9/30/2013

20 Important Factors For Oily Water Separator Operation On Ships

Optimal performance of the Oily Water Separator is dependent on the knowledge of certain factors such as design, operation, bilge management and maintenance etc. For more information, read what factors affect oily water separator on ships?
In this article we shall discuss the various operational factors influencing performance of the Oily Water Separator.
Operational Factors
Correct operational knowledge is required for all machinery on ships to run properly and the Oily Water Separator is no exception. Marine engineers work with different types of Oily Water Separators through their sea career and each type has its own unique features.
Oily Water Separator
Equipment specific knowledge is essential for the correct operation of oily water separator and can be learnt from the operational manual on board. However a generic knowledge is also required as the basic working principle is essentially the same.
An idea borrowed from existing shore technology, the Oily Water Separators for ships are designed to work properly under ideal conditions. However ships do not have ideal conditions, and therefore ship’s staff should consider the following operational factors which affect the performance of  Oily Water Separator on ships.
1. Avoid Emulsions: Emulsions are formed when the inter-facial tension between two liquids is reduced by certain means sufficiently to allow droplets of one liquid to disperse in another. Mechanical agitation, shearing forces, solvents, chemicals, surfactants and the presence of particulate matter can all reduce inter-facial tension and result in formation of emulsion.
2. Avoid Chemical emulsions:  The chemical emulsion is formed by the addition of some chemicals in the water. These chemicals act as surfactants and they hold the oil drops together in emulsified state.  The surfactants may be the detergents used for cleaning, alkaline chemicals used for boiler cleaning and conditioning etc.
3. Avoid secondary dispersion:  Mechanical emulsions are of primary and secondary types. The primary emulsions are larger drops of oil dispersed in water and are generally separated within 24 hours. The secondary emulsions are fine droplets of oil that are thermodynamically stable and do not separate. The secondary dispersion is caused by turbulent conditions.
4. Avoid suspended solids: Suspended solids cause stabilization of emulsion and cause problems in separation of the oil from the bilge water. Suspended solids can be mud, boiler soot and cargo residues sucked from the blowers. The suspended solids get coated with oil and stabilize the emulsion. Neutrally buoyant solids that neither rise nor fall are most troublesome as it is difficult to remove them. They also generate the high ppm alarm.
5. Avoid Turbulence: OWS needs laminar flow to operate optimally as per their design. Avoid using OWS in times of heavy rolling and keep all line valves fully open to avoid generating turbulence. Rolling motion, retrofitting on old pipelines and inadequate opening of the suction line valves can lead to turbulent flow inside the OWS with resulting fall in OWS capacity due to formation of emulsion. Sometimes due to turbulence some of the oil droplets become less than 8 microns and are affected by the random motion of the water particles. This random motion is called as Brownanian motion and it nullifies the forces of buoyancy and the oil drops fail to rise.
6. Avoid Particulate Matter: Fine particulate matter like soot, rust, microbial contamination of bilge water etc. also act as emulsifying agent. Although most of the soot of the boiler washing settles down in the bilge holding tank, fine soot particles (1μm or less) will give the bilge water a blackish appearance. These particulate matter will not only fool the ppm meter into activating the high ppm alarm but will also physically act as emulsifying agent
7. Optimal use of Chemicals: Sometimes it is required to use special chemicals called emulsion breakers to separate the oil from the water and release free oil. If emulsion breaker chemical is used, care should be taken that it is used as per the instructions given by the manufacturer emulsion does’t go worse. Sometimes putting more than the recommended amount can worsen the problem.
8. Restrict Drainage of Chemicals: Lot many chemicals are used in engine room for special purposes such as water conditioning, corrosion inhibition, rust removal, cleaning, degreasing etc. However care should be taken to collect these chemicals and disposing them properly. Allowing all kind of chemicals to run free into the bilges is not good housekeeping. More over the pH of water above 10 and below 4 can cause chemical emulsification.
9. Detergent Disposal: Detergents are used for mopping and soap washing of bulkheads and such areas. Generally these are the same detergents we use at home or ashore. These detergents act as surfactants and cause emulsion of oil in water. Disposing mop water separately or using quick break detergents would help significantly towards better separation.
10. Avoid prolonged storage: Prolonged storage of the bilge water causes modification in the nature of free oil. Normally oil water mixture when allowed to stand for some time (say 24 hours) separates into a layer of oil on top of water called as free oil. This free oil is easy to remove but long retention of the bilge water can cause modification in the properties of free oil due to oxidation and microbial action. If this modification occurs then it is difficult to remove the oil.
11. Do Proper Filtration: If there is large amount of solid particles, floating media, jute etc. in the bilge water, it should be properly removed using strainers to avoid fouling of the filter media.
12. Collect leakages: Ensure that minimum of oil reaches the bilge wells and if the oil quantity is more in a mixture (of oil and water) put it in separated oil tank.  Always remember that the Oily Water Separator is not a purifier.
13. Heat the influent:  Heating the influent reduces the viscosity of the continuous media causing better separation.
14. Segregation of Wastes:  Do not mix sludge and bilges. Even a bit of sludge can contaminate large amount of bilge water. In some ports even discharge of treated sewage is not permitted due to local regulation and therefore in absence of dedicated sewage holding tank, treated sewage is put in bilge holding tank. This should be avoided as it would be impossible to run the Oily Water Separator thereafter without cleaning the tank.
15. Fill up OWS prior use: Prior to operating the OWS and allowing the bilge water to enter always ensure that it is filled up with clean water and all air pockets have been removed. This is important as air pockets can confuse the capacitive sensors and can make automation go haywire.
16. Back Flush: Back flushing of the OWS should be done as per the recommended frequency given by the manufacturer if there is a provision for doing so as increases the life of the filter media.
17. Clean Sensors: Frequent cleaning of the electronic interface sensors would ensure the correct operation, proper oil removal and sharp cutting off ensuring less discharge of water to separated oil tank.
18. Remove Accumulated Oil: Apart from the automated oil removal any other accumulated oil should be removed from the OWS chambers regularly.
OWS Chamber and Filter
19. Proper Operating Procedure: Make sure that the operating procedure of OWS is followed in a proper step-by-step and systematic procedure.
20. Proper OWS Maintenance:  Needless to say proper maintenance of the OWS as per the instructions of the manufacturer would keep it ship shape.

