

1. For convenience of presentation and application this Code is produced in Sections, each dealing with an appropriate area of control. Each Section shall always be read in conjunction with this Section_____ "Introduction, Definitions and General Requirements" and such other Section or Sections to which a special reference may be made.

2. These Uniform Requirements shall apply to all new vessels and except when otherwise specified in a Section, to all existing vessels as far as is considered reasonable and practicable by the Fiji Marine Board.

PART 2 - DEFINITIONS

Terms defined in Section 5 of the Marine Act 1986 shall apply in the Uniform Requirements. Although some of the terms are repeated or further clarified in these Uniform Requirements for convenience of reference, the definition in the Act takes preference.

3. The definitions set out in clause 4 of this Section shall have the meaning when used in reference to any Section of these Uniform Requirements unless the contrary intention appears.

4. The following terms shall have the meanings set against them respectively:

Accommodation Space - Passenger spaces, corridors, lavatories, cabins, offices, crew spaces, shops, isolated pantries and lockers and similar spaces.

Approved - Approved by the Fiji Marine Board.

"Australian Uniform Shipping Laws Code" - The Australian Transport Advisory Council Uniform Shipping Laws Code (amended to 1 August 1984) Published by the Australian Government Publishing Service Canberra.

Authorised - Authorised by the Fiji Marine Board.

Authority - The Fiji Marine Board, unless stated otherwise in the text.

Approved Society or Authorised Society - An Approved Classification Society as listed in Appendix II of Section 14.

Breadth - The maximum breadth measured amidships

(i) in the case of a metal hull - to the moulded line of the frame;

(ii) in the case of any other hull - to the outer surface of the hull.

Cargo Space - All spaces appropriated for cargo including trunks leading to such spaces.

Classed Vessel - A vessel in respect of which there is in force a Classification Certificate.

Classification Certificate - A certificate issued by a Classification Society which records the classification accorded to a vessel by that society.

Classification Society - An association approved for the survey of vessels.

Commercial Vessel - A Vessel which is not used solely for pleasure or recreation and the use of which is made, allowed or authorised in the course of any business or in connection with any commercial transaction.

Control Station - Includes those spaces in which the vessel’s radio or main navigating equipment or the emergency source of power is located or where the fire recording or fire control equipment is centralised.

Crew Accommodation or Crew Space - In relation to a vessel means such parts of the vessel as are set aside for the exclusive use of the Crew.

Depth - The moulded depth measured at the middle of the measured length from the base line to the top of the freeboard deck beams at the side of the vessel.

For the purposes of this definition, the baseline is the line projected by the plane forming the top of the keel where a plate keel is fitted. In the case of a timber or composite vessel, the top of the keel shall be read as a reference to the lower edge of the keel rabbet.

In the case of a vessel which has a bar keel or in which the format the lower part of the midship section is of a hollow character, or thick garboards are fitted, the top of the keel shall be read as a reference to the point where the flat of the bottom continued inward cuts the side of the keel of the vessel.

In each case the plane shall be horizontal when extended transversely.

Examiner - A person appointed by the Fiji Marine Board to conduct examinations of the kinds specified by the Fiji Marine Board.

Existing Vessel - A vessel which is not a new vessel.

Fishing Vessel-A vessel that is, or is, intended to be, used wholly or principally for the catching or taking of Marine Organisms but does not include a vessel that is, or is, intended to be, used wholly or principally -

(a) in the harvesting or transporting of algae or aquatic plants; or

(b) as a carrier or mother vessel.

ISO - The International Organisation for Standardization, 1, Rue de Varambe, CH-1211 Geneva, 20, SWITZERLAND.

Measured Length - The distance from the fore part of the hull to the after part of the hull, taken at the upper side of the uppermost weathertight deck or, in the case of open vessels, at the height of the gunwale.

NOTE:

A clarification of certain terms used in the definition of Measured Length is contained in Appendix A of this Section.

Master - A person having command or charge of a vessel, but does not include a pilot.

Nautical Mile - The International nautical mile of 1852 metres.

New Vessel - A vessel -

(a) the keel of which was laid or which was at a similar stage of construction; or

(b) that has been substantially -

(i) altered; or

(ii) reconstructed,

on or after the coming into force of the applicable provisions.

Open Vessel - A vessel which has no weather tight deck for the whole or part of the length of the vessel e.g. a rowing boat with open bottom boards or a half cabin vessel with a cockpit aft fitted with loose deck panels.

Owner - In relation to a vessel means any person exercising or discharging or claiming the right or accepting the obligation to exercise or discharge any of the power or duties of an owner whether on his own behalf or on behalf of another and includes a person who is the owner jointly with any other person or persons and the manager or secretary of any body corporate or company.

Passenger - A person carried on board with the knowledge or consent of the owner or master of the vessel but does not include -

(a) a person engaged in any capacity on board the vessel in the business of the vessel; or

(b) a child under the age of one year.

Passenger Vessel - A vessel engaged in International voyages which carries more than twelve passengers.

Proper Officer - A person appointed under Section 18 of the Marine Act 1986 to be a proper officer.

Radio Surveyor - A person appointed by the Ministry of Information.

Service Space - Spaces used for galleys, main pantries, stores (except isolated pantries and lockers), mail and special rooms, workshops other than those forming part of the machinery spaces and trunks to such spaces.

SOLAS - In respect of an item or appliance means that the item or appliance shall comply with the requirements of the SAFETY CONVENTION, taking into account the date on which the vessel’s keel was laid or was at a similar stage of construction.

Special Personnel - All able bodied persons having some knowledge of safety procedures and handling of safety equipment on board who are not directly - or indirectly - paying passengers, carried on board a vessel in connection with the special purpose of the vessel, or because of the need to be on board because of special work being carried out on the vessel, and who are not members of the crew engaged in navigation, engineering or maintenance of the vessel or attached to the vessel to provide services for other persons on board.

Standards Abbreviations -

A.S. refers to the Australian Standard.

ASTM refers to the American Standard for Testing Materials.

ALPGA refers to the Australian Liquified Petroleum Gas Association.

Superstructure - A decked structure, including a raised quarter deck, on the freeboard deck extending from side to side of the vessel or with the side plating of the structure not being inboard of the shell plating by more than 4 per cent of the breadth of the vessel.

Where, in pursuance of the above, a lower deck is specified as the freeboard deck of a vessel, any part of the hull which extends above the deck so specified shall be deemed to be a superstructure.

Surveyor - A person appointed by the Minister to be a surveyor.

Tanker - A cargo vessel constructed or adapted for the carriage of bulk fluid cargoes.

Tons - In relation to the grading of vessels means gross tonnage.

Unclassed Vessel - A vessel that is not a "Classed Vessel"

Unmanned Machinery Space - A decked propulsion machinery space which under normal operating conditions is not occupied or is intermittently occupied.

Vessel - Any ship or boat or any other description of vessel used in navigation by water.

PART 3 - OPERATIONAL AREAS AND CLASSIFICATION OF VESSELS

5. Operational Areas shall apply to appropriate Sections of these Requirements as follows:

5.1 International Voyage means a voyage -

(a) from a port or place in Fiji to a port or place outside Fiji;

(b) from a port or place outside Fiji to a port or place in Fiji; or

(c) from a port or place outside Fiji to another port or place outside Fiji.

5.2 Pacific Region Trade, in respect of a vessel, means the operation of the vessel within the area delineated by Latitudes 15 degrees North to 47 degrees South and Longitudes 130 degrees East to 130 degrees West.

5.3 Restricted Pacific Trade, in respect of a vessel, means the operation of the vessel on voyages between the island of Rotuma and another port or place in Fiji.

5.4 Fiji Islands Trade, in respect of a vessel, means the operation of the vessel between any two ports or places in Fiji (except Rotuma) beyond the protection of the reefs.

5.5 Seagoing Service, in respect of a vessel, means the operation of the vessel beyond the protection of the reefs, and in respect of seamen, means service on a vessel engaged upon such operations.

5.6 Short Coasting Service, in respect of a vessel, means the operation of the vessel generally within the protection of the land or reefs in the areas specified in Appendix 8, and as may be further restricted in respect of a Certificate of Competency by endorsement on that Certificate.

5.7 Harbours and Rivers Service, in respect of a vessel, means the operation of the vessel entirely within harbour or river limits where the waters are entirely protected and smooth.

6. Classification of vessels shall apply to all Sections of these Requirements as follows:

6.1

Class 1..................Passenger vessels engaged on International Voyages.

6.2

Class 2...................Non-Passenger vessels engaged on International Voyages.

Class 2A................Non-Passenger vessels of 500 GT and over engaged on International Voyages

Class 2B................Non-Passenger vessels of less than 500 GT engaged on International Voyages.

6.3

Class 3...................Vessels other than vessels engaged on International Voyages.

Class 3A.............Vessels engaged in the Restricted Pacific Trade.

Class 3B.............Vessels engaged in the Fiji Islands Trade.

Class 3C................Vessels engaged in the Sea Going Service.

Class 3D................Vessels engaged in the Short Coasting Service.

Class 3E................Vessels engaged in the Harbours & Rivers Service.

7. Vessels Limited by Manning.

7.1 A vessel of any class may be subject to a restricted area of operations if the manning or the qualifications of the personnel are insufficient for the area of operations allowed by its certificate of survey.

PART 4-GENERAL

8. Exemption and Equivalents

8.1 The Fiji Marine Board may, subject to the principles embodied in these Requirements, exempt a vessel, or vessels included in a specified class of vessel, from the application of any of the provisions of these Requirements to the extent that the Fiji Marine Board is satisfied that compliance with such provision or provisions is unreasonable or impracticable in relation to that vessel or those vessels.

8.2 Where these Requirements provide that a particular fitting, material, appliance or apparatus, or type thereof, shall be fitted or carried in a vessel or that any particular provision shall be made, the Fiji Marine Board may allow any other fitting, material, appliance or apparatus, or type thereof, to be fitted or carried, or any other provision to be made to that vessel, if it is satisfied by trial thereof, or otherwise, that such fitting, material, appliance or apparatus, or type thereof, or provision, is at least as effective as that required by these Requirements.

8.3 The Fiji Marine Board will exercise its power under this clause only after receipt of a written application from the owner of the vessel, or the owner of a vessel in the specified class of vessel, which sets out the grounds of the application and which is supported by such evidence as the Fiji Marine Board may, at or after the time of application, require in order to enable it adequately to investigate the application.

8.4 The Fiji Marine Board may grant an exemption or make an allowance under this clause upon such conditions as it thinks fit.

9. Requirements not otherwise Specified

9.1 Where in case of a vessel provision is not made in these Requirements to cover a specific matter, the Fiji Marine Board may determine what special provisions shall apply to that matter.

10. Sufficiency of Machinery, Equipment and Components

10.1 In any respect in which detailed requirements or specifications are not laid down or determined by the Fiji Marine Board for specific items, such items shall be sufficient for the intended service, and conform to good marine practice.

11. Positioning of Equipment.

11.1 Items of equipment required by these Requirements shall be positioned to the satisfaction of the surveyor.

12. Materials

12.1. All materials shall be of a good quality conforming to good marine practice and free from defects and when required materials must be covered by test certificates issued by an approved authority or Standards Institute. The cost of any tests required for the materials shall be borne by the owner.

13. Workmanship

13.1 Manufacture and construction shall conform to good marine practice. The Fiji Marine Board may require any item not in accordance with the approved plans and specifications, or any material, workmanship, or arrangement that is deficient to be rectified.

PART 5 - SUBMISSION OF INFORMATION

14. Preliminary Information, Plans and Specifications to be Submitted.

14.1 When a vessel is to be built or an existing vessel is to be purchased or substantially altered and any doubt exists as to whether these Requirements shall apply or which certificates will be required, the office of the Fiji Marine Board should be contacted, by the owner or intending owner, as soon as possible. The basic information necessary for initial assessment by the Fiji Marine Board is as follows:

(a) Vessel Identification, e.g. name or construction number if any;

(b) Name of owner or intending owner;

(c) Hull construction material;

(d) Principal dimensions: of vessel,

(e) Nature of the service in which the vessel will be engaged;

(f) Intended area of operations of the vessel;

(g) Gross tonnage(s) or estimated lower and upper limits of gross tonnage(s);

(h) Whether the vessel is to be classed or is classed and if so the name of the Classification Society and details of the Classification;

(i) Whether the vessel will hold or holds a Load Line Certificate and/or Cargo Ship Safety Construction Certificate issued by a Classification Society; and

(j) Whether the vessel, being an existing vessel, holds any other certificates relating to survey and if so the type of each certificate, its date of expiry and the name of the authority who issued the certificate.

14.2 When a vessel is to be built or an existing vessel is to be purchased, chartered or substantially altered for operations within the jurisdiction of the Fiji Marine Board the owner, or intending owner, shall comply with the requirements of the Survey and Certificates of Survey Section and, to ensure that the requirements of other appropriate Sections relating to the construction, equipment and outfitting of that vessel shall be met, submit appropriate information, plans and data to the Fiji Marine Board for assessment and approval.

14.2.1 The information submitted shall be in accordance with the following:

(a) Information must be sufficient in detail to ensure that all the relevant requirements have been incorporated in the design. Extraneous and irrelevant information should be omitted where practicable. Written material shall be submitted in the English language;

(b) Where any doubt exists, as to the information required to be submitted, clarification should be sought from the Fiji Marine Board;

(c) Print outs should be clear, easy to read and properly identified;

(d) The number of copies submitted shall be sufficient to permit the retention of two by the Fiji Marine Board;

(e) Where a design is amended, subsequent to the initial submission, every plan, specification, etc. affected by the alteration, shall be amended accordingly and the date of amendment recorded. As necessary revised copies shall be forwarded immediately to the Fiji Marine Board;

(f) Drawings and plans should be submitted according to one or more of the following scales: 1:1, 1:2, 1:5, or multiples of 10 thereof.

14.2.2. The extent of the information to be submitted will be dependent on classification and size of the vessel. The following may be used as a general guide:

(a) all the information nominated in sub-clause 14.1 unless such information has previously been submitted in accordance with that sub-clause;

(b) the general arrangement plans;

(c) the construction plans, including transverse and longitudinal section;

(d) the lines plan;

(e) plans, specifications or data sheets to cover;

(i) the scantlings of all members, including methods of fastening;

(ii) the details of the closing devices;

(iii) the bilge pumping arrangements;

(iv) the details of the oil fuel system, including tanks, filling and venting arrangements, piping and valves;

(v) where applicable, the arrangements for the loading, carriage and discharge of liquid cargoes;

(vi) the structural fire, protection arrangements and fixed fire appliances;

(vii) the details of the rudder and stern frame, propeller brackets, engine and thrust seating, propeller shafting, bearings and couplings, steering gear and alternative method of steering;

(viii) where applicable; the welding schedule, the laminating schedule or the plastering programme;

(ix) electrical equipment and wiring.

(f) the preliminary stability information; and

(g) such further plans, information and data as the Fiji Marine Board may require to determine the proper construction, machinery, equipment and safety of the vessel.

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APPENDIX A

CLARIFICATION OF TERMS USED IN DEFINITION OF MEASURED LENGTH
(as referred to in Clause 4)

The following terms used in the definition of Measured Length should be interpreted as follows:

Fore part of hull – The leading edge of the shell plating or other structural material or, in the case of bar steams or stem posts, the intersection of the outside of the shell plating or planking with the stem bar or post but, in all cases, excluding any member added to the exterior of the hull e.g. fender, sponson, rubbing strips, etc.

After part of the hull – The trailing edge of the shell plating, planking or other structural material or, in the case of stern bars or posts, the intersection of the outside of the shell plating or planking with the stern bar or post but, in all cases, excluding any member added to the exterior of the hull, e.g. fender, sponson, rubbing strip, etc.

Height of gunwale – The top edge of the fore and after member which is fitted round the inside of the vessel at the top of the side shell plating, planking or other structural material.

As a further guide to the interpretation of Measured Length reference should be made to the Guidance for Measuring Diagrams included in this appendix.

Section 1

MEASURED LENGTH

GUIDANCE FOR MEASURING – SHEET 1

FORE PART OF HULL

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 2

AFTER PART OF HULL

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 3

AFTER PART OF HULL (Cont.)

