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type of marine vehicle



    Seagoing marine vehicles may be divided into   transport , including cargo, container and passenger ships and   nontransport   including  fi  shing vessels, service craft such as tugs and supply vessels, and warships. An overview of the wide range of ship types is given in   Figure. Each vessel type has a particular role to play and each will have a different set of design and operational conditions. This chapter provides a brief review of the main design and operational features of the principal types of marine vehicle.  

     Merchant ships 



    The development of merchant ship types has been 
dictated largely by the nature of the cargo and the 
trade routes. They can be classifi  ed accordingly with 
the major types being: 
  ●       general  cargo  ships  
  ●       container  ships  
  ●       tankers  
  ●       dry  bulk  carriers 
  ●       passenger  ships  
  ●       tugs. 


General  cargo  ships




    The industry distinguishes between   break bulk   cargo which is packed, loaded and stowed separately and   bulk cargo which is carried loose in bulk. The general cargo carrier (  Figure 2.2     ) is a fl  exible design of vessel which will go anywhere and carry a wide variety of cargo. The cargo may be break bulk or containers. Such vessels have several large clear open cargo-carrying spaces or holds. One or more decks may be present within the holds. These are known as  ’ tween decks and provide increased fl  exibility in loading and unloading, permit cargo segregation and improved stability. Access to the holds is by openings in the deck known as hatches.     Hatches are made as large as strength considerations permit in order to reduce the amount of horizontal movement of cargo within the ship. Typically the hatch width is about a third of the ship’s beam. Hatch covers are of various types. Pontoon hatches are quite common in ships of up to 10 000       dwt, for the upper deck and  ’ tween decks, each pontoon weighing up to 25 tonnes. They are opened and closed using a gantry or cranes. In large bulk carriers side rolling hatch covers are often fi  tted, opening and closing by movement in the transverse direction. Another type of cover is the folding design operated by hydraulics. The coamings of the upper or weather deck hatches are raised above the deck to reduce the risk of fl  ooding in heavy seas. They are liable to distort a little due to movement of the structure during loading and unloading of the ship. This must be allowed for in the design of the securing arrangements. Coamings can provide some compensation for the loss of hull strength due to the deck opening. 
    A  double  bottom  is  fi  tted along the ship’s length, divided into various tanks. These may be used for
fuel, lubricating oils, fresh water or ballast water. Fore and aft peak tanks are fi  tted and may be used to
carry ballast and to trim the ship. Deep tanks are often fitted and used to carry liquid cargoes or water ballast.
Water ballast tanks can be fi  lled when the ship is only partially loaded in order to provide a suffi  cient draught for stability, better weight distribution for longitudinal strength and better propeller immersion.
    Cranes and derricks are provided for cargo handling. Typically cranes have a lifting capacity of 10–25 tonnes with a reach of 10–20 m, but they can be much larger. General cargo ships can carry cranes or gantries with lifts of up to 150 tonnes. Above this, up to about 500 tonnes lift they are referred to as heavy lift ships.
    The machinery spaces are often well aft but there is usually one hold aft of the accommodation and
machinery space to improve the trim of the vessel when partially loaded. General cargo ships are generally
smaller than the ships devoted to the carriage of bulk cargoes. Typically their speeds range from 12 to 18 knots.  




    Refrigerated  cargo  ships  (Reefers)
 A refrigeration system provides low temperature holds for carrying perishable cargoes.



The holds are insulated to reduce heat transfer. The cargo may be carried frozen or chilled and holds are at different temperatures according to requirements. The possible effect of the low temperatures on surrounding structure must be considered. Refrigerated fruit is carried under modified atmosphere conditions. The cargo is maintained in a nitrogen-rich environment in order to slow the ripening process. The costs of keeping the cargo refrigerated, and the nature of the cargo, make a shorter journey time desirable and economic and these vessels are usually faster than general cargo ships with speeds up to 22 knots. Up to 12 passengers are carried on some, this number being the maximum permitted without the need to meet full passenger ship regulations.  

   Container  ships 


    Container ships are a good example of an integrated approach to the problem of transporting goods.