9/29/2013

The Basics of Troubleshooting Engine Room Machinery

For marine engineers working on ships, troubleshooting problems related to engine room machinery is the most important task they have to deal with on a daily basis.
We often get questions like – what is the best way to troubleshoot a machinery problem? And to be honest there is no one answer to such question. Technically, there are several aspects that play important roles toward solving a engine room machinery problem.
Though marine engineering training inculcates the very basics of maritime concepts, it is only through hands-on experience that marine engineers understand the vital techniques of engine room operation and maintenance. However, even both of these two factors together are not enough.
ship engine room
The process of troubleshooting ship’s machinery involves three important factors which are as follows:
- Requirement
- Approach
- Learning
Requirement
Though the art of troubleshooting cannot be learnt just from marine engineering books, bookish knowledge is equally important. As important as it is to learn solving machinery related issues of ships through experience and practical approach, it is equally essential for a seafarer to have a technical background along with following basic requirements:
- A marine engineering course to understand the basic marine machinery skills- A Diploma or Degree
- Practical training with real machinery- Ground or hands-on training in workshops, projects, onboard ships etc.
- Simulation training to enhance the problem solving capabilities
- Experience – As stated earlier, practical experience is the best teacher and one should never forget its importance
ship main engine
Approach
Though it is mandatory for a person to have all the “requirements” stated above in order to work on ships, those are also not enough. Fulfilling the requirements is just the first step towards successful troubleshooting. The right approach to learn and understand the machinery is one of the three important factors seafarers must consider for troubleshooting. A healthy approach involves:
- Knowing your machinery inside-out
- Learning starting and stopping procedures of engine room machinery thoroughly
- Reading the maker’s manual for a friendly interface and easy understanding, especially the troubleshooting points
- Understanding what makes machinery perform and what are the power sources that are used to operate? Take a look at important factors such as electricity, oil, water, air, temperature etc.
- Checking and knowing the basic parameters and comparing with previous records
- Checking for the most basic faults- malfunctioning of gauges and parameter display panels even when the components are working fine
- Identifying which parameter is abnormal
- Identifying which component or part of the machinery is in fault
- If identification of troubled component is not possible, start a reverse technique of ruling out the performing component and approaching the faulty one
- Once the component or reason is located, think logically as to where the fault lies – in the region in front or in some other area
- Identify wether other parts connected to the faulty component can be at trouble
- Rectify the problem once identified immediately
- Test the machinery for satisfactory performance
- If problem persists, check the same again and also track other connected parts
engine room machinery

Know more about the right troubleshooting approach here. 
Learning
Seafarers often forget that troubleshooting is a continuous learning process. There is no stage such as “know-it-all”. There is something new to learn everyday even if one has years of sailing experience. So if sometimes someone is not able to solve a problem at hand, don’t be disappointed. Learn from the issue.
Learning from the last problem tackled always adds on to the experience which can be used for future troubleshooting situations. Once the problem is solved, it is better to discuss the same with your team to find other simpler way of tackling the same issue.
Recording the problem faced, the way it is approached and the method used for solving will not only be helpful in future but also serve as a useful resource for other engineers to solve similar situations quickly and easily.

While working in ship’s engine room, it’s of utmost importance to troubleshoot any problem in a fast and streamlined manner to ensure that the ship’s voyage schedule does not suffer. The above three factors together form the basics of troubleshooting engine room machinery problems.