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 4

SINGLE DECK VESSELS

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 5

MULTIPLE DECK VESSELS

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 6

LANDING BARGES, ETC

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OPEN VESSELS

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MEASURED LENGTH
GUIDANCE FOR MEASURING – SHEET 7

MEASURING ON EXISTING VESSEL

Measurement should, wherever possible, to be taken in a direct line between the two defined extremities.

On an existing vessel this would normally be achieved by setting up sight boards at the stem and stern, together with as many intermediate sights as are necessary to circumvent obstructions or breaks in the uppermost weather tight deck or if the vessel is out of the water, by measuring between plumb lines dropped from the defined extremities, in which case, care should be taken to ensure that the measurement is taken between points on the plumb lines which are equidistant from the points of origin (i.e. the top of deck or gunwale).

However, the measurement could be taken, when agreed to by the Authority and the owner, by means of a tape laid along the deck or decks. It is a fact that the measurement thus taken will be in excess of the true measurement thus taken will be in excess of the true measurement due to the curvature of the deck, as illustrated in the sketch below where the sheer of the deck has been exaggerated for clarity. In most cases this increase in length will be of little concern, however, if the measurement is critical, the length should be checked by either of the two methods described above.

MEASUREMENT OF LENGTH (L_m) BY TAPE LAID ON DECK

Note: Sheer exaggerated for clarity.

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APPENDIX B

BOUNDARIES OF SHORT COASTING SERVICE AREAS

1. VITI LEVU

The sea area bounded on the landward side by the main island and, on the seaward side by the inside edge of:

1.1 Suva Harbour outer reef to Nukulau Island to the Rewa River.

1.2 Tomberua Passage to Moturiki, then the East and North Coasts of Ovalau to Levuka.

1.3 North Coast of Levuka along the 100 fathom contour to Nananu Passage to Manava Passage to Ba Passage.

1.4 The reef from Ba Passage to Vomo Island then a straight line to the Northern most of the Mamanuca Islands, the Mamanuca Reefs, the Malolo Barrier Reef to Navula Reef Light, to Uverite Point.

1.5 Serua Harbour to Beqa Reef to Navua River.

2. VANUA LEVU

The sea area bounded on the landward side by the main land and, on the seaward side by the inside edge of:

2.1 The 100 fathom line of the Somosomo Strait and the Rabi Channel, the Texas Reef then a straight line on a bearing of 260 degrees True, to the main land.

2.2 The reef from Udu Point to Sausau Passage, to Mali Passage, to Kia Island to Yaggaga Island, then within 1 mile of the main land to Bua Bay, then a straight line to Vuya Passage of the Namena Barrier Reef, then following the Namena Barrier Reef to Nasonisoni Passage to Nyavu Passage.

2.3. Savusavu Bay.

3. TAVEUNI

The sea area bounded on the landward side by the main island and, on the seaward side by the 100 fathom line from Vuna Reef Light to Black Point, then a line 1 mile from the reef to north end of Taveuni, then to the inside of the reef surrounding the Laucala Island only.

4. VANUA LEVU TO TAVEUNI

A two mile wide sea area at the narrowest point of the Somosomo Strait between the two sea areas defined in 2 and 3 above.

NOTE: There is no Short Coasting Service area joining VITI LEVU to VANUA LEVU, SUVA to BEQA, or SAVUSAVU Eastwards to SOMOSOMO.

SECTION 2

CERTIFICATE OF COMPETENCY

1. This Section should be read in conjunction with the Introduction, Definition and General Requirements Section.

2. Full details of the Certificates of Competency requirements are contained in the Marine (Certificates of Competency and Manning of Vessels) Regulations, 1989. These Regulations are made up of a number of other Regulations.

3. Regulations 5 to 20 of the Marine (Certificates of Competency and Manning of Vessels) (General) Regulations, 1989, which are set out in the Schedule to this Section, describe the general scheme and indicate the function of each subsidiary set of Regulations so that a person interested in acquiring a Certificate of Competency may know which Regulations he needs to refer to.

4. The Certificates of Competency required in respect of fishing vessels can be found in the Marine (Fishing Vessels-Certificates of Competency and Manning of Vessels) Regulations, 1989.

SCHEDULE

Regulations 5 to 20 of the Marine (Certificates of Competency and Manning of Vessels) (General) Regulations, 1989

Grades of certificates of competency which may be issued

5. The Marine Board may, under subsection 99(3) of the Act, issue certificates of competency in the following grades, namely-

(a) in respect of deck officers-

(i) Grade 1 Master;

(ii) Grade 2 Master;

(iii) Grade 3 Master;

(iv) Grade 4 Master,

(v) Grade 5 Master,

(vi) Grade 1 Mate,

(vii) Grade 2 Mate;

(viii) Grade 3 Mate;

(ix) Grade 4 Mate;

(x) Grade 5 Mate;

(xi) Sailing Licence (Seagoing Service);

(xii) Sailing Licence (Short Coasting Service);

(xiii) Sailing Licence (Harbour and River Craft);

(b) in respect of engineering officers-

(i) Engineer Grade 1;

(ii) Engineer Grade 2,

(iii) Engineer Grade 3,

(iv) Engineer Grade 4;

(v) Engineer Grade 5,

(vi) Engine Operator;

(c) in respect of ratings-

(i) Deck Watchkeeping Rating Certificate;

(ii) Able Seaman Certificate;

(iii) Engine Room Watchkeeping Rating Certificate.

Marine Board not to issue certificates of competency except to qualified persons

6.-(1) The Marine Board shall not issue a certificate of competency to an applicant unless it first satisfies itself that-

(a) the applicant has passed any appropriate examination leading to a qualification for the grade of certificate applied for; and

(b) the applicant has successfully completed any supplementary courses appropriate to that grade of certificate.

(2) The appropriate examination loading to a qualification for each grade of certificate of competency that must be passed for the purpose of paragraph (1) (a), and the syllabuses in respect of each of those examinations are prescribed-

(a) in respect of deck officers-in the Marine (Certificates of Competency (Examinations Syllabuses) (Deck Officers)) Regulations, 1989;

(b) in respect of engineering officers-in the Marine (Certificates of Competency (Examination Syllabuses) (Engineering Officers)) Regulations, 1989; and

(c) in respect of ratings-in the Marine (Certificates of Competency (Required Qualifications) (Ratings)) Regulations, 1989.

(3) The appropriate supplementary courses that must be successfully completed for the purposes of paragraph (1)(b) before a grade of certificate of competency may be applied for, and the aims and scopes of those courses are prescribed in the Marine (Certificates of Competency (Supplementary Courses)) Regulations, 1989.

Conduct of examinations for certificates of competency

7.-(1) The Marine Board may conduct, or approve the conduct of, examinations leading to qualifications for each grade of certificate of competency.

(2) The examinations referred to in sub regulation (1) shall be conducted in the manner prescribed in the Marine (Certificates of Competency (Conduct of Examinations)) Regulations, 1989.

Conditions of entry to examinations for certificates of competency

8.-(1) The Marine Board shall not permit a person to enter for an examination leading to a qualification for a grade of certificate of competency unless it first satisfies itself that the applicant has the qualifications and has satisfied the other prerequisite prescribed in respect of that examination.

(2) The qualifications and prerequisite referred to in sub regulation (1) are prescribed-

(a) in respect of deck officers-in the Marine (Certificates of Competency (Qualifications for Entry to Examinations) (Deck Officers)) Regulations, 1989;

(b) in respect of engineering officers-in the Marine (Certificates of Competency

(Qualifications for Entry to Examinations) (Engineering Officers)) Regulations, 1989; and

(c) in respect of ratings-in the Marine (Certificates of Competency) (Required Qualifications) (Ratings)) Regulations, 1989.

Examination fees

9. The fees to be paid by candidates to enter for an examination leading to a qualification for the various grades of certificates of competency are prescribed in the Marine (Fees) Regulations, 1989.

Application for certificate of competency

10. The prescribed application form for a certificate of competency is the form specified in Schedule 1.

Application fee for a certificate of competency

11.-(1) The prescribed application fee for a certificate of competency is prescribed in the Marine (Fees) Regulations, 1989.

(2) The fee prescribed under sub regulation (1) shall also apply in respect of a document issued under sub regulation 13(2).

Any lower grade certificate of competency to be surrendered

12.-(1) Where an applicant for a certificate of competency is already the holder of a lower grade certificate of competency he shall surrender that lower grade certificate to the Marine Board on the issue to him by the Board of the Higher grade certificate.

(2) The Marine Board may refuse to issue a certificate of competency to a person who fails to comply with sub regulation (1).

Marine Board may decline to issue certificates of competency to certain people

13.-(1) where an application for a certificate of competency is made by a person who is neither a citizen of Fiji nor of any other country which is a member of the South Pacific Forum it may decline to issue the certificate applied for.

(2) Where the marine Board, acting in accordance with sub regulation (1), declines to issue a certificate of competency to a person who would otherwise be entitled to the issue of that certificate the Board shall instead issue that person with a document, in a form approved by the Marine Board, certifying the examination results of the applicant in respect of any examination which the applicant sat and which would otherwise have led to a qualification for a certificate of competency.

(3) A document issued under sub regulation (2) shall, as far as practicable, be in such form as to satisfy the reasonable requirements of the appropriate authorities in the applicant’s home country.

Form of certificate of competency

14.-(1) A certificate of competency shall be in the form specified in Part 1-of Schedule 2.

(2) A certificate of competency shall bear an endorsement in the form specified in Part 2 of Schedule 2.

(3) A certificate of competency shall bear a certificate in the form specified in Part 3 of Schedule 2.

(4) A certificate of competency shall state its period of validity and shall contain spaces where endorsements revalidating the certificate may be entered.

(5) A certificate of competency shall contain spaces in which endorsements certifying that the holder of the certificate has obtained further qualification may be entered.

(6) A certificate of competency shall contain spaces in which any limitation on or exceptions to the certificate may be endorsed

(7) Details of revalidation under subregulation (4) or endorsements under sub-regulations (5) and (6) may be made in writing, by rubber stamp, printed slip or similar method and shall be certified by or on behalf of the Marine Board.

Capacities that holders of certificates of competency may serve in on a registered vessel

15. The capacities that the holders of each grade of certificate of competency may serve in on a registered vessel are set out in the Marine (Certificates of Competency (Authorised Capacities)) Regulations, 1989.

Manning requirements on registered vessels

16. For the purpose of subsection 98(1) of the Act, the manning requirements in respect of a registered vessel shall be determined in accordance with the Marine (Manning of Vessels) Regulations, 1989.

Additional requirements in respect of tankers

17. The Marine (Certificates of Competency (Tankers and Dangerous Cargoes)) Regulations, 1989-

(a) specify that the holders of certain positions of responsibility on an oil, chemical or gas tanker must hold additional qualifications; and

(b) specify how those qualifications may be obtained.

Revalidation of certificates of competency

18.-(1) A certificate of competency is valid for seagoing purposes until the date specified in it but may be revalidated for these purposes.

(2) The Marine Board shall not validate a certificate of competency for seagoing purposes for a period exceeding 5 years, nor shall it revalidate a certificate of competency for seagoing purposes for a period exceeding 5 years.

(3) The manner in which a certificate of competency may be revalidated for seagoing purposes and any requirements to be complied with on that revalidation are prescribed in the Marine (Certificate of Competency (Revalidation)) Regulations, 1989.

Transitional provision

19. The Marine (Certificates of Competency (Transitional Provisions)) Regulations, 1989 provide-

(a) for the recognition of certificates of competency issued before these Regulations came into operation;

(b) for the continued issue of certificates of competency of the type issued before these Regulations came into operation where a seafarer’s training had been started under the previous system of training; and

(c) for the issue of certificates of service to persons who had seagoing experience but were not the holders of certificates of competency issued before these Regulations came into operation.

Review of decisions of Marine Board

20.-(1) A person aggrieved by a decision of the Marine Board in respect of the grant, endorsement or revalidation of a certificate of competency or service may apply to the Board for a review of the decision.

(2) An application for review under subregulation (1) must be accompanied by the fee prescribed by the Marine (Fees) Regulations, 1989.

(3) On receipt of an application under subregulation (1) the Marine Board shall refer it to a person or persons appointed by the Minister to hear reviews.

(4) The Marine Board shall give a person or the persons appointed in accordance with subregulation (3) all necessary details and assistance necessary to allow him or them to determine the review.

(5) The decision of a person or persons appointed in accordance with sub-regulation (3) on a review referred to him or them under that subregulation shall be deemed to be decision of the Marine Board and shall have effect accordingly.

(6) A person or persons appointed under subregulation (3) may, where appropriate, be a person or include a person with experience in the relevant field of knowledge or experience.

SECTION 3

SAFETY MANNING

1. This Section should be read in conjunction with the Introduction, Definitions and General Requirements Section.

2. Full details of safety manning requirements are contained in the Marine (Manning of Vessels) Regulations, 1989. This Section describes the principal provisions of those regulations for the general guidance of owners, masters and seamen. A number in brackets refers to the regulation number of the relevant regulation.

3. (4) Safety manning regulations apply to registered vessels including fishing vessels, Government vessels, and trading vessels any of which are 10 metres or more in length.

4. (6) The vessel must display a “Manning certificate” issued by the Marine Board, stating the minimum number of qualified and other persons to be carried.

5. (7) The owner of a vessel must apply to the Marine Board for the issue of a Manning Certificate in respect of the vessel. The Marine Board must refer the application to the Manning Committee.

6. (10) The Manning Committee consists of-

the Director of Marine;

a deck officer (a public officer administering the Act);

an engineering officer (a public officer administering the Act);

a deck officer (with extensive seagoing commercial ship experience); and an engineering officer (with extensive seagoing commercial ship experience).

7.(14) In deciding the minimum safety manning requirements of the vessel the Committee is guided by IMO Resolution A 481(XII) Principles of Safe Manning, and the manning tables Parts 1 to 4 set out in the Schedule to this Section.

8. (18) Dispensations from the manning scale may be issued only in cases of exceptional necessity, and. only after careful consideration by The Marine Board.

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SCHEDULE

This Schedule prescribes the minimum grade of certificate of competency required for the respective position on vessels to which the Regulations apply, for vessels engaged in the relevant operations.

______

PART 1

Deck officers

UNLIMITED TRADE

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PART 3

Ratings

A. Able Seamen (AB) and Deck Watchkeeping Rating (DW)

B. Engineeroom Watchkeeping Rating (EW)

C. Qualified Cooks

A qualified cook means a person who holds a Certificate of Approved Trade Test for Cooks Class 3 issued by the Fiji National Training Council, or an equivalent Certificate approved by the Marine Board.

HARBOURS, RIVERS, SHORT COASTING
AND SEA GOING SERVICE

______

PART 2
Engineering Officers

Unlimited Trade

PACIFIC REGION TRADE

FIJI ISLANDS TRADE

SECTION 4

MERCANTILE MARINE

1. This Section should be read in conjunction with the Introduction, Definitions and General Requirements Section.

2. Full details of Mercantile Marine requirements are contained in the Marine (Masters and Seamen) Regulations, 1989. This section describes the principal provisions of those regulations for the general guidance of masters and seamen. A number in brackets refers to the regulation number of the relevant regulation.

SECTION 5

CONSTRUCTION AND STABILITY

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PART 1 - PRELIMINARY

This Section should be read in conjunction with the Introduction, Definitions and General Requirements Section.

In this Section:

(a) the provisions of Part 2 apply to all ships;

(b) the provisions, of Part 3 apply to Safety Convention ships; and

(c) the provisions of Part 4 and Part 5 apply to ships other than Safety Convention ships.

PART 2 - GENERAL REQUIREMENTS FOR VESSELS

2.1 Structural Strength

2.1.1 Subject to particular requirements in this Section, the structural strength of every vessel shall be sufficient for the service for which the vessel is intended.
.

2.1.2 A vessel constructed in accordance with the appropriate rules of a Classification Society or with the appropriate provisions of this Part shall be accepted as complying with 2.1.1 of this Part.