 Once goods are placed in the container at a factory or depot, they can be carried by road, rail or sea, being transferred from one to another at road or rail depots or a port. The container need not be opened until it reaches its destination. This makes the operation more secure. The maritime interest is primarily in the ports and ships but any element of the overall system may impose restrictions on what can be done. Height of container is likely to be dictated by the tunnels and bridges involved in land transport. Weight is likely to be dictated by the wheel loadings of lorries. The handling arrangements at the main terminals and ports are specially designed to handle the containers quickly and accurately. The larger container ships use dedicated
container ports and tend not to have their own cargo handling gantries.  The containers themselves are simply reusable boxes made of steel or aluminium. They come in a range of types and sizes. Details can be obtained from the web site of one of the operators. Nominal dimensions are lengths  of  20,  40  and  45   ft,  width  of  8  ft  and  height 8.5 or 9.5  ft. Internal volumes and weight of goods that can be carried vary with the material. For a 20  ft general-purpose steel container the internal capacity is about  33 m3  , weight empty is about 2.3 tonnef and the maximum payload is about 21.7 ton. Aluminium containers will have about the same volume, weigh less and be able to carry a larger payload. They are used for most general cargoes and liquid carrying.     The cargo-carrying section of the ship is divided into several holds with the containers racked in special frameworks and stacked one upon the other within the hold space. Containers may also be stacked on hatch covers and secured by special lashings. Some modern ships dispense with the hatch covers, pumps
dealing with any water that enters the holds. Each container must be of known all up weight and stowage arrangements must ensure the ship’s stability is adequate as well as meeting the offl  oading schedule if more than one port is involved. The ship’s deadweight will determine the total number of containers carried.   Cargo holds are separated by a deep web-framed structure to provide the ship with transverse strength. The structure outboard of the container holds is a box-like arrangement of wing tanks providing longitudinal and torsional strength. The wing tanks may be used for water ballast and can be used to counter the heeling of the ship when discharging containers. A double bottom is fi  tted which adds to the longitudinal strength and provides additional ballast space. Accommodation and machinery spaces are usually located aft leaving the maximum length of full-bodied ship for container stowage. The overall capacity of a container ship is expressed in terms of the number of standard 20 ft units it can carry, that is, the number of   twenty-foot equivalent units  (TEU). Thus a 40-foot container is classed as 2 TEU.   The container ship is one application where the size of ship seems to be ever increasing to take advantage of the economies of scale. By the turn of the century 6000 TEU ships had become the standard for the main trade routes, and some 80 ships of 8000 TEU were on order plus some of 9200 TEU. Concept work was underway for ships of 14 000 TEU size. Container ships tend to be faster than most general cargo ships, with speeds up to 30 knots. The larger ships
can use only the largest ports. Since these are fi  tted out to unload and load containers the ship itself does not
need such handling gear. Smaller ships are used on routes for which the large ships would be uneconomic, and to distribute containers from the large ports to smaller ports. That is, they can be used as feeder ships. Since the smaller ports may not have suitable handling gear the ships can load and offl  oad their own cargos.     Some containers are refrigerated. They may have their own independent cooling plant or be supplied with cooled air from the ship’s refrigeration system. Because of the insulation required refrigerated containers have less usable volume. Temperatures would be maintained at about    27°C and for a freezer unit about    60°C. They may be carried on general cargo ships or on dedicated refrigerated container ships. One such dedicated vessel is a 21 knot, 30 560 dwt ship of 2046 TEU capacity. The ship has six holds of which five are open. The hatchcover-less design enables the cell structure, in which the containers are stowed, to be continued above deck level giving greater security to the upper containers. Another advantage of the open hold is the easier dissipation of heat from the concentration of reefer boxes.

   Barge carriers are a variant of the container ship.


Standard barges are carried into which the cargo has been previously loaded. The barges, once unloaded, are towed away by tugs and return cargo barges are loaded. Minimal or even no port facilities are required and the system is particularly suited to countries with extensive inland waterways.




 Ref : Eyres, D.J. (2007) Ship Construction. Butterworth-Heinemann, Oxford, UK. [Section 2.2.4]
Rawson K.J. and Tupper E.C. (2001) Basic Ship Theory. 5th Edition, Combined Volume. 
Butterworth-Heinemann, Oxford, UK. [Sections 2.2.9, 2.4]
Tupper, E.C. (2004) Introduction to Naval Architecture. Butterworth-Heinemann, Oxford, UK.
[Sections 2.2.1–2.2.3, 2.2.5–2.2.8, 2.3, 2.5]
Maritime engineering reference book
lovelymimiko@blogspot.com

Post By Ruth

Jenis baja dapat dibedakan menjadi :

  1. Baja karbon
  2. Baja paduan rendah berkekuatan tinggi
  3. Baja paduan
Baja Karbon
Merupakan baja yang mengandung unsur bukan besi dengan persentase sebagai berikut:

  • karbon 1.7%
  • mangan 1.65%
  • silikon 0.6%
  • tembaga 0.6%
Karbon dan mangan adalah unsur utama yang dapat menaikkan kekuatan besi murni.Penambahan persentase karbon mengakibatkan peningkatan tegangan leleh tetapi mengurangi ductility sehingga baja sukar dilas.
Yang temasuk baja karbon disini adalah :

  • baja karbon rendah : kandungan karbon kurang dari 0.15%
  • baja karbon lunak : 0.15 - 0.29%
  • baja kkarbon sedang : 0.30 - 0.59%
  • baja karbon tinggi : 0.6-1.7%
Kurva Tegangan Regangan



Baja Paduan Rendah Kekuatan Tinggi
Adalah baja yang tegangan lelehnya antara 40-70 ksi (275-480 Mpa) dengan titik leleh sama seperti baja karbon. Baja ini merupakan perpaduan dari unsur chrom, columbium, tembaga, mangan, molybdenum,nikel, fosfor,vanadium atau zirconium.Dengan memperhalus mikrostruktur yang terjadi selama pendinginan baja. Baja jenis ini dipakai pada kondisi penggilingan/penormalan (tanpa perlakuan panas).

Baja Paduan
Baja jenis ini tidak membutuhkan perlakuan panas setelah dilas, merupakan baja yang mengandung karbon maksimal sebesar 0.2% , dengan maksud untuk membatasi kekerasan mikrostruktur kasar (martensit) yang dapat terbentuk selam retak kea perlakuan panas/pengelasan sehingga bahaya retak kecil.

Ductility adalah jumlah regangan permanen (regangan yang melampaui batas proporsional sampai titik patah /yield point). Besarnya ductility/daktilitas diperoleh dari uji tarik dengan menentukan persentase perpanjangan -dengan membandingkan luas penampang lintang akhir dan semula-dari benda uji.
Ductility sangat penting karena memungkinkan terjadinya kelelahan setempat akibat tegangan yang besar, sehingga distribusi tegangan berubah.