9/28/2013

Types of Exhaust Gas Boiler (EGB) Fires and Ways to Prevent Them

An Exhaust Gas Boiler is a type of heat recovering system on ships which allows the exhaust heat of the main engine to produce steam while going out in the atmosphere.
Every system, which is operated at high temperature, always has a risk of fire. This applies to EGB which has the inlet temperature of exhaust gases @ 300-400 deg. C. The most common type of Exhaust Gas Boiler (EGB) used on ships are water tube boilers.
In water tube type of arrangement, the water passes through tube stack, which is arranged in the path of exhaust gas inside the exhaust gas trunking of the main engine. The exhaust gas flows over the tube stacks and heats the water, thus producing steam.
Exhaust gas boiler
The main constituent of the soot deposit is particulates but in addition, some unburnt residues of fuel and lubricating oils may be deposited in the boiler.
Soot deposit and fire in the EGB can be-
  1. Due to the poor combustion of fuel in the main engine
  2. Due to prolong slow steaming
  3. Long maneuvering of the ship
  4. Frequent starting and stopping of the engine
  5. Poor grade of fuel oil/ cylinder oil
  6. Low exhaust gas velocity passing the EGB
  7. Low water inlet velocity in the water tubes
  8. Low circulation water flow ratio
Types of Exhaust Gas / Soot fire in the Exhaust Gas Boiler (EGB)
For a better understanding, it is better to distinguish the EGB fire in stages rather than in types. EGB fires can be differentiated in two or three stages depending upon the intensity of fire.
Stage 1: Normal Soot fire
Stage 2: Hydrogen Fire
Stage 3: Iron Fire
Stage 1: Normal Soot Fire:
Soot is deposited in the water tube of the exhaust boiler. When the ship is at slow speed, the exhaust temperature of main engine may vary from 100 to 200 deg C. This temperature is enough to ignite “wet soot” whose ignition temperature is around 150 deg. C.
If the soot is “dry”, it will not get ignited at such low temperature (150 deg. C) but when the engine is running at higher speed and the temperature of gases reaches to above 300 deg. C, then in the presence of excess oxygen the deposits of combustible materials will liberate sufficient vapor, which can be ignited by a spark or a flame.
The above soot fires are called small or normal soot fire because the heat energy is conducted away by the circulating boiler water and steam. Also the sparks remain inside the funnel or diminish while passing through the flame arrestor in the funnel top.
Stage 2: Hydrogen Fire
Hydrogen fire in a EGB occurs when the chemical reaction of dissociation of water takes place at a temperature above 1000 deg. C. This leads to formation of Hydrogen (H2) and Carbon mono-oxide (CO) which are both combustible in nature.
2H2O= 2H2 + O2 (Dissociation of water Leading to formation of hydrogen-H2)
H 2 O + C =H 2 + C O (Reaction of water with carbon deposit leading to formation of carbon monoxide-CO)
Melted tube
Stage 3: Iron Fire
At this stage, the chain reaction of oxidation of iron metal starts at a high temperature of 1100 deg. C which means at such high temperature the tube will start burning itself, leading to complete meltdown of tube stacks.
2Fe + O2 2=FeO+ heat
It is strictly advisable not to use water or steam at this stage to fight the fire because the overheated iron will react with water to continue this reaction.
Fe + H2O =FeO+ H2 + heat
Steps for Prevention of Fire
  • Avoid slow steaming of main engine
  • Ensure good fuel combustion in the main engine
  • Ensure fuel is treated and is of good quality while supplying to the engine
  • Do regular soot blow of boiler tubes
  • Do water washing in ports at regular interval
  • Ensure design of exhaust trunk to be such to provide uniform heat to complete tube stack
  • Pre-heated circulating water to be supplied to boiler mainly at the time of start up
  • Circulating pump should not be turn off at any time while main engine is running
  • Do not stop circulating pump for at least two hours after the main engine is stopped
  • Start circulating pump prior to 2 hours before starting the main engine
How to Tackle EGB Fire?
The response for tacking EGB fire will be different for different stages.
When there is stage 1 fire, i.e. normal soot fire:
a) Stop the main engine, and thereby the oxygen supply to the fire
b) Continue operating the water-circulating pump. Never stop the pump
c) Never use soot blowers for fire fighting whatever type it is – Steam or Air as both will accelerate the effect of fire
d) Ensure all the exhaust valves in the stopped Main engine are in closed position so as to cut any chance of air supply to the soot fire
e) Cover the filter of turbocharger
f) Water washing, if fitted, may be used to extinguish the fire. This is normally connected to the ship’s fire fighting water system
g) External boundary cooling can be done
For Major Fire:
a) Stop the main engine, if it is not stopped already
b) Stop the circulating water pump.
c) Shut all the inlet and outlet valves on the water circulation line
d) Discharge the (remaining) water from the exhaust gas boiler sections by draining
e) Cool down with plenty of splash water directly on the heart of the fire (Take care not to splash water in other parts as water can accelerate the reaction)