2.1.3 The structural requirements for a vessel of unusual design shall be to the satisfaction of the Fiji Marine Board.

2.1.4 The structural requirements for a vessel constructed wholly or partly of materials not specifically included in requirements referred to in 2.1.2 of this Part shall be to the satisfaction of the Fiji Marine Board. In determining structural requirements not otherwise specified, regard shall be had to the following Sub-Sections of Section 5 of the Australian Uniform Shipping Laws Code;

Sub-Section H-Aluminium

Sub-Section I-Copper Nickel

Sub-Section J-Ferro-Cement

Sub-Section K-Glass Reinforced Plastic

Sub-Section L-Steel

Sub-Section M-Timber

2.2 Design Loadings

For the purpose of paragraph 2.1.2 of this Part, where a vessel is not constructed in accordance with the rules of a Classification Society, then the structure shall be designed to the satisfaction of the Fiji Marine Board and having regard to Part II of Sub-Section G, Section 5 of the Australian Uniform Shipping Laws Code.

2.3 Anchors and Cables

2.3.1 Equipment to be provided

Every vessel shall be provided with anchor equipment designed for quick and safe operation which shall consist of anchors, cables, stoppers and a windlass or other arrangements for dropping and hoisting the anchor and for holding the vessel at anchor in all foreseeable service conditions.

2.3.2 Acceptable Equipment

For the purposes of paragraph 2.3.1, equipment shall comply with Section 13, Miscellaneous Equipment.

2.3.3 Anchor Windlass

Where requirements in respect of an anchor windlass are not otherwise provided under paragraph 2.3.2, the requirements of this paragraph shall be met as follows:

(a) The windlass shall be of sufficient power to lift each anchor and its full length of cable;

(b) Each cable lifter shall be fitted with a release coupling and a brake sufficient capacity for the safe stopping of anchors and cable when paying out,

(c) A windlass with brake engaged and release couplings disengaged shall be able to withstand a static pull of 45% of the required cable minimum breaking strength on all cable lifters simultaneously and without any brake slip;

(d) If a chain stopper is not fitted, a windlass shall be able to withstand a static pull equal to the minimum breaking strength of the cable without release of the cable.

(e) An adequate cover or seal shall be provided for each spurling pipe, to prevent flooding of the cable locker when the vessel is at sea.

PART 3-REQUIREMENTS FOR SAFETY CONVENTION SHIPS

3.1 Watertight Subdivision

The requirements for watertight subdivision of Safety Convention ships are dealt with under the relevant provisions of Chapter 11-1 of the Safety Convention with particular reference to Part 8 of that Chapter, (Subdivision and Stability).

3.2 Structural Fire Protection

The requirements for structural fire protection of Safety Convention ships are dealt with under the relevant provisions of Chapter 11-2 of the Safety Convention, with particular reference to the following Parts of that Chapter.

Part B-Fire Safety Measures for Passenger Ships;

Part C-Fire Safety Measures for Cargo Ships; and

Part D-Fire Safety Measures for Tankers

3.3 Stability

The requirements for stability for Safety Convention ships are dealt with under the relevant provisions of Chapter 11-1 of the Safety Convention with particular reference to the following Regulations of Part B of that Chapter:

Regulation 8 - Stability of Passenger Ships in Damaged Condition;

Regulation 9 - Ballasting of Passenger Ships;

Regulation 21 - Bilge Pumping Arrangements;

Regulation 22 - Stability information for passenger ships and cargo ships; and Regulation 23 - Damage Control Plans in Passenger Ships.

3.4 Rudders and Steering Gear

The requirements for the steering gear of Safety Convention ships are dealt with under the relevant provisions of Chapter 11-1 of the Safety Convention with particular reference to the following Regulations of Part C of that Chapter:

Regulation 29-Steering gear; and

Regulation 30-Additional requirements for electrical and electrohydraulic steering gear.

PART 4-REQUIREMENTS FOR SHIPS OTHER THEN SAFETY CONVENTION SHIPS

4.1 Watertight Subdivision

4.1.1 Bulkheads and other enclosures of watertight spaces and arrangements to maintain watertight integrity shall be designed, constructed and tested to the satisfaction of the Fiji Marine Board and having regard to the relevant provisions of Sub-Section C and D, Section 5, of the Australian Uniform Shipping Laws Code.

4.1.2 Every vessel shall be provided with an efficient system capable of pumping from or draining any watertight compartment not permanently appropriated for ship services and for which other efficient means of pumping are not provided. Arrangements of the system shall be to the satisfaction of the Fiji Marine Board, having regard to the provisions of Clause 17, Section 9, of the Australian Uniform Shipping Laws Code.

4.2 Structural Fire Protection

The hull, superstructure, structural bulkheads, decks, deckhouses and structural components below decks shall be so constructed as to provide the fullest practicable degree of fire protection to the satisfaction of the Fiji Marine Board and having regard to the relevant provisions of Sub-Section F, Section 5, of the Australian Uniform Shipping Laws Code.

4.3 Stability

4.3.1 A ship shall be so designed and constructed as to provide adequate intact stability for the anticipated service conditions which shall be determined according to criteria acceptable to the Fiji Marine Board.

4.3.2 Every ship shall at all times be provided with information acceptable to the Fiji Marine Board, relating to the ship’s stability characteristics under different service conditions.

4.3.3 In determining requirements under 4.3.1 and 4.3.2 regard shall be had to Section 8 of the Australian Uniform Shipping Laws Code.

4.4 Rudders and Steering gear

4.4.1 Every vessel shall be provided with a main steering gear and with an auxiliary means of actuating the rudder.

4.4.2 For the purposes of paragraph 4.4.1. the provisions shall be to the satisfaction of the Fiji Marine Board and having regard to the appropriate rules of a Classification Society and to the following clauses of Part 3, Section 9, of the Australian Uniform Shipping Laws Code.

Clause 21 - Steering Gear, and

Clause 22 - Rudders and Rudder Stocks.

PART 5 - MISCELLANEOUS PROVISIONS

5.1 Modifications for Existing Ships

In the case of a ship, other than a Safety Convention ship, that is an existing ship the Fiji Marine Board may permit such modifications to the requirements of this Part as it thinks, fit, having regard to:

(a) the age of the ship; and

(b) the trade in which the ship is, or is about to be, engaged.

SECTION 6

CREW ACCOMMODATION

1. This Section shall be read in conjunction with the Introduction, Definitions and General Requirements Section.

2. In this Section crew accommodation means the accommodation to be provided for the Master, Crew and Special Personnel.

3. Application.

3.1 This Section applies to vessels of 10 metres and over.

3.2 The Fiji Marine Board may not require compliance with any of the provisions of this Section on vessels which are normally engaged on voyages for period of less than 36 hours, or in which the crew is not required to reside on board.

3.3 In addition the conditions maybe varied in the case of any vessel if the Fiji Marine Board is satisfied after consultation with the vessel’s owners that the variations made provide corresponding advantages as a result of which the overall conditions are not less favourable than those that would result from the full application of the provisions of the Section.

4. General

4.1 The location, means of access, structure and arrangement of crew accommodation in relation to other spaces shall be such as to ensure adequate security and protection against weather, sea and undue noise.

4.2 There shall be no direct openings into sleeping rooms from fish or cargo holds and spaces, from machinery spaces, from galleys, lamp and paint rooms or from engine, deck and other bulk store rooms, drying rooms, communal wash places or water closet spaces. That part of the bulkhead separating such places from sleeping rooms and external bulkheads shall be constructed of approved material and shall be watertight and gastight.

4.3 External bulkheads of sleeping rooms and mess rooms shall be adequately insulated. All machinery casings and all boundary bulkheads of galleys and other spaces in which heat is produced shall be adequately insulated where there is a possibility of resulting heat effects in adjoining accommodation or passageways. Protection shall be provided from heat effects of steam and/or hot-water service, pipes.

4.4 Internal bulkheads shall be of material which is not likely to harbour vermin.

4.5 Sleeping rooms, mess rooms recreation rooms and passageways in the crew accommodation space shall be insulated to prevent condensation or over- heating.

4.6 Main steam and exhaust pipes for winches and similar gear shall, whenever practicable, not pass through crew accommodation or through passageways leading to crew accommodation; where they do pass through such accommodation or passageways they shall be adequately insulated.

4.7 Inside panelling or sheeting shall be of material with a surface easily kept clean. Tongued and grooved boarding or any other form of construction likely to harbour vermin shall not be used.

4.8 The wall surface and deckheads in sleeping rooms and mess rooms shall be easily kept clean, and, if painted, shall be light in colour; lime wash must not be used.

4.9 The decks in all crew accommodation shall be of approved materials and construction and shall provide a surface impervious to damp and easily kept clean.

4.10 Exposed decks over crew accommodation shall be sheathed with wood or have equivalent insulation.

4.11 Where the floorings are of composition, the joinings with the sides shall be rounded to avoid crevices.

4.12 Sufficient drainage shall be provided.

4.13 All practical measures shall be taken to protect crew accommodation spaces against the admission of flies and other insects.

5. Ventilation

5.1 Crew accommodation spaces shall be adequately ventilated.

5.2 Vessels regularly engaged on voyages in the tropics and other areas with similar climatic conditions, shall be equipped both with mechanical means of ventilation and with electric fans. Provided that one only of these means may be required in spaces where this ensures satisfactory ventilation.

5.3 Power for the operation of the aids to ventilation required by sub-clause 5.2 shall, when practicable, be available at all times when the crew is living or working on board and conditions so require.

6. Heating

6.1 An adequate system of heating the crew accommodation shall be provided as required by climatic conditions. Vessels of Class 3 shall be exempted from this requirement.

6.2 The heating system shall, when practicable, be in operation at all times when the crew is living or working on board and conditions so require.

6.3 Heating by means of open fires shall be prohibited. Heaters, if used, shall be in a fixed position and so constructed as to reduce fire risks to a minimum. No such heater shall be fitted with a heating medium which is so exposed that clothing, curtains or other flammable materials can be scorched or set on fire by heat from the heater.

6.4 The heating system shall be capable of providing a temperature in crew accommodation at a satisfactory level under normal conditions of weather and climate likely to be met with on service.

7. Lighting

7.1 All crew spaces shall be adequately lit. The minimum standard for natural lighting in living rooms shall be such as to permit a person with normal vision to read on a clear day an ordinary newspaper in any part of the space available for free movement. When it is not possible to provide adequate natural lighting, artificial lighting of the above minimum standard shall be provided.

7.2 In all vessels electric lights shall, as far as practicable, be provided in the crew accommodation.

7.3 An adequate reading light shall be provided for every berth in addition to the normal lighting.

8. Free movement Areas

8.1 The clear headroom in areas of free movement shall, wherever possible be not less than 1.9 metres.

9. Sleeping Rooms

9.1 Sleeping rooms shall be in no case be forward of the collision bulkhead.

9.2 The floor area per person of sleeping rooms, excluding the space occupied by berths and fixed furniture shall not be less than:

Provided that, in the case of passenger ships in which more than 4 ratings are berthed in one room the minimum per person may be 2.22 square metres.

9.3 The number of persons allowed to occupy any sleeping room shall not exceed six.

9.4 The maximum number of persons allowed to occupy any sleeping room shall be legibly and indelibly marked in some place in the room where it can conveniently be seen.

9.5 Each member of the crew shall be provided with an individual berth.

9.6 Berths shall not be placed side by side in such a way that access to one berth can be obtained only over another.

9.7 Berths shall not be arranged in tiers of more than two.

9.8 The lower berth in a double tier shall not be less than 0.3m above the deck; the upper deck shall be placed approximately midway between the bottom of the lower berth and the lower side of the deckhead beams.

9.9 The minimum inside dimensions of a berth shall wherever practicable be 1.9 metres by 0.68 metres.

9.10 If tubular frames are used for the construction of berths, they shall be completely sealed and without perforations which would give access to vermin.

9.11 Each berth shall be fitted with a mattress.

9.12 When one berth is placed over another a dustproof base shall be fitted beneath the upper berth.

9.13 Each occupant shall be provided with a clothes locker of not less than 1.50m height and cross-sectional area 0.19 sq. metres fitted with a suitable locking device and a rod for holding clothes on hangers, and a drawer or equivalent space which shall be not less than 0.06 cubic metre.

9.14 Any furniture and fittings shall be of smooth, hard material not liable to warp or corrode, or to harbour vermin.

9.15 Sidelights in sleeping rooms shall be fitted with means of excluding light.

9.16 Each sleeping room shall be fitted with a mirror.

9.17 Wherever possible, a separate room should be provided for a member of the crew who suffers from illness or injury.

9.18 The number of persons allowed to occupy sleeping rooms shall not exceed the following maxima.

9.18.1 officers in charge of a department or a Watch: one person per room;

9.18.2 other officers and petty officers: not more than two persons per room;

9.18.3 other ratings: not more than 6 persons per room.

10. Mess Rooms

10.1 Mess room accommodation separate from sleeping quarters shall be provided in all vessels carrying a crew of more than ten persons. Wherever possible it should be provided also in vessels carrying a smaller crew.

10.2 The dimensions of each mess room, where provided shall be sufficient for the number of persons using it at any time.

10.3 Mess rooms shall be equipped with tables and seats sufficient for the number of persons likely to use them at any one time.

10.4 Mess rooms shall be as close as practicable to the galley.

10.5 Adequate lockers for mess utensils and proper facilities for washing utensils shall be provided.

10.6 The tops of tables and seats shall be of damp resisting material without cracks and easily kept clean for.

10.7 In vessels of more than 30 metres length there shall be a separate mess room

10.7.1 officers and berthed passengers;

10.7.2 ratings.

11 Galley

11.1 Satisfactory cooking equipment shall be provided on board and shall, wherever practicable, be fitted in a separate galley.

11.2 The galley shall be of adequate dimensions for the purpose and shall be well lighted and ventilated.

11.3 The galley shall be equipped with cooking utensils, the necessary number of cupboards and shelves, and sinks and dish racks of rust-proof material and with satisfactory drainage. Where hot water is not supplied to the galley, an apparatus for heating water shall be provided.

11.4 Facilities shall be provided for the preparation of hot drinks for the crew at all times.

11.5 A cupboard, locker or storeroom of adequate capacity for messing provisions which can be kept dry, end well ventilated to avoid deterioration of stores shall be provided. Where necessary, refrigerators or other low temperature storage space shall also be provided.

12. Sanitation

12.1 Sufficient sanitary accommodation, including washing facilities shall be provided.

12.2 Sanitary facilities for all members of the crew who do not occupy rooms to which private facilities are attached shall, wherever practicable, be provided on the following scale:

(a) one shower for every eight persons or less;

(b) one water closet for every eight persons or less; and

(c) one wash basin for every six persons or less.

12.3 Cold fresh water and hot fresh water or means of heating water shall be available in all wash places.

12.4 Wash basins and shower recesses shall be of adequate size and constructed of material with a smooth surface not liable to crack, flake or corrode.

12.5 All water closet spaces shall have independent ventilation to the open air.

12.6 The sanitary equipment to be placed in water closet spaces shall be provided with ample flush of water, available at all times and independently controllable.

12.7 Soil pipes and waste pipes shall be of adequate dimensions and shall be so constructed as to minimise the risk of obstruction and to facilitate cleaning. They shall not pass through fresh water nor drinking water tanks, neither shall they, if practicable, pass overhead in mess rooms or sleeping accommodation.

12.8 Sanitary accommodation shall comply with the following requirements:

12.8.1 Floors shall be of material that is easily cleaned and impervious to damp, and shall be properly drained;

12.8.2 bulkheads shall be watertight up to at least 200 mm above the level of the deck;

12.8.3 water closet spaces shall not have direct access to spaces where food is stored, prepared or consumed;

12.8.4 water closet spaces shall be situated convenient to but separate from sleeping rooms and shall if practicable be separate from washrooms; and

12.8.5 where there is more than one water closet in a compartment, they shall be sufficiently screened to ensure privacy.

12.9 Facilities for washing and drying clothes shall be provided on a scale appropriate to the number of crew and the normal duration of the voyage.

12.10 The facilities for washing clothes shall include suitable sinks equipped with drainage which may be installed in washrooms if separate laundry accommodation is not reasonably practicable. The sinks shall be provided with an adequate supply of cold fresh water and hot fresh water or means of heating water.

12.11 Where practicable the facilities for drying clothes may be provided in an adequately ventilated compartment separate from sleeping quarters, mess rooms and water closet spaces.

13. Miscellaneous

13.1. Sufficient and adequately ventilated accommodation for the hanging of oilskins shall be provided outside, but convenient to the sleeping rooms.

13.2 Crew accommodation shall be maintained in a clean and habitable condition and shall be kept from of goods and stores which are not the personal property of the occupants.

