CARBON FIBRE REINFORCED PLASTIC (CFRP) FERRY BOATS

  The use of fibre-reinforced plastic has become firmly established in boat building over many years. The advantage lies in the simple practicability of free form shapes compared with the use of conventional materials such as wood or steel.  This results in a very varied scope for design. With targeted use of sandwich constructions, it´s possible to produce lightweight components with high specific mechanical values.

The application of carbon fibers and epoxy resin, in combination with lightweight Nomex honeycombs enables a maximum optimization of weight and stability for uses in water sports from regatta boats, to rowing boats or highly specialized sailing yachts for racing purposes. Nowadays this material combination is also increasingly used for building luxury yachts.

When constructing pleasure boats or large scale production yachts the optimal cost-benefit-ratio of fiber-glass reinforced plastics has resulted in it being used as a standard material.

In the sectors of commercial shipping, passenger transport and the navy; for example ferries, cruise ships or frigates, special fire prevention properties are needed to offer the highest possible safety for the passengers and crew. Fibre-glass reinforced plastics can only fulfill these standards through the use of special raw-materials.

As a general rule the materials for ship and boat building have to be approved by the Germanischer Lloyd, Lloyds Register or Det Norske Veritas.

Carbon fibre reinforced polymer is a type of fibre composite material in which carbon fibres constitutes the fibre phase. Carbon fiber is a group of fibrous materials comprising essentially elemental carbon. This is prepared by pyrolysis of organic fibres. PAN-based (PAN-poly acrylo nitrile) carbon fibres contains 93-95 percentage carbons, and it is produced at 1315°C (2400°F). Carbon fibres have been used as reinforcement for albative plastics and for reinforcements for lightweight, high strength and high stiffness structures. Carbon fibres are also produced by growing single crystals carbon electric arc under high-pressure inert gas or by growth from a vapour state by thermal decomposition of a hydrocarbon gas.

CFRP materials possess good rigidity, high strength, low density, corrosion resistance, vibration resistance, high ultimate strain, high fatigue resistance, and low thermal conductivity. They are bad conductors of electricity and are non-magnetic.

Strengthening measures are required in structures when they are required to accommodate increased loads. Also when there are changes in the use of structures, individual supports and walls may need to be removed. This leads to a redistribution of forces and the need for local reinforcement. In addition, structural strengthening may become necessary owing to wear and deterioration arising from normal usage or environmental factors.

INTRODUCTION
PROPERTIES OF CARBON FIBRE
MARKET SURVEY
PRESENT MANUFACTURERS OF FIRRY BOATS
DETAILS OF COMPOSITE MATERIALS
MANUFACTURING PROCESS OF CFRP FERRY BOAT
PROCESS FLOW DIAGRAM
PROPERTIES OF CARBON FIBRE REINFORCED POLYMER
BLACK DIAGRAM FOR FERRY BOAT
CONSTRUCTION METHOD OF HULL
GENERAL CONDITION IN BOAT BUILDING
TECHNICAL DETAILS IN BOAT BUILDING
APPLY RESIN BEFORE REINFORCEMENT
DESIGN AND CONSTRUCTION CONSIDERATION
CHOICE OF PROPULSION
PRINCIPLES OF PLANT LAYOUT
PLANT LOCATION FACTORS
EXPLANATION OF TERMS USED IN THE PROJECT REPORT
PROJECT IMPLEMENTATION SCHEDULES
SUPPLIERS OF PLANT AND MACHINERY
SERVICE PROVIDER FOR BOAT DESIGNING/ BUILDING

APPENDIX – A :

1.      COST OF PLANT ECONOMICS
2.      LAND & BUILDING
3.      PLANT AND MACHINERY
4.      FIXED CAPITAL INVESTMENT
5.      RAW MATERIAL
6.      SALARY AND WAGES
7.      UTILITIES AND OVERHEADS
8.      TOTAL WORKING CAPITAL
9.      COST OF PRODUCTION
10.      PROFITABILITY ANALYSIS
11.      BREAK EVEN POINT
12.      RESOURCES OF FINANCE
13.      INTEREST CHART
14.      DEPRECIATION CHART
15.      CASH FLOW STATEMENT
16.      PROJECTED BALANCE SHEET