9/27/2013

10 Steps for Converting a Conventional Marine Propulsion Engine to an Intelligent Electronic Controlled Engine

With the evolution of GREEN shipping in the maritime industry, the machinery and equipment which drive the industry are seeing a myriad of changes for cutting down pollution and operating costs.
The main engine of the ship is probably seeing most number of changes. The conventional 2 stroke marine propulsion engine, a mechanical achievement of skilled engineering, is now been converted into new electronically controlled smart engine, providing instant adaptability of the engine process which benefits both marine environment and ship operators.bal recession and be in sync with the strict maritime pollution norms.
In this article we will take a look as to how a conventional marine propulsion engine is converted into an intelligent electronic controlled engine.
For the conversion, let’s take the most popular marine propulsion engines in the shipping industry, MAN diesel engines and Wartsila/ Sulzer engines.
10 steps for converting MAN MC Series mechanically controlled engine into MAN ME electronically controlled engine:
1.  Remove Camshaft and reversing attachments (fuel roller and starting air cams) from the engine.
2.  Remove Chain Drive of the engine.
3.  Remove Fuel pumps, Exhaust valve actuating gear (Pumps) and starting air distributor.
4.  Attach Cylinder control system in each unit (CCU) comprising of starting air control, electronic fuel injection control, and exhaust valve electronic actuation. The latter two systems are operated by Hydraulic Control Unit (HCU).
5.  Provide system oil at 200 bars for operating HCU of each cylinder unit via cylinder control system.
6.  Attach a common hydraulic oil supply unit.
7.  Attach a tacho system unit in the crankshaft which gives engine speed signal to CCU.
8.  All these added systems are controlled by electronic main operating panel via solenoid valves and electronic signals.
9.  Remove conventional cylinder lubrication system and replace it with Alpha Adaptive Cylinder Lubrication Control Unit (ACC).
10. Remove conventional Piston and replace it with OROS type modern piston.
Watch the Video:


10 steps for converting a conventional Wartsila/Sulzer RTA engine into RTFlex electronically controlled engine:
1.  Remove Camshaft along with reversing servomotor connections from the engine.
2.  Remove Gear drive from the engine.
3.  Remove Fuel pumps, Exhaust valve actuating gear (Pumps) and starting air distributor.
4.  Attach an exhaust valve actuation, starting air control and common rail platform with Volumetric Injection Control Unit.
5.  Provide system oil at 200 bars.
6.  Provide fuel oil to common rail at 1000 bar.
7.  Remove conventional Cylinder Lubrication system and replace it with Pulse type Lubrication Control Unit.
8.  Remove conventional piston and replace it with Jet shaker type modern piston with Sulzer Integrated Piston Wear Analysis (SIPWA) system.
9.  A Delta tuning control system instead of conventional fuel injection system for cutting of fuel supply to one or more unit at low load.
10. Install a Tribo Pack which is a combination of design features of combustion chamber components for increasing Time Between Overhaul (TBO).
Watch the Video:

These are the basic changes required to convert a conventional mechanical controlled engine in to an electronically controlled engine.
Do you know more ways to convert a Conventional Marine Propulsion Engine to an Intelligent Electronic Controlled Engine? Let us know.

9/26/2013

What is a Metering Pump On board a Ship?

Metering pump, as the name suggests, is a type of pump which is used on ship to pump a precise volume of liquid. Metering pump can be adjusted to provide different flow rates. They are generally used when the precision of volume to be delivered is very important.
The marine application of metering pump is in the form of chemical dosing pumps, which is used to transfer precise amount of dosing chemicals, especially in boilers. They are also used for dosing chemical additives to protect corrosion in the cooling water system. It is to note that the amount of dosing has to be precise. Over dosing or under dosing may cause corrosion and other damages inside the boiler, which may end up in heavy repairs.
The metering pump is connected to the system in which the chemicals are injected with the help of valve in the pipeline. The pressure produced by this pump should be higher than the pressure in the pipeline, or else there will not be any dosing and the level of chemicals in the dosing tank will be the same.
The metering pumps consist of a small motor which moves the plunger, in and out of the barrel, to provide pressure in the system. The check valves are provided in the suction and discharge side of the pump. Since the pump is of the plunger type, metering pump is a positive displacement pump.
Points to Note
For a positive displacement pump, the relief valve has to be provided in the discharge line. The reason for this is that the liquid is incompressible and there is no space in the barrel to accommodate the pressed liquid. A high pressure is created if the discharge valve is closed or if there is any other restriction/blockage in the system. The high pressure might completely damage the pipes connected. For this reason a relief valve is connected in the discharge line and is set at a particular pressure. When the pressure rises, the relief valve opens and relieves the extra pressure, thus protecting the pipes.
Generally metering pumps are connected to the dosing pumps and the whole unit is known as the dosing unit. The relief valve is connected to the dosing pump, which releases the excess pressure back to the dosing tank.
Working of Metering Pump
As the plunger moves away from the suction valve, a vacuum is created inside the pump because of which makes liquid flow inside the pump. This closes the check valve closes and the plunger again starts moving towards the valves. The discharge valve then opens and supplies the liquid to the system.
The seal arrangement is provided at the end of the plunger i.e. towards the motor side so that no leak should take place.
The volume of the liquid supplied can be altered by altering the movement of the plunger inside the barrel. This is generally done by a small knob provided on the pump and which thus allows adjusting the percentage of liquid supplied.
When the knob is turned to increase or decrease the flow rate, it alters the movement of the plunger, which means that it moves less in the plunger rather than along the full length of the plunger. Because of this the liquid enters the chamber and changes the plunger position along with the flow rate.
Image Credit