SECTION 7

LOAD LINES
Contents

1. This Section is divided into Parts as follows:

PART 1 - PRELIMINARY

2. This Section should be read in conjunction with the Introduction, Definitions and General Requirements Section.

SECTION 7
LOAD LINES

PART 2 - REQUIREMENTS FOR LOAD LINE CONVENTION SHIPS

3. The requirements for determining load lines of Load Line Convention Ships are detailed in the Load Line Convention and the Regulations annexed to that Convention.

4. Load Line Convention Ships shall be surveyed by an Approved Classification Society in accordance with the requirements of the Convention.

PART 3 - REQUIREMENTS FOR SHIPS OTHER THAN LOAD LINE CONVENTION SHIPS

5. Interpretation.

In this Part unless the context otherwise requires:

(a) “length” means the length taken as 96% of the total length on a waterline at 85% of the least moulded depth measured from the top of the keel, or as the length from the foreside of the stem to the axis of the rudder stock on that waterline if that be greater. In ships designed with a rake of keel, the waterline on which this length is measured shall be parallel to the designed waterline. Provided that, in a case where no relevant plans of a ship are available, the length may be taken as 91 % of the length overall, except in the case of ships of landing craft type when a figure of 88% of the length overall should be used;

(b) “moulded depth” means the vertical distance measured from the top of the keel to the top of the freeboard deck beams at side. In wood and composite ships the distance is measured from the lower edge of the keel rabbet. Where the form at the lower part of the midship section is of a hollow character or where thick garboards are fitted, the distance is measured from the point where the line of the flat of the bottom continued inwards cuts the side of the keel. In ships having rounded gunwales, the moulded depth shall be measured to the point of intersection of the moulded lines of the deck and sides, the lines extending as though the gunwales were of angular design. Where the freeboard deck is stepped and the raised part of the deck extends over the point at which the moulded depth is to be determined the moulded depth shall be measured to a line of reference extending from the lower part of the deck along a line parallel with the raised part;

(c) “Position 1” means a position upon exposed freeboard and raised quarter decks and upon exposed superstructure decks, situated forward of a point located a quarter of the ship’s length from the forward perpendicular;

(d) “Position 2” means a position upon exposed superstructure decks situated abaft a quarter of the ship’s length from the forward perpendicular;

(e) “ship” does not include a ship that is a Load Line Convention ship or a ship in respect of which a valid International Load Line Certificate or an International Load Line Exemption Certificate is in force.

6. Freeboard Computation

(a) Subject to the provisions of clause 14, in the case of a vessel of 24 metres length or more, the freeboard shall be computed in the manner set down in the Load Line Convention;

(b) Subject to the provisions of clause 14, in the case of a vessel of less than 24 metres length, the freeboard shall be computed in the manner prescribed in Appendix A of this Part.

7. Conditions of Assignment

(a) Subject to the provisions of clause 13, in the case of a vessel of 24 metres length or more, the conditions of assignment of freeboard shall be those set down in the Load Line Convention;

(b) Subject to the provisions of clause 13, in the case of a vessel of less than 24 metres length, the conditions of assignment of freeboard shall be those conditions prescribed in Appendix B.

8. Survey Procedures

(a) Non-Load Line Convention Ships shall undergo an initial load line survey to establish the vessel’s freeboard and correct marking;

(b) The freeboard shall be stated on the Survey Certificate;

(c) Maintenance of the Conditions of Assignment of the loadline shall be ascertained Annually as part of the Annual Survey;

(d) Where, due to an accident, alteration, or general deterioration of the ship it is considered the existing freeboard may be insufficient; or the owner so requests, a Special Loadline Survey shall be conducted.

9. Markings

9.1 General requirements for marking.

A ship shall be marked on each side with:

(a) a deck line mark;

(b) a load line mark; and

(c) the mark of the assigning authority

The marks described above are specified in Appendix C.

10. Load Line Marks

(a) The load line mark of a ship shall consist of a ring that is:

(i) 250 mm in outside diameter;

(ii) 25 mm in breadth; and

(iii) intersected by a horizontal line 375 mm in length and 25 mm in breadth, the upper edge of which passes through the centre of ring;

(b) The centre of the ring referred to in paragraph (a) shall be placed at mid length and at a distance equal to the assigned freeboard, measured vertically below the upper edge of the deck line.

11. Mark of assigning authority

(a) The letters denoting the assigning authority for the load line of a ship shall be marked on the ship on either side of the load line disc, the base of such letters being in line with the horizontal line referred to in paragraph 10 (a) (iii);

(b) The letters referred to in paragraph (a) shall be 100 mm in height and of proportionate breadth;

(c) Where the assigning Authority is the Fiji Marine Board the marking shall consist of the letter “F”, placed to the left hand side of the loadline disc and the letter “M” placed on the right hand side of the loadline disc. The letters shall be 100 mm high, 80 mm wide and 15 mm in thickness.

12. Details of marking

The ring and lines referred to in this Sub-Section shall be painted in white or yellow on a dark ground or black on a light ground and shall be permanently marked on the side of the ship in such a manner as to be plainly visible to the satisfaction of the Marine Board.

13. Modification of requirements for existing ships

In the case of a ship that is an existing ship, the requirements of Sub-Section 8(c) relating to conditions of assignment shall be complied with as far as is in the opinion of the Marine Board, reasonable and practicable having regard to the efficiency of:

(a) the protection of openings;

(b) the guardrails and freeing ports; and

(c) the means of access to crew accommodation, provided by the existing arrangements of the fittings and appliances on the ship.

14. Freeboards in existing ships

Where freeboards have been assigned by an approved Authority to a ship that is an existing ship, the ship may retain those freeboards after the date of coming into force of this Section provided that the conditions of assignment maintained in the ship are continued as effective as when the original assignment was made.

PART 4 - APPENDICES

Appendix A - Computation of freeboard for vessels less than 24 metres in length.

Appendix B - Conditions of assignment for vessels less than 24 metres in length.

Appendix C - Deck Line Marks, Load Line Marks and Marks of the Fiji Marine Board.

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APPENDIX A

COMPUTATION OF FREEBOARD FOR VESSELS LESS THAN 24 METRES IN LENGTH

1. For all vessels having a continuous watertight deck and where hatchways are secured watertight by steel covers or equivalent means: 200 millimetres.

2. For all vessels having a continuous watertight deck and where hatchways are secured watertight by wooden boards and tarpaulins 250 millimetres.

3. For vessels which are open or only partly decked:

Freeboard for intermediate lengths are to be obtained by linear interpolation.

4. Additional freeboard for vessels licensed to carry passengers

4.1 In additional to the freeboard assigned in clauses 1, 2 or 3 to the vessel shall, if necessary, be increased to such that, if all the passengers the vessel is licensed to carry are placed on one extreme side of the vessel on the uppermost deck, while the vessel is in its fully loaded condition, the resultant list shall not submerge the loadline more than 50% of such freeboard assigned.

For this purpose it is assumed 13.6 persons to weigh one ton.

APPENDIX B

CONDITIONS OF ASSIGNMENT FOR VESSELS LESS THAN 24 METRES IN LENGTH

1. Sill Height

1.1 The height above deck of sills in doorways of deckhouses shall comply with the following:

1.1.1 The height above the deck of sills in doorways of deckhouses or superstructures on the weather deck from inside which there is direct access to spaces below the weather deck shall not be less than 300 mm.

1.1.2 The height above the deck of sills in doorways of deckhouses, or companion ways on the weather deck which are shielded from the full force of the sea, except those giving direct access to machinery spaces, shall be not less than 150 mm.

2. Hatch Coamings of Standard Height

The coamings of hatchways in Position 1 and Position 2 shall be of substantial construction. The height above deck of coamings in Position 1 and Position 2 shall be not less than 450 mm and 300 mm respectively.

3. Hatch Coamings of Reduced or No Height

Where hatches situated within the mid half beam of the vessel are of a width less than half the beam of the vessel, are closed with efficient weathertight covers of steel or other equivalent materials fitted with gaskets and clamping devices and are capable of being rapidly closed and battened down and the Marine Board is satisfied that the safety of the vessel in the service sea conditions will not be impaired by so doing, the Marine Board may:

(a) determine that the coamings of these hatchways shall be of a height less than that specified above; or

(b) determine that the coamings for these hatchways be omitted and in such a case the coamings shall be of the height so specified or the coamings may be omitted.

4. Scuppers and Discharges

Scuppers and discharge pipes which pass through the side of the vessel shall comply with the following:

(a) scupper and discharge pipes, excluding machinery exhaust an easily accessible position against the vessel’s side, except that where approved bilge alarms are fitted, such valves or cocks shall not be required in the case of discharges not exceeding 40 mm internal diameter, the lowest point of which is not less than 225 mm above the load waterline. Waste and soil discharges greater than 40 mm internal diameter from spaces above the freeboard deck which are led through the vessel’s side more than 225 mm above the summer load waterline maybe fitted with a non-return valve in lieu of a screw-down valve or cock;

(b) Main propulsion machinery exhaust systems shall be fitted with an approved hull fitting, the lower edge of which shall be as high as practicable but not less than 225 mm above the summer load waterline. Such systems may pass through watertight bulkheads aft of the machinery space provided that:

(i) an after peak bulkhead is fitted extending to the weather deck;

(ii) the system is passed through the bulkhead or bulkheads as close to the underside of the weather deck as practicable; and

(iii) an approved bulkhead fitting is provided at each watertight bulkhead through which the system passes.

(c) Auxiliary machinery exhaust systems shall comply with the provisions of sub-paragraph 4(b) (i) above shall not pass through watertight bulkheads without the approval of the Marine Board.

5. Freeing Ports

5.1 Where bulk warks in the weather portion of a freeboard deck form wells, there shall be provided, on each side of the vessel, in each well a minimum freeing port area having the same number of square metres as the number obtained as follows:

(a) Where the length of the well is 20 metres or greater, from the formula:

Freeing port area = 0.07 g

Where g = length of well in metres; or

(b) Where the length of the well is less than 20 metres, from the following table:

The freeing port area for intermediate lengths of well may be determined by interpolation.

5.2 Where the average height of bulwark exceeds 1.2 metres, the area obtained in accordance with the provisions of sub-item 5.1 shall be increased by the number of square metres ascertained from the formula: 0.04 gh

5.3 Where the average height of bulwark is less than 0.9 metres, the area obtained in accordance with the provisions of sub-item 5.1 shall be reduced by the number of square metres ascertained from the formula: 0.04 gh₂

5.4 For the purposes of sub-items 5.2 and 5.3:

g=length of the bulwark in the well;

h=the difference in metres between the average height of the bulwark in the well and 1.2 metres; and

h2= the difference in metres between the average height of the bulwark in the well and 0.9 metres.

6. Air Pipes and Ventilator Coamings

The heights of air pipes and ventilator coamings in Position 1 and Position 2 shall be not less than 450 mm and 300 mm respectively.

SECTION 7

APPENDIX C

DECK LINE MARKS, LOAD LINE MARKS AND MARKS OF FIJI MARINE BOARD

[PacLII Editorial Note: View PDF Original for Image]

SECTION 8

TONNAGE MEASUREMENT SECTION

CONTENTS

l. This Section is divided into Parts as follows:

Part 1: Preliminary

Part 2: Tonnage Measurement Convention

Part 3: Vessels to which the tonnage convention does not apply

Part 4: Tonnage certificates

PART 1-PRELIMINARY

2. This Section should be read in conjunction with the Introduction, Definitions and General Requirements Section.

PART 2-TONNAGE MEASUREMENT CONVENTION

3. Vessels to which the Tonnage Measurement Convention applies shall have their tonnage determined according to that convention.

PART 3-VESSELS TO WHICH THE TONNAGE MEASUREMENT CONVENTION DOES NOT APPLY

4. Vessels to which the Tonnage Measurement Convention does not apply shall have their tonnage determined according to that convention, subject to the following:

4.1 Vessels of less than 24 metres length shall have their gross tonnage determined according to the formula:

Gross tonnage=0.24 (0.6 LBD + VgA)

4.2 Vessels of less than 10 metres length shall not be required to have their tonnage determined, but when the owner so requests, a tonnage may be determined in accordance with this Part.

4.3 In respect of existing vessels Article 3 of the Convention shall apply. The Convention came into force in respect of Fiji on 18th July 1982.

Paragraph (2) (d) of Article 3 of the Convention shall come into effect in respect of Fiji on 18th July 1994.

PART 4-TONNAGE CERTIFICATES

5. The following forms are the certificates which shall be issued:

Form TM1-INTERNATIONAL TONNAGE CERTIFICATE (1969) to vessels to which the Tonnage Convention applies;

Form TM2-FIJI MARINE BOARD TONNAGE CERTIFICATE to vessels to which the Tonnage Convention does not apply.

Issued under the provisions of the International Convention on Tonnage Measurement of Ships, 1969, under the authority of the Government of FIJI for which the Convention came into force on 18th JULY, 1982 by the FIJI MARINE BOARD.

*Date on which the keel was laid or the ship was at a similar stage of construction (Article 2(6), or date on which the ship underwent alterations or modifications of a major character (Article 3(2) (b), as appropriate.

MAIN DIMENSIONS

THE TONNAGES OF THE SHIP ARE:

GROSS TONNAGE ____________________________________
NET TONNAGE_______________________________________

This is to certify that the tonnages of this ship have been determined in accordance with the provisions of the International Convention of Tonnage Measurement of Ships, 1969.

_____________________________________________________________________

(signature of the President, FIJI MARINE BOARD
and/or
(seal of FIJI MARINE BOARD)

If signed, the following paragraph is to be added:

The undersigned declares that he is duly authorized by the said Government to issue this certificate.

(Signature)_________________________________________

FORM TM2

CERTIFICATE

___________

FIJI MARINE BOARD TONNAGE CERTIFICATE

Issued under the provisions of Section 21 of the Marine Act, 1986.

*Date on which the keel was laid or the ship was at a similar stage of construction or date on which the ship underwent alterations or modifications of a major character as appropriate.

THE TONNAGES OF THE SHIP ARE:

GROSS TONNAGE ____________________________________
NET TONNAGE_______________________________________

This is to certify that the tonnages of this ship have been determined in accordance with the provisions of Section 21 of the Marine Act, 1986.

_____________________________________________________________________

(signature of the President, FIJI MARINE BOARD

(Seal of FIJI MARINE BOARD)

If signed, the following paragraph is to be added:
The undersigned declares that he is duly authorized by the said Government to issue this certificate.

(Signature)________________________________________

SECTION 9

ENGINEERING

SECTION 9

ENGINEERING

PART 1 - PRELIMINARY

1. This section is divided into Parts as follows:

Part 1 Preliminary

Part 2 General

Part 3 Machinery

Part 4 Electrical

Part 5 Liquid Petroleum Gas Installation

Part 6 Cargo Refrigeration

Part 7 Personnel Protection

2. This Section should be read in conjunction with the Introduction, Definitions and General requirements Section.

3. Application

3.1 Subject to sub clause 3.2 these requirements shall be applicable to all classes of vessels less than 35 m in length.

3.2 Vessels of 35m in length and over shall comply with Parts 2, 5 and 7 and Clause 29 of Part 4 of this section and shall otherwise be assessed under the Rules of an approved Classification Society. Additionally Safety Convention Ships shall comply with the Safety Convention.

3.3 In the case of a ship other than a Safety Convention Ship that is an existing ship the Fiji Marine Board may permit such modifications to the requirements of this Section as it thinks fit, having regard to:

(a) the Age of the ship; and

(b) the trade in which the ship is, or is about to be engaged.

PART 2 - GENERAL

4. In this Section the following requirements shall apply:

4.1 Design-Corrosion and Abnormal Loadings

4.1.1 Where any item detailed in this Section is subject to rapid corrosion, other rapid form of deterioration or to abnormal loading, and such item shall be subject to special consideration.

4.1.2 In any pipe system provision shall be made to avoid excessive stress in any part due to expansion and contraction resulting from variation in temperature or due or vibration and shall otherwise take account of the effects of corrosion and external mechanical damage.

4.2 Novel Design and Unusual Materials

Where any item detailed in this Section is novel in design, or involves the use of unusual materials, the owner or his agent shall submit full calculations and any other information required. He shall bear the cost of any special tests or examinations considered necessary by the Fiji Marine Board.