As a worldwide marine service agent, Ijin Marine Limited provides ship voyage repair, lifesaving inspection, fire-fighting inspection, radio inspection, and underwater hull cleaning, in more than 3000 ports of 100 countries. Below is a list of world's seaports, arranged by oceans and seas. Ijin has attended many jobs in some of them as below. The lifesaving equipment includes life boat, life raft, which is annually inspected accordingly to class requirement. Fire fighting equipment includes fire extinguisher (dry powder, CO2, foam, etc, hand type or wheeled type), firemen outfitting and cylinder, air breathing apparatus, EEBD, etc. Communication inspection includes GMDSS, AIS, SSAS, EPIRB, SVDR, VHF radio, etc. Underwater service includes inspection, hull cleaning, repairing, plugging, etc.
The list of jobs Ijin attending in the past.
M/V Changhang Xianghai, TurbaraoBrazil, Ship Store Supply
M/V Changhang Bohai, KandleIndia, Motor Rewinding
M/V Changhang An Hai, AmsterdamNetherlands Or Holland, Store Supply
M/V CF Diamond, VancouverCanada, Oil Tank Repair For Life Boat
M/V CF Crystol, VancouverCanada, Hatch Cover Repair
M/V LR Lily, KalimantanIndonesia, Bearing Replacement For Crane
M/V Sky Jupiter, Johor BahruMalaysia, Provision And Ship Store Supply
M/V Sky Oceanus, Johor BahruMalaysia, Provision And Ship Store Supply
M/V Msc Sentosa, Johor BahruMalaysia, Provision And Ship Store Supply
M/V Man Hai, JarkataIndonesia, Life Raft Supply
M/V Jian Hua, Point ComfertAmerica, Ship Store Supply
M/V Long Hua, Dong HaeKorea, Spare Part Delivery
M/V Xin Xiang An, KaraikalIndia, Ship Store Supply
M/V Xin Bo Lin 3, MumbaiIndia, Ship Store Supply
M/V Hui Tong 56, BelawanIndonesia, Boiler Repair
M/V Zhe Hai 505, AuklandNew Zealand, Fire Fighting Equipment Inspection
M/V Zhe Hai 505, VitoriaBrazil, Life Raft Inspection
M/V Zhe Hai 505, RotterdamNetherlands, Ship Store Supply
M/V Zhe Hai 505, San LorenzoArgentina, Ship Store Supply
M/V Da Xin Hua Li Shun, UlsanKorea, Fire Fighting, Life Saving And Gmdss Inspection
M/V Ratna Shalini, GdanskPoland, Gas Detector Calibration
M/V Cleantec, Casablanca, Morroco, Ship Store Supply
M/V Chang Hang An Hai, TaichuangTaiwan, Auxiliary Engine Repair
M/V Chang Hang An Hai, Richard BayAustralia, Ship Store Supply
M/V Rich Sino, Junk Bay Anchorage Of Hong Kong, Underwater Hulls Inspection, Pre Purchase.
Atlantic Ocean
List of ports and harbours of the Atlantic Ocean
AbidjanIvory Coast
AccraGhana
A Coruña, Spain
Port of Albany-RensselaerNew YorkUnited States
Bahía BlancaArgentina
Coronel Rosales PartidoArgentina
General Belgrano, Buenos AiresArgentina
BananaDemocratic Republic of the Congo
BarranquillaColombia
BelémBrazil
BergenNorway
BodøNorway
Port of BostonMassachusettsUnited States
BotwoodNewfoundland and LabradorCanada
BridgetownBarbados
BrunswickGeorgiaUnited States
Buenos AiresArgentina
CalabarNigeria
CabindaAngola
CádizSpain
Port CanaveralFloridaUnited States
Cape MayNew JerseyUnited States
Cape TownSouth Africa
Port of CasablancaMorocco
CayenneFrench GuianaFrance
CharlestonSouth CarolinaUnited States
ColónPanama
CorkIreland
DakarSenegal
DoualaCameroon
ElizabethNew JerseyUnited States
FerrolSpain
FreeportBahamas
FreetownSierra Leone
FortalezaBrazil
GalwayIreland
GeorgetownGuyana
Port of HafnarfjörðurIceland
Port of HalifaxNova ScotiaCanada
HamiltonBermuda
Hampton Roads, Virginia, United States
HarstadNorway
HuelvaSpain
JacksonvilleFloridaUnited States
LagosNigeria
Las Palmas de Gran Canaria, Canary Islands, Spain
LibrevilleGabon
LisbonPortugal
LoméTogo
LuandaAngola
MalaboEquatorial Guinea
MelfordNova ScotiaCanada (proposed)
Port of MiamiFloridaUnited States
MonroviaLiberia
MontevideoUruguay
NantesFrance
NarvikNorway
NassauBahamas
Port NewarkUnited States
Port of New York and New JerseyUnited States
ParamariboSuriname
PecémBrazil
Port of PhiladelphiaPennsylvaniaUnited States
Port Everglades, FloridaUnited States
Port HarcourtNigeria
PortlandMaineUnited States
PortoPortugal
Porto AlegreBrazil
QuequénArgentina
RecifeBrazil
ReykjavíkIceland
Rio de JaneiroBrazil
SalvadorBrazil
San JuanPuerto RicoUnited States
Santa Cruz de Tenerife, Canary Islands, Spain
Port of Santos near São PauloBrazil
Port of SavannahGeorgiaUnited States
St. AugustineFloridaUnited States
Saint JohnNew BrunswickCanada
Sept-Îles, QuebecCanada
SetúbalPortugal
Sines, Portugal
StornowayScotlandUnited Kingdom
Shannon/Foynes, Ireland
St. John'sNewfoundland and LabradorCanada
Tangier, Morocco
TromsøNorway
TrondheimNorway
Port of VigoSpain
VitóriaBrazil
Walvis BayNamibia
WilmingtonDelawareUnited States
WilmingtonNorth CarolinaUnited States
ÅlesundNorway
ParanaguáBrazil
São Francisco do SulBrazil
ItajaíBrazil
Porto VelhoBrazil
SantosBrazil
ItapoáBrazil
Adriatic Sea
Ancona, Italy
Port of BarMontenegro
BariItaly
BudvaMontenegro
Port of DurrësAlbania
Port of KoperSlovenia
Port of PescaraItaly
Port of PločeCroatia
Port of RijekaCroatia
Shën GjinAlbania
Port of SplitCroatia
Port of TriesteItaly
VeniceItaly
Port of VlorëAlbania
RavennaItaly
MonfalconeItaly
ChioggiaItaly
Porto MargheraItaly
Aegean Sea
AlexandroupolisGreece
BodrumTurkey
ChalcisGreece
ChiosGreece
EleusinaGreece
Heraklion, CreteGreece
İzmir, Turkey
KavalaGreece
KuşadasıTurkey
LauriumGreece
MytileneGreece
PiraeusGreece
RhodesGreece
ThessalonikiGreece
VolosGreece
Azov Sea
AzovRussia
BerdianskUkraine
MariupolUkraine
TaganrogRussia
YeyskRussia
Baltic Sea
List of Ports of the Baltic Sea.
Bay of Biscay
AvilésSpain
BayonneFrance
BurelaSpain
Port of BilbaoSpain
BordeauxFrance
BrestFrance
El Musel, GijónSpain
PasaiaSpain
La RochelleFrance
Les Sables-d'OlonneFrance
SantanderSpain
Black Sea
BatumiGeorgia
BilhorodUkraine
BurgasBulgaria
IllichivskUkraine
MangaliaRomania
Midia, NăvodariRomania
NovorossiyskRussia
OdessaUkraine
PotiGeorgia
Port of ConstanţaRomania
Giurgiulesti International Free PortMoldova
Port of ErdemirTurkey
Port of VarnaBulgaria
SamsunTurkey
SevastopolUkraine
SukhumiGeorgia
TrabzonTurkey
YuzhnyUkraine
Caribbean Sea
Basse-TerreGuadeloupeFrance
Belize CityBelize
BridgetownBarbados
Port of Cabo RojoDominican Republic
CartagenaColombia
ChetumalMexico
ColónPanama
Fort-de-FranceMartiniqueFrance
La GuairaVenezuela
GuantaVenezuela
GuantánamoCuba
KingstonJamaica
LimónCosta Rica
MaracaiboVenezuela
Oranjestad, ArubaNetherlands
Pointe-à-Pitre, GuadeloupeFrance
PoncePuerto RicoUnited States
Port-au-PrinceHaiti
Port CaucedoDominican Republic
Port Rio HainaDominican Republic
Port of SpainTrinidad and Tobago
Puerto Barrios, Guatemala
Puerto CabelloVenezuela
Puerto PlataDominican Republic
Puerto CastillaHonduras
Puerto CortésHonduras
RoatánHonduras
Santiago de CubaCuba
Port of Santo DomingoDominican Republic
Santo Tomás de CastillaGuatemala