4.3 Astern Power

Where the shaft power available for propulsion exceeds 5kW astern power shall be provided for adequate manoeuvrability under normal operating conditions.

4.4 Access to Machinery The overall design of a machinery space shall be so arranged as to permit reasonable access to all items of the installation which may require attention; in service.

4.5 Machinery Identification

4.5.1 All controls for operating the machinery, and all measuring devices, pumping systems, valves, cocks, air pipes, sounding pipes, switches etc. shall be permanently marked with appropriate inscriptions clearly showing their purpose. All hand-wheels for valves which are closed by turning anti-clockwise shall be marked to show the direction of turning for closure. Where pipes are marked by colours to indicate their purpose the colours shall be in accordance with Australian Standard AS 1345.

4.5.2 The provisions of this sub-clause need not apply if the surveyor considers it to be unnecessary owing to the simplicity of the installation.

4.6 Manufacturer’s Recommendations

In all requirements of this Section due consideration shall be given to any specific recommendations of the manufacturer of any engine or item of ancillary equipment.

4.7 Other Sections

In addition to a requirement of this Section there may be associated requirements in the Load Lines, Construction, Fire Appliances, Life-saving Appliances and other Sections of these uniform requirements. Due regard shall therefore be paid to these requirements.

4.8 Communication

A vessel of 24.4m and over shall be provided with a suitable means of communication between the wheelhouse and the machinery space except that this shall not apply in the case of a vessel having propulsion machinery which under normal operating conditions is started, controlled and stopped from the wheelhouse only.

PART 3 - MACHINERY

5. Main Engines

5.1 Subject to the next succeeding sub-clause of this clause, a vessel shall be provided with a main engine or engines of a type designed and manufactured for marine use having regard to their intended purpose and shall operate on fuel having a closed flash point of not less than 60°C.

5.2 Engines which operate on fuel having a closed flash point of less than 60°C may only be used on vessels of less than 10 m in length in outboard engines in Classes 3D and 3E vessels.

6. Machinery Seatings

6.1 General

Each item of machinery shall be securely bolted to a rigid seating. Fitted and/or clearance bolts may be used and suitable arrangements are to be provided to prevent the bolts from becoming slack.

6.2 Wood and Glass Reinforced Plastic (GRP)

Where the machinery seatings are of wood or GRP the upper face of recesses to accommodate the nuts and washers of the holding down bolts are to be located at a depth, below the upper face of the seating, sufficient to ensure ample material in compression when the bolts are tightened.

6.3 Resilient Mountings

When resilient mountings are fitted the output shaft is to be connected to a flexible coupling. Satisfactory arrangements are to be made to transmit thrust.

7. Instrumentation

7.1 Instruments-General

Instruments shall be suitable for marine use, capable of withstanding vibration and shock and be so installed and illuminated as to be readily visible.

7.2 Items Monitored

7.2.1 An engine essential for the safe operation of a vessel of 25m in length and over shall be provided with an audible warning device to indicate a dangerous condition associated with:

(a) engine lubricating oil pressure;

(b) engine jacket cooling water outlet temperature; and

(c) engine gear box lubricating oil pressure.

7.2.2 All engines essential for the safe operation of the vessel shall, to the extent that the design and manufacture allows, be provided with instruments indicating the following:

(a) engine lubricating oil pressure;

(b) engine jacket cooling water outlet temperature;

(c) engine gear box lubricating oil pressure;

(d) charging rate of generator; and

(e) in the case of propulsion machinery, the rotational speed.

7.3 Unmanned Machinery Space

In the case of an unmanned machinery space the instruments as required by sub-paragraph 7.2.2(a) (b) and(c) shall be located as to be clearly visible at each steering position. The instruments required by sub-paragraph 7.2.2 (d) and (e) shall only be necessary at the position at which the vessel is principally navigated.

8. Starting Arrangements

8.1 Methods

In all Class 1, 2A, 2B & 2C vessels where the main engine or engines are not fitted with hand starting arrangements, provision shall be made for an alternative method of starting to be capable of being developed onboard without external aid. If for this purpose:

(a) an electric generator or air compressor is required, the unit shall be power driven by a hand starting engine. A hand operated air compressor may be accepted and in the case of electric starting a standby set of batteries may be accepted.

(b) a hydraulic accumulator is required, then the accumulator shall be capable of being pressurised by hand

8.2 Number of Starts

Air receivers or batteries used for starting main engines shall have sufficient capacity without recharging to provide:

(a) 6 consecutive starts for each non-reversible engine.

(b) 12 consecutive starts for each reversible engine.

8.3 Bars and Hand Cranks

Bars used on flywheels to turn machinery over by hand shall be so constructed as to facilitate easy withdrawal from the flywheel’s recess if the engine should recoil. Hand cranks for engines shall be designed to disengage instantly when the engine starts.

9. Unfired Pressure Vessels

9.1 Unfired pressure vessels and their mountings shall be designed, constructed and tested in accordance with the requirements of Australian Standard AS 1210 or the requirements of a classification society.

10. Exhaust Systems

10.1 Gas Passage Area

No part of the exhaust gas passage shall have an area less than that of the outlet of the exhaust manifold. If the exhaust system is unusually long or the conditions require bend, the internal cross sectional area of the piping shall be increased to prevent an increase of back pressure at the engine.

10.2 Separation

Exhaust pipes of several engines shall not be connected together but shall be run separately to the atmosphere unless arranged to prevent the return of gases to an idle engine.

10.3 Silencer

All internal combustion engines, shall be effectively silenced.

10.4 Materials

Exhaust pipes and silencers shall be of steel, copper or other approved material.

The use of reinforced synthetic rubber hose may be permitted for exhaust pipes on engines having water cooled exhausts. Except for reinforced synthetic rubber hose enclosed in a gastight trunk as required by sub-clause 10.8, all of the hose shall be readily visible.

10.5 Thermal Protection

Exhaust piping and silences are to be water cooled or efficiently lagged. The exhaust system is to be so installed as to prevent the transfer of heat to readily combustible materials.

10.6 Height of Discharge

Exhaust pipe discharges which are led through the hull below deck level are to be installed as high above the load water line as practicable and shall not be installed at a height less than the height required by the Load Line or Construction Sections of these uniform requirements, as is applicable. The arrangement shall otherwise comply with the relevant provisions of the Load Lines Section.

10.7 Back Flooding

The exhaust system shall be so designed and installed as to prevent sea water or exhaust cooling water entering the engine manifold.

10.8 Protection of Accommodation Space

An exhaust pipe which passes through an accommodation space shall be enclosed in a gas tight trunking.

10.9 Location of Discharge

Where an exhaust pipe is led above the deck it shall be installed well clear of space openings so as to limit the products of combustion passing back into any space in the vessel.

10.10 Layout-Support

Exhaust pipes shall be led to the point of escape with a minimum number of bends or elbows and be adequately supported.

11. Engine Cooling Systems

11.1 Air Cooling

11.1.1 In air cooled engines the cooling air discharge shall be separately trunked to the open air.

11.2 Water Cooling

11.2.1 In water cooled engines an adequate supply of sea water shall be provided for cooling purposes.

11.2.2 A cooling water pump may be driven by the engine it serves or be independently driven.

11.2.3 In vessels propelled by a single main engine exceeding 400 kW brake power, provision is to be made for an emergency supply of cooling water from a separate power pump which may be driven by the engine.

12. Ventilation of Machinery Spaces

12.1 Aspiration

Adequate ventilation shall be provided in the engine room and all other enclosed machinery spaces. The volume of air provided shall be not less than that necessary for the efficient aspiration and efficient operation of the main engines and other machinery. Such ventilation shall be obtained with all access openings closed.

12.2 Ventilator Sizes for Natural Ventilation

The engine room shall be furnished with an inlet and exhaust ventilator each of which is to have a minimum size as follows:

12.3 Area of Cowls or Scoops

Where cowls or scoops are provided on any ventilator, the free area of the cowl or scoop shall be not less than twice the required trunk area. Where the cowls or scoops are screened, the mouth area shall be increased to compensate for the area of the screen wire. Inlet and outlet openings shall not be located where the natural flow of air is obstructed. Outlet ventilators shall not discharge within one metre of a possible source of ignition. Ventilators shall be so located that exhaust air will not be taken into supply vents.

13. Gear Boxes

13.1 Gearboxes shall be of the marine type and suitably matched to the prime mover with which they are to be used. When coupled to the engine it shall not be possible to exceed the limiting power, torque, speed or thrust of any component of the gear box. Maker’s certificates covering design, material and manufacture may be accepted for this purpose.

14. Propeller and Intermediate Shafting

14.1 Intermediate Shaft Size

The diameter of the intermediate shafting shall not be less than that determined by the following formula:

d_i = akf ³√^P/_N

where d =diameter of intermediate shafting in mm

f = 1.01 ³√⁴⁰⁰/_T

where T is the minimum ultimate tensile strength of the shaft material in MPa Note: Where test pieces are not submitted the value of T shall be the minimum ultimate tensile strength of the material as guaranteed by the manufacturer and for low carbon steel it shall be taken as 410 MPa for 316 stainless steel 618 MPa and for 329 stainless steel 724 MPa:

TABLE 14.1A

14.2 Propeller Shaft Size

The diameter of the propeller shaft shall not be less than that determined by the following formula:

d_p = (1.14 d_i = ^d/_K) f

where d_p = diameter of propeller shaft in mm

d_i = diameter of intermediate shaft in mm

(calculated for a material with a U.T.S. of 410 MPa)

d = propeller diameter in mm
K = 144 for shafts protected against corrosion by

(a) a continuous liner;

(b) a suitable oil gland;

(c) an appropriate coating of the shaft between bushes, if this coating can be examined at each dry docking; or

(d) the nature of the material of the shaft

K = 100 in all other cases
f = steel factor to be determined by formula

f = 1.01 ³√⁴⁰⁰/_T

where T is the minimum ultimate tensile strength of the shaft material in MPa.

NOTE: Where test pieces are not submitted the value of T shall be the minimum ultimate tensile strength of the material as guaranteed by the manufacturer and for low carbon steel it shall betaken as 410 MPa, for 316 stainless steel 618 MPa and for 329 stainless steel 724 MPa.

The part of the propeller shaft forward of the stern gland may be tapered down to a diameter calculated in accordance with the following formula:

Reduced diameter= 1.14 (d_i × ^f/_f p)

where f_p is the steel factor used for calculating d_p and f_i is the steel factor used in calculating d_i. The reduction in diameter is to be as gradual as possible.

14.3 Hollow Shafting

Where hollow shafting is used, the proportions are to be such that the strength will be equivalent to that required for the corresponding solid shaft, except that a central hole not exceeding one third of the shaft diameter may be accepted without increase in shafts size.

14.4 Bearing Spacing

Any unsupported length of shafting shall not exceed that determined by the following formula:

S = 0.142 ³√d²

where

S = distance between bearing in mm

d = diameter of shaft in mm

The forward most bearing should preferably be at least 12 shaft diameters from the engine gear box or thrust block flange.

14.5 Propeller Shaft Overhang

The overhang of the propeller shaft between the forward face of the propeller boss and the after face of the adjoining shaft bearing shall not be more than the actual propeller shaft diameter. However an overhang greater than this amount may be permitted provided that the bending stress due to the additional overhang is considered in the calculation of the shaft diameter.

14.6 Material

14.6.1 Shafts shall be of

(a) salt water resistant stainless steel;

(b) bronze;

(c) monel metal;

(d) fully killed carbon steel for diameters of 150 mms and over; or

(e) semi-killed carbon steel for diameters less than 150 mms.

The use of rimming of free cutting steel is not acceptable.

14.6.2 Shafts shall conform to the following minimum requirements:

(a) ultimate tensile strength (U.T.S.) 410 MPa;

(b) yield point 230 MPa;

(c) elongation:

bronze 25%

carbon steel 23%

monel 20%

stainless steel 17%

The Board shall be satisfied that the material is suitable for the purpose and where doubt exists may require physical and/or chemical tests to be conducted. Where tests are required to determine the U.T.S. and elongation they shall be determined on a 70 mm minimum gauge length by 14 mm diameter test piece.

Screw shafts and tube shafts of carbon or carbon manganese steel are in general to be restricted to a range of tensile strength between 410 and 510 MPa.

Where it is proposed to use:

(a) a carbon or carbon manganese steel having a specified minimum tensile strength greater than 590 MPa; or

(b) a material other than carbon or carbon manganese steel having a minimum tensile strength greater than 724 MPa.

full details shall be submitted to the Fiji Marine Board for consideration.

14.7 Propeller Shaft Liner

14.7.1 Propeller shafts of carbon steel are to be protected by a continuous salt water resistant liner where exposed to sea water. Alternatively, the liner may be omitted provided the shaft runs in an oil lubricated stern tube with an approved sealing gland at the after end. Lengths of shafting between stern tubes and propeller brackets may be protected by suitable coatings.

14.7.2 The thickness of bronze liners fitted on propeller shafts or tube shafts in way of the bushes shall not be less than

t = thickness of the liner in mm

d_p = diameter required for the propeller or tube shaft within the liner in mm

The thickness of a continuous liner at the part between the bushes shall not be less than 0.75 t. Liners shall be shrunk on or forced on to the shafts by hydraulic pressure. Securing pins shall not be fitted.

14.7.3 The thickness of stainless steel or mild steel liners fitted on propeller shafts or tube shafts in way of the bushes shall not be less than:

where t = thickness of the liner in mm

d_p = diameter required for the propeller or tube shaft within the liner in mm

Liners shall be either shrunk on, or forced on to the shafts by hydraulic pressure. Securing pins shall not be fitted.

14.7.4 Effective means shall be provided to exclude water from the part of the shaft between the after end of the liner and the propeller boss. Any cavity between the liner and the shaft clear of the close fitting portions shall be filled with a suitable composition.

14.8 Propeller Shaft Taper

Propeller shafts are to be provided with an accurate taper fit in the propeller boss, particular attention being given to the fit at the large end of the taper. The taper shall be between the limits of 1 in 12 and 1 in 16 on the diameter. It is recommended that the 1 in 12 taper be employed wherever possible.

14.9 Keys and Keyways

14.9.1 Keyways are to be contained wholly within the length of the taper. The distance between the large end of the taper and the commencement of the keyway is to be not less than 0.2 of the nominal diameter of the propeller shaft. The depth of the keyway shall be half the required thickness of the key.

14.9.2 Keyways are to be provided with smooth fillets at the bottom and sharp edges at the top are to be removed. For shafts in excess of 150 mm nominal diameter, the radius of the fillet in the bottom corners of the keyways is to be at least 0.012 of the nominal diameter of the shaft.

14.9.3 Keys for propeller shafting are to be of the round ended or sled-runner type, and shall be of material similar to the shaft to which they are to be fitted. Where keys of the sled-runner type are used provision should be made to prevent them from sliding in the keyway.

14.9.4 The dimensions of keys are to be determined in accordance with the following formula:

t (for shafts less than 150 mm dia)

= 0.633 (w-8) + 6 mm

d_p = diameter of propeller shall in mm

w = width of key in mm

t = highness of key in mm

The length of the key (L) in mm is to be not less than

Where d_p = nominal diameter of the propeller shaft in mm.

14.10 Propeller and Shaft Coupling Retaining Nuts

14.10.1 Retaining nuts which are of similar materials to the propeller or intermediate shafting to which they are to be fitted shall comply with the following:

(a) the outside diameter of the threads shall be not less than 0.75 of the diameter at the small end of the taper;

(b) the depth over which the nut is fully threaded shall not be less than 0.75 of the diameter of the thread; and

(c) the width across the flats or the effective outside diameter shall not be less than 1.5 times the diameter of the thread.

The nuts shall be fitted with effective locking devices. Propeller nuts fitted to low carbon steel shafts shall be cap nuts.

14.10.2 The pitch of the threads for shafts and nuts should be in accordance with the following:

(a) 2.5 mm pitch for diameters not exceeding 40 mm;

(b) 3.5 mm pitch for diameters of 40 mm and not exceeding 75 mm;

(c) 4 mm pitch for diameters of 75 mm and not exceeding 100 mm; and

(d) 6 mm pitch for diameters exceeding 100 mm.

The tread form should be U.N.C.

14.11 Coupling Materials

Couplings are to be of carbon steel or equivalent material. Ordinary grades of cast iron will not be accepted and higher grades will be subject to special consideration.

14.12 Coupling Types

Couplings shall be of the following types:

(a) Flange couplings with flanges formed by upsetting the ends of a shaft;

(b) Flange couplings with flanges of fabricated construction. Such couplings shall be suitably designed, prepared, and heat treated subsequent to welding and then machined. They shall be subjected to such testing as is deemed necessary;

(c) Coupling fitted on a taper, keyed and held in place with a nut;

(d) Couplings shrunk on a parallel shaft which do not employ a key, pin, dowel or similar item in way of the shrink fit provided that the design and manufacture satisfactory and the couplings are not subject to removal in service;

(e) Oil injection couplings;

(f) Couplings of the split type, keyed and clamped to parallel shafts;

(g) Approved flexible couplings.

14.13 Coupling Dimensions

The thickness of a coupling flange shall be not less than 0.25 of the diameter of the intermediate shaft or shall be equal to the diameter of the coupling bolt whichever is the greater.

The ligament thickness outside the coupling bolt holes shall be not less than 0.6 of the coupling bolt diameter.

The fillet radius at the base of the flange is to be not less than 0.125 of the actual diameter of the shaft. The strength of the boss of a coupling shall be not less than the equivalent strength of the shaft.

14.14 Universal Joint Couplings

Universal joints may be incorporated in the propulsion shafting between the engine and thrust block.

The hollow shafting component of such a universal jointed propulsion shafting installation shall be equivalent to the requirements of the clause which relates to solid propeller shafting, and the flanged universal ends shall be equivalent to the requirements which relate to couplings.

The installation shall be such as to limit the stresses set up by cyclic irregularities.

Effective arrangements are to be provided to prevent damage to the hull or structure of the vessel due to the flailing of the shaft should the universal joint elements fail to service.

14.15 Shaft Coupling Bolts

14.15.1 The minimum diameter of the shaft coupling bolts is to be determined by the following formula:

d_b = 0.54 √d³/Nr

where

d_b = diameter of bolts at joint in mm

N = number of bolts fitted in one coupling

r = pitch circle radius of bolts in mm

3 =required diameter of intermediate shaft in mm, using material having the same mechanical properties as the material of the coupling bolts.

14.15.2 Shaft coupling bolts shall be machine finished and neat fitting.

14.16 Bolts for Clamp Coupling

14.16.1 The diameter at the bottom of the threads of bolts in clamp coupling is not to be less than:

d_b = 3.3 √d_i³/Nr

where d_b = diameter of bolts in mm

N = number of clamp bolts at one of the shaft ends

r = distance in mm between the centre of the bolts and the centre line of the shaft

d_i = required diameter of intermediate shaft in mm, using material having the same mechanical properties as the material of the coupling bolts.

14.16.2 A minimum of two bolts shall be let into the shaft for half their diameter, to take the astern thrust.

14.17 Stern Bearings

14.17.1 Grease lubricated white metal bearings, or water lubricated bearings which are lined with rubber composition or other suitable material, shall not be less in length than four times the diameter of the propeller shaft

14.17.2 Oil lubricated white metal bearings shall be provided with a satisfactory type of oil sealing gland. The length of the bearing is to be sufficient to ensure that the bearing pressure resulting from the mass of the propeller and propeller shafting will not exceed 480 kPa. The length of the bearing shall not be less than 2 times the diameter of the propeller shaft.

14.18. Flexible Stern Gland

In the case of a vessel of less than 10 m in length, any Class 2 or any Class 3 vessel in which the screw or tube shaft is not greater than 60 mm in diameter, a flexible stern gland may be fitted. The gland shall be connected to the stern tube by approved reinforced synthetic rubber hose and the hose shall be secured by two corrosion resistant clips at each end. Circular movements of the gland shall be limited by stops to not more than 5°either side of the mean position.

14.19 Propeller Shaft Brackets

14.19.1 General

Unless otherwise provided, reference to diameter of propeller shaft in this sub-clause shall mean the diameter of the propeller shaft as provided for the vessel.

14.19.2 Boss

The length of the boss is to be not less than four times the diameter of the propeller shaft. The thickness of the boss is to be not less than one quarter of the diameter of the propeller shaft.

14.19.3 Brackets of ‘V’ Configuration of Carbon Steel

14.19.3.1. Width

The width of each leg is not to be less than that obtained from the following formula:

W=2.27d

where

W= width of major axis in mm

d=diameter of propeller shaft in mm, calculated for a material, having a U.T.S. of 410 MPa

14.19.3.2 Thickness

The thickness of each leg is not to be less than that obtained from the following formula:

t = 0.35d

where

t = thickness of leg (minor axis) in mm

d = diameter of propeller shaft in mm, calculated for a material having a U.T.S. of 410 MPa.

Where the included angle between the legs is less than 45° the scantlings are to be specially considered.

14.19.4 Brackets of ‘I’ Configuration of Carbon Steel

14.19.4.1 Width

The width of the leg is not to be less than that obtained from the following formula:

W_i = 3.22d

where

W_i = width of major axis in mm

d = diameter of propeller shaft in mm, calculated for a material having a U.T.S of 410 MPa.

14.19.4.2 Thickness

The thickness of the leg is not be less than that obtained from whichever of the following formula is appropriate:

(a) where the bracket is a cantilever

t_i = 0.515d; or

(b) where the lower end of the bracket is attached to a shoe piece or skeg

t_i = 0.036d

and t_i = thickness of the leg (minor axis) in mm

d = diameter of propeller shaft in mm, calculated for a material having a U.T.S. of 410 MPa.

14.19.5 Propeller Shaft Brackets of Materials other than Carbon Steel. Where a material other than carbon steel is used, the Authority may allow the thickness of the legs to be determined from:

t₂ = t√⁴¹⁰/_T

t₂ = thickness of the leg of materials other than carbon steel in mm

t = thickness of the leg determined in accordance with sub-paragraphs 14.19.3.2 or 14.19.4.2 whichever is appropriate

T = Ultimate tensile strength of material in MPa

14.19.6 Leg Length

The length of the longer leg of a V bracket or the leg of an 1 bracket measured from the outside perimeter of the boss to the outside of the shell plating is not to exceed 10.6 times the diameter of the propeller shaft. Where this length is exceeded the width and thickness of the legs or leg are to be increased and the bracket design will be given special consideration.

14.19.7 Where the bracket is a hollow section, the modulus of section is to be at least equal to the modulus of section of the solid bar as required by the preceding paragraphs.

15. Fuel Systems

15.1 Fuel Tanks Forming Part of the Hull Structure

Fuel tanks forming part of the vessel’s hull structure shall comply with the relevant provisions of the Construction Section.

15.2 Free-Standing Non-Portable Metal Fuel Tanks

15.2.1 Free-standing non-portable metal fuel tanks shall be substantially constructed of carbon steel, stainless steel, and copper or marine grade aluminium alloy. No part of the fuel tank shall depend on soft solder for tightness.

15.2.2 Where a dimension parallel to the longitudinal axis of a tank exceeds 1 m, baffles spaced not more than 1 m apart may be required.

15.2.3 The minimum thickness of carbon steel used in the construction of a fuel tank shall be determined using the dimensions of the largest unsupported panel but shall not be less than 3 mm. In assessing the largest unsupported panel account shall be taken of the support afforded by:

(a) tank boundaries;

(b) baffles, where the thickness of the baffles is not less than the thickness of the tank plating in way; and

(c) stiffeners, where

(i) the thickness of the stiffener is not less than the thickness of the tank plating in way, or 5 mm, whichever is the greater; and

(ii) the depth of the stiffener is not less than

15.2.4 Where the depth from the top of the filling pipe to the bottom of the tank does not exceed 2.5 m the plate thickness shall be obtained from figure 15.2.4 which is developed from the formula:

t = 0.024 ac

where t = thickness of plate in mm

a = width of panel (minor axis) in mm

c = numerical value as given below, where

b = length of panel (major axis) in mm

15.2.5 Where the depth from the top of the filling pipe to the bottom of the tank exceeds 2.5 m the plate thickness shall be calculated from the formula:

t = 0.024 ac√^h/_2.5

where t, a, b and c are as defined in paragraph 15.2.4 and h =distance from top of filling pipe to bottom of tank in m.

15.2.6 Where a material other than carbon steel is used, the Authority may allow the plate thickness to be determined from:

t_i = t √⁴¹⁰/_T

Where t_i =plate thickness of material other than carbon steel in mm.

t = thickness of plate in mm determined in accordance with paragraph 15.2.4 or 15.2.5 as appropriate

f = ultimate tensile strength of material in MPa.

15.2.7 The pressure test of a tank shall be carried out prior to its installation in the vessel.

15.3 Installations with Non-Portable Fuel Tanks

15.3.1 Fuel rank Pressure Test

A fuel oil tank shall be subjected to a test equivalent to 2.5m of fresh water above the top of the tank or to the maximum head to which the tank may be subject in service, whichever is the greater.

15.3.2 Fuel Tank Location

15.3.2.1 Taking account of the possibility of overflow, leakage or rupture, fuel storage tanks and piping should be arranged to minimize the possibility of fuel coming into contact with a hot surface or electrical components which may result in outbreak of fire.

15.3.2.2 Fuel tanks should not be fitted over stairways and ladders, hot surf ayes and electrical equipment. However, there this is unavoidable; each tank shall be provided with the self draining save-all. The Board, may waive this requirement where the fuel tank is supplied as an integral part of the engine.

15.3.3 Fuel Tank Venting

The vent pipe for a fuel tank shall be of size sufficient to prevent generation of pressure. Where the tank filling is affected by pumping through the filling line, the area of air escape shall not be less than 1.25 times the area of the filling pipe. The pipe shall terminate in a gooseneck, the top of the bend not being less than the height of the bulwark or the top of the guard rail. Where the pipe outlet exceeds 18 mm in diameter a corrosion resistant wire gauges screen shall be fitted. The open area of the screen shall be not less than the cross-sectional area of the vent pipe; Where the Board considers the provision of a suitable vent pipe is not practicable it may permit a small vent hole in the filling cap.

15.3.4 Fuel Tank Inspection Opening

A suitable manhole or hand hole to facilitate cleaning and inspection shall be provided except that this requirement may be dispensed with in the case of free-standing non-portable tanks which have a capacity of less than 800 L.

15.3.5 Fuel Shut-off

15.3.5.1 A shut-off valve or cock shall be fitted in each tank outlet line. Non-metallic piping and fittings shall not be fitted in the line between the, tank and this shut-off valve or cock.

15.3.5.2 Means shall be provided outside a propulsion machinery space, in an accessible position not likely to be isolated by a fire in the space, to shut off the fuel to the main and auxiliary engines by means of a fire-safe valve or cock. Non-metallic piping and fittings shall not be fitted in the line between any fuel tank and this fuel shut-off.

15.4 Safety Devices for Power Operated Fuel Pumps and Motors.

Section 9

[PacLII Editorial Note: View PDF Original for Image]

15.4.1 If the closed discharge pressure of a cargo oil pump, fuel transfer pump or fuel pressure pump exceeds the maximum design working pressure of the discharge system, a relief valve discharging back to the suction side of the pump shall be fitted.

15.4.2 Stop valves shall be provided on the suctions and deliveries of cargo oil, fuel transfer and fuel pressure pumps.

15.4.3 A fuel transfer or a cargo oil pump which is located below deck in a machinery space shall be provided with means to stop the pump from both inside and outside the space.

15.5 Fuel Filters

Filters manufactured of steel or an equivalent material may be fitted at any position in the fuel system. See-through glass or plastic filters shall be resistant to both mechanical impact and thermal shock and may only be fitted in a protested position.

15.6 Fuel Systems for Vessels Having Engines which Operate on Fuel with Flashpoint of 60°C or More.

15.6.1 Fuel Tank Filling

Each fuel oil tank shall be provided with a permanent filling pipe of suitable material led from the deck to the top of the tank. Where the Board considers that a flexible section is necessary between the decks and tank fitting, the flexible section shall be of reinforced synthetic rubber piping which is resistant to fuel, salt water and vibrations. It shall be fastened to the deck fitting and tank fitting with corrosion resistant clips.

15.6.2 Fuel Tank Contents Measurement

Suitable means shall be provided for determining fuel tank contents and they shall be such that in the even to tank being overfilled, spillage, through them shall not occur.

Where a level indicating gauge glass is fitted on a fuel tank it shall be fitted with self-closing valves or cocks, provided that where the upper end of the gauge glass is connected to the tank through the top plating, only one such self-closing valve or cock at the lower end need be fitted. Oil fuel tank soundings should not be located in crew accommodation but where in exceptional circumstances they are located in alleyways, flush deck screwed caps should be fitted.

15.6.3 Fuel Tank Drain

Each fuel service tank having a capacity of 400 litres or more shall be fitted with a drain valve or drain cock, the open end of which is blanked with a screwed plug. Tanks having a capacity less than 400 litres shall be fitted with a screwed drain plug.

15.6.4 Fuel Filling Stations

Oil fuel filling stations shall be situated outside machinery spaces and be so arranged that any overflow cannot come into contact with a hot surface.

15.6.5 Fuel Piping

Fuel piping shall be of seamless steel or heavy gauge copper. The piping shall be connected by flanged joints, metal to metal joints of the conical type or by other acceptable means.

Where cone nipples are used they are to be welded. Olive type compression fittings shall not be used. Connections in pipes shall be kept to a minimum and shall be so located as to be readily visible and accessible. Flexible piping may be fitted:

(a) between the fuel shut-off valve required under sub-paragraph 15.3.5.2 and the engine;

(b) to conduct any fuel by-pass back to the top of the fuel tank.

Flexible piping shall be of metal braided reinforced type having a synthetic rubber inner tube and must have a high resistance to saltwater, petroleum products and vibration. It shall be capable of containing fuel after being exposed to free-burning kerosene for a period of 21 minutes. It must be so installed as to be readily visible, clear of the bilge and effectively secured to prevent chafing.

15.7 Fuel Systems for Vessels having engines which operate on Fuel with a Flashpoint less than 60’C, but not including Installations which Employ Portable Fuel Tanks.

15.7.1 Gravity Feed Fuel System

Engines employing a gravity feed fuel system will not be permitted except that this requirement may be waived in the case of small engines with a tank not exceeding 101 capacity.

15.7.2 Fuel Tank Capacity

Fuel tanks shall be no larger than necessary for the intended service of the vessel but shall be of sufficient capacity to prevent them having to be filled at sea. No loose cans of fuel shall be carried on board a vessel for this purpose.

15.7.3 Fuel Tank Location

Fuel tanks shall be securely installed in positions as remote from the engine and exhaust pipes as practicable. When they are installed in a compartment the compartment shall be well ventilated. Provision is to be made to allow, as far as practicable, the external inspection of the tanks and fittings.

15.7.4 Fuel Tank Filling Pipe

Fuel tanks shall be provided with a filling pipe so arranged as to prevent fuel spillage entering the vessel. The filling pipe is to extend internally to near the bottom of the tank and shall be fitted with a watertight cover.

Where the Board considers that a flexible section is necessary between the deck and tank fitting, the flexible section shall be of a reinforced type, having a synthetic rubber inner tube and be resistant to fuel, salt water, and vibration. It shall be secured to deck and tank fitting with corrosion resistant metal clips.

15.7.5 Fuel Pump Suction

When a fuel pump is employed the fuel shall be drawn from the tank by means of a pipe extending internally from the top of the tank to near the bottom of the tank. An anti syphon device shall be provided in the line.

15.7.6 Fuel Tank Venting

A vent pipe shall he led from each tank to an open position where no danger will arise from escaping vapour.

15.7.7 Fuel Piping

Fuel piping shall be of seamless steel or heavy gauges copper. The piping shall be connected by metal to metal joints of the conical type or by other acceptable means. Where come nipples are used they are to be welded. Olive type compression fittings shall not be used. Connections in pipes shall be kept to a minimum and shall be so located as to be readily visible and accessible. A short length of flexible piping may be fitted in the section of line between the engine bed and the fuel lift pump. Such flexible piping shall be of metal braided reinforced type having a synthetic rubber inner tube and must have a high resistance to salt water, petroleum products and vibration. It shall be capable of containing fuel after being subject to a 2½ minute exposure to free burning kerosene. It must be so installed as to be readily visible. Fuel filters may be fitted with screwed drain plugs but drain cocks on valves should not be fitted.