WillemstadCuraçaoNetherlands
Chesapeake Bay
BaltimoreUnited States
NorfolkVirginiaUnited States
SalisburyMarylandUnited States
English Channel
Caen (Ouistreham), France
CalaisFrance
CherbourgFrance
DieppeFrance
Port of DoverUnited Kingdom
Le HavreFrance
Port of LondonUnited Kingdom
Dunkerque(Duinkerken), France
NewhavenUnited Kingdom
OstendBelgium
St. Peter PortGuernseyUnited Kingdom
Portland HarbourUnited Kingdom
PortsmouthUnited Kingdom
PlymouthUnited Kingdom
RamsgateUnited Kingdom
Saint-MaloFrance
Shoreham-by-SeaUnited Kingdom
Port of SouthamptonUnited Kingdom
Great Lakes
Port of MontrealCanada
BuffaloNew YorkUnited States
Burns Harbor / PortageIndianaUnited States
Port of ChicagoIllinoisUnited States
ClevelandOhioUnited States
DetroitMichiganUnited States
DuluthMinnesotaUnited States
EriePennsylvaniaUnited States
HamiltonOntarioCanada
KingstonOntarioCanada
MilwaukeeWisconsinUnited States
Port of MontrealCanada
NanticokeOntarioCanada
OshawaOntarioCanada
Port of Oswego AuthorityNew YorkUnited States
Thunder BayOntarioCanada
Two Harbors, MinnesotaUnited States
ToledoOhioUnited States
TorontoOntarioCanada
Sault Ste. MarieOntarioCanada
Sault Ste. Marie, Michigan, United States
Irish Sea
Barrow-in-FurnessEngland
BelfastNorthern Ireland
CairnryanScotland
CardiffWales
Douglas, Isle of Man
DroghedaIreland
DublinIreland
Dún LaoghaireIreland
DundalkIreland
EllesmereEngland
Fishguard, Wales
FleetwoodEngland
GarstonEngland
GlasgowScotland
HeyshamEngland
Holyhead, Wales
LarneNorthern Ireland
LiverpoolEngland
Milford Haven, Wales
Mostyn, Wales
Pembroke Dock, Wales
Rosslare EuroportIreland
RuncornEngland
StranraerScotland
SwanseaWales
Sea of Marmara
IstanbulTurkey
İzmit, Turkey
TekirdağTurkey
Mediterranean Sea
AdanaTurkey
AlexandriaEgypt
AlgecirasSpain
Al Hoceima, Morocco
AlgiersAlgeria
AlmeríaSpain
AntalyaTurkey
Port of AshdodIsrael
BarcelonaSpain
BardiaLibya
BeirutLebanon
BenghaziLibya
CagliariSardiniaItaly
CartagenaSpain
CeutaSpain
ChalcisGreece
CivitavecchiaItaly
CorinthGreece
DatcaTurkey
FethiyeTurkey
GenoaItaly
Gibraltar (British Overseas Territory)
Gioia TauroItaly
Grand HarbourMalta
IskenderunTurkey
Port of HaifaIsrael
LarnacaCyprus
LatakiaSyria
LeghornItaly
LimassolCyprus
MálagaSpain
MarmarisTurkey
MarseilleFrance
MelillaSpain
Mersa MatruhEgypt
MersinTurkey
MessinaSicilyItaly
MisrataLibya
NadorMorocco
NaplesItaly
OranAlgeria
Palma de MallorcaSpain
PalermoSicilyItaly
PatrasGreece
PiraeusGreece
Port SaidEgypt
SidonLebanon
Tangier, Morocco
TarragonaSpain
Tel AvivIsrael
ThessalonikiGreece
TétouanMorocco
TripoliLebanon
TripoliLibya
TunisTunisia
ValenciaSpain
Gulf of Mexico
Port of BeaumontTexasUnited States
CampecheMexico
Ciudad del CarmenMexico
CoatzacoalcosVeracruzMexico
Port Corpus ChristiTexasUnited States
GalvestonTexasUnited States
GulfportMississippiUnited States
HavanaCuba
Port of HoustonTexasUnited States
Intracoastal CityLouisianaUnited States
Lake CharlesLouisianaUnited States
Louisiana Offshore Oil PortLouisianaUnited States
MatamorosTamaulipasMexico
MatanzasMatanzasCuba
Port of MobileAlabamaUnited States
Port of New OrleansLouisianaUnited States
Panama CityFloridaUnited States
PensacolaFloridaUnited States
Plaquemines PortLouisianaUnited States
Port FourchonLouisianaUnited States
ProgresoMexico
Port of TampaUnited States
TampicoTamaulipasMexico
VeracruzVeracruzMexico
North Sea
List of North Sea ports