15.7.8 Electric Bonding

All elements of the fuel installation shall be electrically bonded.

15.7.9 Carburettor Trays

Carburettors (other than the down draught type) which can be flooded or over-flowed must be fitted with a copper or brass fuel tight drip tray. Such trays must have sweated into it not less than 13 mm below it. A corrosion resistant wire gauze screen. The tray shall be of a size sufficient to impound any leak from the carburettor and shall be readily removable for emptying.

The carburettor must be fitted with an efficient flame trap.

15.7.10 Engine Enclosure

Where a petrol engine is installed in an enclosure, the enclosure shall be well ventilated.

15.8 Fuel Systems for Vessels Having Engines which Operate on Fuel With a Flashpoint less than 60°C and which Employ Portable Fuel Tanks.

15.8.1 Portable fuel tanks shall:

(a) be not more than 301 capacity;

(b) be designed an constructed to allow case of handling and be provided with means for locating and securing against movement;

(c) be manufactured from metal which is corrosion resistant or coated to provide protection from corrosion and where necessary shall have mated parts that are galvanically compatible;

(d) have all service and vent openings above the full contents level;

(e) be fitted with a fuel contents gauge;

(f) have base areas in proportion to their height to minimise upsetting.

15.8.2 Where the vessel is fitted with a flush or sealed deck, portable fuel tanks shall be situated above that deck in such a position as to prevent any spillage of fuel from draining below the deck.

15.8.3 Where portable fuel tanks are fitted, the fuel lines shall be of heavy duty synthetic rubber fitted with bayonet type fittings which when disconnected with automatically shut off from the tank.

16. Shipside Valves and Sea Water Piping

16.1 Inlet and Discharge Valves General

All sea inlets and overboard discharge pipes shall be fitted with screw down valves or cocks unless required otherwise by the Load Lines Section and except that:

(a) discharge valves or cocks shall not be required in the case of discharges (including sanitary discharges) having bore diameters not exceeding 50 mm, and the lowest points of which are not less than 230 mm above the load water line; and

(b) discharges which are led through the vessels side from spaces above the bulkhead deck may be fitted with non-return valves in lieu of screw down valves or cocks.

16.2 Requirements for Valves and Cocks

16.2.1 Valves and cocks shall be of bronze, cast steel or equivalent material. Where a valve with a screwed cap is a sea injection valve or a valve controlled by an extended spindle, the cover shall be secured so that it cannot slacken when the valve is operated.

16.2.2 Shipside valves and cocks with a bore greater than 50 mm shall be of the flanged type. Valves and cocks not greater than 50 mm bore may be of the screwed type.

16.3 Fitting of Valves and Cocks

16.3.1 Flanged valves and cocks shall be mounted on suitable pads or flanges which are secured to:

(a) the hull of the vessel;

(b) suitable water boxes; or

(c) standpipes which shall be as short as practicable.

16.3.2 Valves and cocks of the screwed type shall be secured to the hull of the vessel by means of a suitable skin fitting or standpipe. The finished wall thickness of any such fitting or stand pipe shall not be less than the thickness of the hull plating to which it is attached.

16.3.3 The valves or cocks must be so fitted that they are readily accessible at all times.

16.4 Gratings

Gratings shall be fitted on the outside of the hull, to all sea water inlets. The clear area through the gratings shall be not less than twice the area of the valve connected.

16.5 Pipe Materials

All pipes that can be placed in communication with the sea are to be a heavy gauge copper or steel. Suitable reinforced synthetic rubber piping having a high resistance to salt water, fuel oil, heat and vibration, and capable of operation under suction without collapse and resultant reduction in effective area, may be used:

(a) in short lengths for vibration damping;

(b) in vessels of less than 15 mm length, provided that the length of piping does not exceed half the beam of the vessel, the run of piping is direct as practicable and it is adequately supported.

When installed the rubber piping shall be readily visible and protected against mechanical damaged and contact with hot surfaces.

16.6 Securing of Flexible Pipe

The method of securing a flexible pipe to a rigid pipe or fitting shall be by corrosion resistant clips or pressed ferrules.

For flexible piping of 25 mm internal diameter and above not less than two clips shall be fitted at each end.

16.7 Material of Pipe Fittings

The material of pipe fittings shall not be of malleable iron.

17. Bilge Pumping Arrangements

17.1 General

17.1.1 Subject to paragraph

17.1.2 Every vessel shall be provided with a pumping system capable of pumping from and draining any water tight compartment in the vessel.

17.1.2 A watertight compartment less than 7% of the total under deck volume may be drained into the adjacent compartment by means of a self-closing valve or cock. The valve or cock shall be fitted outside the compartment to be drained and shall be operable from a readily accessible position.

17.1.3 In the case of a vessel of Classes 1, 2,3A or 3B 15 m length and over the system shall permit pumping and draining from every space in the vessel whilst any one watertight compartment is flooded.

17.2 Number and Capacity of Pumps

Vessels shall be provided with bilge pumps in accordance with the following table:

17.3 Pump Details

In any vessel:

(a) a power pump may be substituted for a manually operated pump;

(b) a power pump may be driven by a main engine, an auxiliary engine or by an electric motor. However, where 2 power pumps are required, each pumps shall not be dependent on the same source of power;

(c) where a vessel is required by sub-clause 17.2 to be fitted with 2 power pumps and the capacity of one of those pumps is less than that specified by not more than 20%, the deficiency may be made good by an excess of capacity in the other power pump; and

(d) a bilge pump shall be of the self priming type or be provided with a suitable priming device.

17.4 Pipe Materials

17.4.1 All bilge piping shall be of steel or heavy gauge copper, except that non-metallic bilge piping may be used on vessels of Class 30, which are less than 15 m in length.

17.4.2 Notwithstanding the provisions of 17.4.1 and subject to 17.5 reinforced synthetic rubber piping may be used as tail pipes.

17.4.3 Where non-metallic bilge piping is used it shall have a high resistance to saltwater, fuel oil, heat and vibration and be capable of operating under suction without collapse and resultant reduction ineffective area.

17.5 Strainers

17.5.1 On vessel of 20 m in length and over each bilge suction in a machinery space shall be fitted with a mudbox and metallic tail pipe. All other bilge suctions shall be fitted with a mudbox strum box or strainer. The Board may give special consideration to the aforementioned arrangements having regard to the accessibility of a bilge suction.

17.5.2 Strainer holes shall not be greater than 10 millimetres diameter and the aggregate area of the holes shall not less than twice the area of the suction pipe.

17.6 Back Flooding

Bilge piping arrangements shall be so arranged as to prevent water passing from the sea into holds or machinery spaces, or where the length of a vessel is 25 m and over from one watertight compartment to another. The bilge connection to any pump which also draws from the sea shall be either a screw down non-returning valve, or a cock which cannot be opened at the same time to the bilges and to the sea. Where the length of a vessel is 25m and over valves in bilge distribution boxes shall be of a non-return type.

17.7 Pipe Sizes

17.7.1 In vessels of 10 m and over in length the diameter of bilge suction pipes is to be not less than that determined by the following:

(a) d_m = 2.5=1.68 √L (B + D)

(b) d_b = 25=2.16, √C (B + D)

where d_m = internal diameter of the main bilge suction pipe in mm

d_b = internal diameter of branch suction pipes in mm

L = the measurement length of the vessel in m

B = breadth of vessel in m

D = depth of vessel in m

C = length of compartment in m.

No main or branch suction piping is to be less than 32 mm in diameter.

17.7.2 In vessels of less than 10 m in length, the diameter of the bilge piping shall not be less than 25 mm.

17.8 Bilge Level Alarm

In all decked vessels other than Class 3E vessels, the space in which the propulsion machinery is located shall be fitted with a bilge level device which is connected to an audible alarm located near the steering position. The power supply for the audible alarm shall be available at all times there is any person on board.

With the machinery operating under full power conditions the alarm shall, when operated, be clearly audible at the steering position.

18. Fish Tank Pumping Systems

18.1 Non-Metallic Piping

18.1.1 Non-metallic piping may be used for filling cargo tanks provided that:

(a) bilge alarms are fitted in each compartment in which the piping is installed;

(b) the sea suction valves can be readily closed from a position above the bulkhead deck;

(c) any penetration by the piping of a machinery space bulkhead is via suitable valve; and

(d) all connections to the tanks are readily accessible and have valve attached directly to the tanks or to heavy gauge metal piping attached directly to the tanks and provided that where the connections are not near the top of the tanks, the valves shall be capable of being readily closed from position above the bulkhead deck or shall be non return valves.

18.1.2 Non-metallic piping maybe used for discharging fish cargo to compliance with sub-paragraph (a), (c) and (d) of paragraph 18.11

Collision Bulkhead Valve

A pipe piercing a collision bulkhead shall be fitted with a screw down valve or cock at the bulkhead. The valve or cock shall be controllable from the bulkhead deck and an appropriate open close indicator shall be provided. If the valve cork is fitted on the after side of the bulkhead and is readily accessible under all service conditions, the remote control may be dispensed with.

20. Sounding Devices and Sounding Pipes

20.1 A suitable means shall be provided for determining the liquid content

(a) any weight compartment, which is not part of the machinery space, including a cofferdam and a double bottom tank; and

(b) any cofferdam and double bottom tank which is located in the machinery space.

20.2 Where a sounding pipe is fitted it shall:

(a) for a pipe located outside of the machinery space, extend to a readily accessible position on deck;

(b) for a pipe located in a machinery space, extend to a readily accessible position. It shall extend to deck level or to a lesser height if the pipe is furnished with a cock having a parallel plug with a permanently secured handle so loaded that on being released in automatically closes the cock; and

(c) terminate in such a position that there is no danger of overflow spillage onto hot surfaces or electrical equipment.

20.3 The upper end of a sounding pipe shall be provided with means of closing to prevent the free entry of water.

20.4 A sounding pipe shall be as straight as practicable and if curved to suit the shape of the vessel, the curvature shall be sufficient to permit the passage of a sounding rod or a sounding chain.

20.5 A sounding pipe shall be of metal not less than 4.5 mm in thickness and be not less than 32 mm internal diameter.

20.6 A sounding pipe shall be protected against mechanical damage and where it passes through any refrigerated space shall be thermally insulated.

20.7 A striking plate shall be fitted under the lower end of a sounding pipe.

21. Steering Gear

21.1 All vessel except twin screw vessels shall be fitted with two effective independent means of steering, one of which may be a hand tiller, except that where the normal means of steering is a hand tiller an alternative means need not be provided. The secondary or emergency gear shall be capable of being brought speedily into action.

21.2 Design

21.2.1 The steering gear arrangement shall be of adequate strength and sufficient to steer the vessel at maximum speed. The steering gear shall be so designed that it is not damaged at maximum astern speed.

21.2.2 Components that transmit torque, tensile stresses or shock loads shall not of ordinary cast iron or other similar non-ductile material.

21.2.3 Rudder movement should be 35° port and starboard and formulae indicated in clause 22 are based on these helm angles. Rudder movement less than or in excess of 35 shall only be permitted with the approval of the Authority and in such cases the Authority may allow a reduction or require an increase in the diameter of the rudder stock.

21.2.4 In a vessel of 10 m length and over the steering gear shall be capable of putting the rubber over from 35 on side to 30° on the other in 30 seconds when the vessel is at maximum ahead service speed with the rudder totally submerged, and, if normally operated shall be designed to prevent violent recoil of the steering wheel.

21.3 Hydraulic Systems

Hydraulic Steering Systems shall meet the requirements of clause 25 and otherwise comply with the following:

21.3.1 Means to facilitate a quick change over from the primary to the secondary steering shall be fitted.

21.3.2 In power systems a relief value shall be installed and set to prevent mechanical damage to the steering gear.

21.3.3 Hydraulic piping shall be so arranged to avoid the possibility of damage.

21.4 Helmsman’s View

The steering arrangement shall be such that the operator has a clear view ahead in the normal steering position.

21.5 Rudder Movement Direction

21.5.1 The trailing edge of the rudder blade of a vessel shall move in the same direction as the top spokes of the steering wheel.

21.5.2 In a vessel of 15 m and overfilled with power operated steering gear, a rudder position or shall be fitted. It shall be so placed as to be in full view of the helmsman whilst he is at the normal steering position.

21.6 Transmission Shaft Bearings

Steering gear transmission shafts shall be adequately supported in bearings spaced not more than 70 times the diameter of the transmission shaft, provided that bearing spacing adjacent to sprockets or gears is such that no undue bending load can, be applied to the shaft.

21.7 Tiller Arm

21.7.1 The section modulus of a tiller arm just clear of the boss, or quadrant just clear of the boss, shall not be less than:

where Z = section modulus of quadrant or tiller in cm3 about the vertical axis

d = required diameter of the upper rudder stock in mm

a = distance from the point of application of the load on the tiller or quad-rant to the centre of the rudder stock in mm

b = distance between the section of tiller or quadrant just clear of the boss and centre of the rudder stock in mm.

For tillers of rectangular section, the ratio between the breadth and thickness is not to be greater than 3.

Note:

This formula is based on the material of the tiller arm and upper rudder stock being carbon steel having a U.T.S. of 410 MPa.

21.7.2 The section modulus at the point of application of the load is to be not less than one third of that required by paragraph 21.7.1.

21.7.3 The outside diameter of the tiller arm boss or quadrant boss is to be not less than 1.8 times the rudder stock diameter and the depth is to be not less than the rudder stock diameter.

21.7.4 The distance from the tiller arm boss to the nearest bearing, gland or other support should not exceed 2.5 times the required diameter of the rudder stock.

22. Rudder and Rudder Stocks

22.1 Materials

22.1.1 Unless otherwise stated, rudder couplings, coupling bolts, gudgeons and similar parts subject to dynamic stress shall be manufactured from materials complying with the requirements of paragraph 14.6.2.

22.1.2 Unless otherwise stated rudder plating and stiffeners shall be of material complying with those requirements specified for hull material in the Construction Section (Steel Vessels).

22.2 Upper Stock Size

A rudder stock above the top pintle for an unbalanced rudder or above the neck bearing for a balanced rudder is to be not less than obtained from the formula:

d = C ³√RAV²

where d=diameter of upper stock in mm

R = distance in mm from the centre line of stock to the centre of area of A

A = area of rudder in m

V = sea speed of vessel in knots with:

a minimum of 8 in vessels up to 30 m in length;

a minimum of 9 in vessels of 30 m in length and over

C for vessels up to 30 m in length:

= 21.66 where V =8

= 19.2 where V =14 or over.

For values of V between 9 and 15, C may be obtained by interpolation.

22.3 Unbalanced Rudder Main Piece Size

For an unbalanced rudder, the main pipe shall be of the required diameter for the upper stack at the top arm of a single-plate rudder or the top of a built up rudder but the diameter may be gradually reduced until it is 0.75d at the bottom.

22.4 Balanced Rudder Lower Stock Size

22.4.1 For a balanced rudder, the stock in way of and below neck bearings shall have diameters not less than obtained from the following equation:

d_i = C ³√RAV ²

where d_i=diameter of lower stock in mm

R =0.25(a+ a²+ 16 b²) for a balanced rudder which has efficient neck and bottom bearings.

R =a+ a²+b² for a balanced rudder which has no bottom bearings.

A = area of rudder in m²

a = vertical distance from the bottom of the neck bearing to the centre of area of A in m

b = horizontal distance from the centre of the lower stock to the centre of area of A in metres

V = speed of vessel in knots with a minimum of 8 in vessels up to 30 m in length and a minimum of 9 in vessels of 30 m in length and over.

C shall be determined according to the following:

(a) where the speed of the vessel is not greater than 4 LWL, LWL being the length of the vessel in m at the designed waterline, and the length of the vessel is less than 30m.

C = 21.66 where V = 8

C = 19.20 where V = 14 and over

For values of V between 8 and 14, C may be obtained by interpolation;

(b) where the speed of the vessel is not greater than 4 LWL, with LWL being the length of the vessel in m at the designed waterline, and the length of the vessel is 30m in length and over.

C = 21.66 where V = 9

C = 19.20 where V = 15 and over

For values of V between 9 and 15. C may be obtained by interpolation; or

(c) where the speed of the vessel is greater than 4 LWL, LWL being the length of the vessel in m at the designed waterline and the length of the vessel is less than 30m.

C = 16

22.4.2 The main piece of a balanced rudder having efficient neck and bottom bearings is to be full diameter for at least 2/3 of the distance from the neck to the bottom bearing. The diameter may be gradually reduced below this point until it is 0.75d, in the bottom bearing. The main piece is to extend into the bottom bearing for a distance not less than 0.7d. Both bearings are to be bushed.

[PacLII Editorial Note: View PDF Original for Image]

22.4.3 The stock of balanced rudder having no bottom bearing is to be full diameter, to the under side of the top rudder arm if a single plate rudder, or to the top of the rudder if a built-up rudder. The diameter may be gradually reduced below this point until it is 0.5d, and the length of stock in way of the rudder shall not be less than 2/3 of the depth of the rudder at the centre line of the stock.

22.5 Rudder Stock Sizes of Material other than Carbon Steel.

The diameter of a rudder stock or main piece of material other than carbon steel shall be:

d ³√⁴¹⁰/_T

where d equals the diameter of the rudder stock in millimetres as required by sub-clause 22.2 and 22.4 and T equals the minimum ultimate tensile strength of the material in MPa.

22.6 Rudder Bearings and Pintles

22.6.1 The neck bearing for rudders shall be bushed, be of the type shown in Fig. 22.4 (b) and not be less in depth than 1.5 times the required stock diameter. For spade rudders of the type shown in Fig. 22.4 (a) the neck bearings shall not be less in depth than 4 times the required stock diameter unless an upper bearing is fitted. Bearings are to be adequately supported and housings effectively attached to the vessel’s structure.

22.6.2 The diameter of rudder pintles shall not be less than 0.75 times the required diameter of the rudder stock, and the depth of pintle bearings shall not be less than the required diameter of the pintle.

22.6.3 Where more than one pintle is fitted the required diameter may be reduced by 10 per cent for each additional pintle fitted.

22.7 Coupling Types

Some acceptable forms of flanged rudder couplings are as follows:

(a) Couplings of fabricated construction, provided that they are suitably designed, prepared and heat treated subsequent to welding;

(b) Couplings formed by upsetting the end of the stock provided that there is no necking or narrowing of the stock;

(c) Couplings fitted on a taper, keyed and held in place by a nut.

22.8 Coupling Dimensions

The scantlings of rudder couplings are to be in accordance with the following:

22.8.1 The thickness of the flange shall be:

(a) for a rudder with a pintle or bottom bearing not less than 0.25 times the diameter of the rudder stock or equal to the required diameter of the coupling bolts whichever is the greatest; and

(b) for a spade rudder not less than 0.3 times the diameter of the rudder stock or equal to the required diameter of the coupling bolts whichever is the greater.

22.8.2 The fillet radius at the base of the flange shall not be less than 0.125 times the diameter of the stock.

22.8.3 The ligament thickness outside the coupling bolt holes shall not be less than 0.6 times the diameter of the coupling bolt.

22.8.4 The pitch circle radius of bolts for couplings of the forged or welded flange type shall not be less than the diameter of the rudder stock, and for couplings keyed to the stock shall be not less than 1.25 times the diameter of the rudder stock.

22.8.5 Couplings keyed to the stock shall be provided with keys of the type specified in paragraph 14.9.3 and having width and thickness in accordance with paragraph 14.9.4 or 14.9 as appropriate.

22.8.6 The boss thickness of keyed couplings shall not be less than 1.5 times the required thickness of the key and the boss length shall not be less than 1.5 times the required diameter of the rudder stock.

22.8.7 Where a rudder stock is 150 mm or more in diameter at least 6 bolts are to be used in each coupling flange. Where the diameter is less than 150 mm, at least 4 bolts are to be used in each coupling flange. The total area of bolts is not to be less than that determined from the following formula:

where A=total bolt area in mm’ at root of threads

R = pitch circle radius of bolts in mm

d = required diameter upper stock in m.

22.8.8 Rudder coupling bolts shall be machine finished, neat fitting and the nuts shall be effectively locked.

22.9 Spade Rudders

Acceptable forms of spade rudder are as follows:

22.9.1 Fabricated or cast rudder blade with integral flange secured to a rudder stock with flange by fitted bolts. (With this type of rudder the sizes of the couplings and bolts are to be based on the required diameter of the lower rudder stock, but due regard shall also be given to the bending and tensile stresses to which they may be subject arising from the forces on the rudder.).

22.9.2 Fabricated or cast rudder blade attached to rudder stock by means of a taper with key and securing nut. (The length of the taper is not to be less than 1.5 times the required diameter on the lower rudder stock. The taper is to be between the limits of m 12 and 1 in 16 on diameter, but should preferably be in 1 in 12).

22.9.3 Fabricated rudder blade integral with rudder stock.

2.9.4 Fabric Ad or cast rudder blade shrunk onto a parallel rudder stock and additionally secured with dowells.

22.9.5 Rudders with the blade cast on to the rudder stock are subject to the approval of the Board. The approval will be dependent upon the design and construction method and may also be dependent on the result of proof load testing.

22.9.6 Cast rudder blades shall be of ductile material.

22.9.7 The pressure on the rudder bearings should, in general, not exceed 3.9 MPa. For bearings with efficient lubrication a pressure of 5.9 MPa may be accepted.

For the determination of the pressure on the bearings the rudder force may be calculated from the following formula:

F_p = 196AV ²

where A = area of rudder in m²

V = speed of vessel in kn

22.10 Single Plate Rudders

22.10.1 A single plate rudder with upper stock diameter measuring 75mm or less shall have a plating thickness not less than obtained from the formula:

t = 0.15d + 6.

A single plater rudder with upper stock diameters d measuring more than 75 mm shall have a plating thickness not less than obtained from the formula

t = 0.04d + 14.

where

t = thickness of rudder plate in mm

d = required diameter of upper rudder stock in m.

Where speed of the vessel exceeds 15 kn, the required thickness of the rudder plate shall be increased at the rate of 1mm/km of excess speed.

Where distances between centres of rudder stiffeners are less than obtained from the formula in 20.10.2 the thickness of the rudder plating t, may be given special consideration.

22.10.2 The distance between the centres of single plate rudder stiffeners is not to be greater than that obtained from the following formula:

h = 2.5d + 952.5

where

h = vertical distance between the centres of stiffeners in mm;

d = required diameter of upper rudder stock in m.

The section modulus (Z) in way of the stiffeners immediately forward and aft of the stock is not to be less than that obtained from the following formula:

Z=0.8 (d-51) cm³

The breadths ‘b’ of the stiffeners may be taped forward and aft of the maximum breadths required to satisfy the above section modulus. However, the breadths at the leading and trailing edges of the rudder are not to be less than obtained from the following formula:

b = 0.1d+8

where b = breadth of the stiffeners in mm.

22.10.3 The blade of a single plate rudder shall be attached to the main piece by a full penetration continuous weld. Stiffeners shall be attached to the main piece and blade by a double continuous fillet weld.

Double Plate Rudders

22.11 Double Plate Rudders

22.11.1 Double plate rudders are to have horizontal internal webs.

22.11.2 In the case of a vessel less than 20 metres in length the thickness of plating for a double plate rudder shall be in accordance with table 22.11.2.

TABLE 22.11.2.

Horizontal and vertical webs in double plate rudders not replacing the main piece are to have the same thickness as the side plates. Plates forming the top and bottom of the rudders are not to be less than the thickness given in column (4).

22.11.3 Where the required rudder stock diameter exceeds 75 mm the thickness of the rudder side plating and webs is not to be less than obtained from the following formula:

t = 6.5 + 0.117V A

where:

The distance between centres of the webs is not to be greater than obtained from the formula:

Sp = 585 + 2.41V A

where:

Sp = distance between centres in mm; and V & A are as defined above.

The thickness of the plating is to be increased at the rate of 0.015 mm for each mm of spacing greater than that given by the formula and may be reduced at the same rate for lesser spacing.

22.11.4 Special attention is to be given to the attachment of the rudder arms, pintle gudgeons and rudder coupling to the body of the rudder.

Horizontal and vertical stiffeners in double plate rudders are to be attached to the main piece by continuous double fillet welds and to the plating by fillet welds consisting of 75 mm increments spaced 150 mm between their centres. Where the interior is inaccessible for welding the stiffeners shall he fitted with flat nor of the flat bars and the plating connected to these flat bars by continuous or slot welds.

22.11.5 Double plate rudders are to be watertight. Means for draining the rudder shall be provided. Double plate rudders are to be tested by a head of water of 2.5m or equivalent.

22.12 Wooden Rudders and Steering Nozzles

The construction and scantlings of wooden rudders and steering nozzles shall be specially considered.

22.13 G.R.P. Rudders

G.R.P rudders are to incorporate a substantial steel spider formed by perforated plate arms, approximately half the rudder width in length and welded to the rudder main piece. The main piece is to continuous through the rudder but where this is not possible owing to the design at the rudder, suitable arrangements are to be made to ensure continuity of strength and alignment. The blade is to be moulded from mats with or without woven rovings, and is to be bonded with epoxy or polyester resins. The rudder is to be filled with a suitable material such as resin/glass dough or a micro-balloon mixture.

22.14 Rudder Support

The weight of a rudder is to be suitably supported at the heel pintle or by a suitable carrier bearing. The structure in way of a carrier bearing is to be adequately strengthened for that purpose.

22.15 Rudder Stops

22.15.1 Effective means shall be provided to limit vertical movement of the rudder.

22.15.2 Effective stops to prevent the rudder coming into contact with the Propeller or hull shall be provided.

23. Windlass

23.1 A mechanical lifting device provided in a vessel to meet the requirements of the Miscellaneous Equipment Section shall constitute a windlass of capstan. Cable stoppers, claws or similar fastenings shall be provided as necessary between the windlass or capstan and the hawse pipe. The windlass or capstan is to be designed for immediate dropping of the anchor and with an efficient brake.

23.2 For an anchor mass of less than 50 kg, the windlass or capstan may be hand operated provided that the applied efforts shall not exceed 155 N when lifting the anchor and total length of cable fitted.

23.3 For an anchor mass of 50 kg and above a power operated windlass or capstan shall be provided. It shall be capable of lifting one anchor and 35 m of its chain cable plus a 20 per cent overload at a speed of not less than 7.5m per minute.

24. Air Compressors

A compressor for the supply of compressed air for purposes other than breathing apparatus shall be in accordance with the following.

24.1 An air compressor shall be provided with a relief valve of such size and set that when the compressor discharge valve is closed and the compressor is running normally, the maximum accumulation pressure will not exceed the working pressure by 10 percent.

24.2 The casing of an air cooler of an air compressor shall be fitted with a relief valve or a safety diaphragm to provide protection against an air tube bursting.

24.3 An air compressor shall be provided with means for draining water and oil from the inter and discharge stages.

24.4 The air intake for a compressor shall be so located to minimise the induction of oil vapours.

24.5 An air compressor shall be so designed and installed that the temperature of the air delivered from the after cooler does not exceed 93°C.

24.6 A pressure gauge shall be fitted between the after cooler and the compressor I I.P. discharge.

25. Hydraulic Power Systems

25.1 Hydraulic pumps shall have pressure relief protection on the discharge side which shall operate in closed circuit.

25.2 The materials of hydraulic pumps, motors and accessories shall be compatible with the working fluid. Hydraulic fluid shall be non-flammable or shall have a flash point of 157°C or over.

25.3 Hydraulic hose shall comply with Australian Standard B226. Installation and fittings shall be in accordance with the manufacturer’s requirements.

26. Pressure Pipes

26.1 General

26.1.1 Unless specified elsewhere in this Section the requirements of this clause shall apply to pipes the working pressure of which is 700 kPa and over.

26.1.2 The design of steel pipe work shall comply with Australian Standard CB 18.

26.2 Copper

Copper and copper alloy pipes shall be of seamless construction. When pipes other than those of seamless construction are proposed, they will be specially considered by the Fiji Marine Board.

26.3 Cooper Pipe Thickness

26.3.1 The minimum thickness of copper and copper alloy pipes shall be determined by the following formula:

where t = wall thickness in mm

WP = working pressure in kPa

d = one side diameter of the tube in mm

f = maximum allowable stress in MPa at the appropriate working temperature (see Table 2.6.3).

c = 0.75 mm

26.3.2 Where copper and copper alloy pipes are to be bent, the thickness as obtained in paragraph 26.3.1 shall be increased by 10 per cent to allow for thinning at the bend. In no case shall the radius of curvature at the centre line of the pipe be less than twice the external diameter of the pipe.

26.4 Copper Pipe Heat Treatment

Copper pipes shall be annealed and copper alloy pipes heat treated in accordance with the manufacturer’s recommendation.

26.5 Reducing Valves

Where a pressure pipe or fitting may receive supply from any source at a higher pressure than that for which the pipe or fitting is designed, an efficient reducing valve shall be fitted. An efficient relief valve of sufficient size together with a pressure gauge shall be fitted on the low pressure side of the reducing valve.

TABLE 26.3

PART 4-ELECTRICAL

27. Electrical Equipment Extra Low Voltage

27.1 This clause shall apply where the electrical supply does not exceed 32 volts D.C.

27.1.2 Details of electrical power supply arrangements for radio shall comply with requirements of the Radio Equipment Section.

27.1.3 In every installation all necessary precautions shall betaken to limit electrical equipment from affecting navigational aids.

27.1.4 Electrical installations associated with an engine using fuel having a closed flash point of less than 60°C, shall be specially considered by the Authority.

27.2 Distribution

27.2.1 The distribution of electrical power shall be by the two wire insulated system. The use of a hull return for lighting or power distribution is not permitted.

27.2.2 The voltage drop in any circuit shall not exceed 10% of the design voltage. Maximum permissible current ratings shall be in accordance with:

(a) the cable manufacturer’s recommendations; or

(b) Tables 27.2.2 (A), (B), (C) and (D) or (E) whichever of (A) and (B) gives the least listing.

27.2.3 Circuits supplying two or more final sub-circuits are to be rated in accordance with the total connected load subjects, where justified, to the application of a diversity factor. Where space ways are provided on a main or sub-switchboard or distribution board an allowance for future increases of load is to be added to the total connected load before application of any diversity factor. The diversity factor may be applied to the calculation for size of cable and rating of switch gear and fuse gear.

27.2.4 Final Sub-Circuits

The number of points that maybe connected to a final sub-circuit is limited only by the connected load. In determining the connected load, the loading is to be determined as follows:

(a) the loading of lamp holders is to be taken as:

(i) 60 watts of the wattage of the largest lamp which could be inserted, whichever is the greater;

(ii) in the case of a fluorescent lamp, the wattage of that lamp;

(b) the loading of the plug sockets is to be taken as 160 watts or the actual wattage of the appliance to be connected, whichever is the greater;

(c) the loading of permanently connected appliances is to be taken as the actual wattage of the appliance.

The connected load so determined is not to exceed the rating of the fuse or fuses required to protect the conductors.

Where protection of the final sub-circuit is by a circuit breaker having a fixed over current setting there is no limit to the number of points that may be connected to the circuit having regard both to the suitability of the circuit breaker setting and the maximum permissible current carrying capacity of the cable. Where circuit breakers having adjustable load setting are used, the above limitations of this paragraph shall apply. A separate final sub-circuit is to be provided for every motor required for an essential service.

Notes: Correction Factors for Current Ratings.

(i) Where more than six cables are bunched together a derating correction factor of 0.85 is to be applied to the current rating of the cable shown in Table 27.2.2A.

(ii) When it is known that the ambient temperature is other than 45°C the current rating is to be multiplied by the appropriate correction factor as shown in Table 27.2.2C

(iii) Where the load is intermittent the correction factors shown in Table 27.2.2D are to be multiplied by the current rating of the cable shown in Table 27.2.2A no case is shorter rating than a one half hour rating to be used.

TABLE 27.2.2B

INSULATION TEMPERATURE RATINGS

TABLE 27.2.2C

TABLE 27.2.2 D

CORRECTION FACTOR FOR INTERMITTENT SERVICE

TABLE 27.2.2E

AUTOMOTIVE CABLES COMPLYING WITH AUSTRALIAN STANDARD 2218- CONDUCTOR DETAILS