AberdeenScotlandUnited Kingdom
Port of AmsterdamNetherlands
Port of AntwerpBelgium
BlythEnglandUnited Kingdom
BremerhavenGermany
BremenGermany
Port of Bruges-ZeebruggeBelgium
CuxhavenGermany
DelfzijlNetherlands
DundeeScotlandUnited Kingdom
EemshavenNetherlands
EmdenGermany
EsbjergDenmark
Port of FelixstoweUnited Kingdom
FlottaScotlandUnited Kingdom
Port of GhentBelgium
GothenburgSweden
GrimsbyUnited Kingdom
Port of HamburgGermany
Harwich International PortEnglandUnited Kingdom
ImminghamEnglandUnited Kingdom
HullEnglandUnited Kingdom
KristiansandNorway
LeithScotlandUnited Kingdom
Port of LondonEnglandUnited Kingdom
MiddlesbroughEnglandUnited Kingdom
NewcastleEnglandUnited Kingdom
OostendeBelgium
OsloNorway
Port of RotterdamNetherlands & Europoort
StavangerNorway
TerneuzenNetherlands
Sullom VoeScotlandUnited Kingdom
SunderlandEnglandUnited Kingdom
Thamesport, Isle of GrainEnglandUnited Kingdom
Port of TilburyEnglandUnited Kingdom
VlissingenNetherlands
WilhelmshavenGermany & JadeWeserPort
ÅlesundNorway
Øresund
CopenhagenDenmark
HelsingborgSweden
MalmöSweden
Ottawa River/Saint Lawrence River
MontrealQuebecCanada
Quebec CityQuebecCanada
Trois-RivièresQuebecCanada
BécancourQuebecCanada
Gulf of Paria
PedernalesVenezuela
Point LisasTrinidad and Tobago
Port of SpainTrinidad and Tobago
ScarboroughTrinidad and Tobago - since 1991
Tyrrhenian Sea
CivitavecchiaItaly
NaplesItaly
LivornoItaly
Arctic Ocean
List of ports and harbours of the Arctic Ocean
AkureyriIceland
ArkhangelskRussia
BarrowAlaskaUnited States
BelomorskRussia
ChurchillManitobaCanada
DiksonRussia
DudinkaRussia
HammerfestNorway
HonningsvågNorway
KandalakshaRussia
IgarkaRussia
KirkenesNorway
MurmanskRussia
Naryan-MarRussia
SeveromorskRussia
TiksiRussia
PevekRussia
Prudhoe BayAlaskaUnited States
VardøNorway
VitinoRussia
Indian Ocean
List of ports and harbours of the Indian Ocean
AdelaideSouth AustraliaAustralia
Jawaharlal Nehru Port Trust, Navi Mumbai, MaharashtraIndia
CochinKeralaIndia
ColomboSri Lanka
Port of Madras, Tamil NaduIndia
DurbanSouth Africa
FremantleWestern AustraliaAustralia
Haldia, West BengalIndia
JakartaIndonesia
KakinadaAndhra PradeshIndia
Krishnapatnam, Andhra PradeshIndia
Kandla, GujaratIndia
Port of KarachiSindhPakistan
Mundra, GujaratIndia
Mangalore, KarnatakaIndia
Machilipatnam, Andhra PradeshIndia
MaputoMozambique
MogadishuSomalia
Port of MumbaiMaharashtraIndia
Paradeep, OdishaIndia
PortlandVictoriaAustralia
Port HedlandWestern AustraliaAustralia
Port ElizabethSouth Africa
Port LincolnSouth AustraliaAustralia
Port LouisMauritius
Port PirieSouth AustraliaAustralia
Port Blair, Andaman & Nicobar IslandsIndia
Richards BaySouth Africa
MombasaKenya
VisakhapatnamAndhra PradeshIndia
Port of Kolkata, West BengalIndia
Tuticorin, Tamil NaduIndia
Gulf of Aden
AdenYemen
BerberaSomalia
MukallaYemen
Port of DjiboutiDjibouti
Arabian Sea
Gwadar Port, Gwadar, BalochistanPakistan
Karachi PortKarachiSindhPakistan
Keti Bandar, SindhPakistan
Port Qasim, SindhPakistan
Port of Ormara, Ormara, BalochistanPakistan
Port of Pasni, Pasni, BalochistanPakistan
Mundra PortGujaratIndia
New Mangalore port, KarnatakaIndia
INS Kadamba, KarnatakaIndia
Cochin PortKeralaIndia
Kandla PortGujaratIndia
Mormugão, GoaIndia
Jawaharlal Nehru Port Trust, Navi Mumbai, MaharashtraIndia
Al Duqm Port & Drydock, Duqm, Al Wusta Region, Oman
Port of Salalah, Salalah, Dhofar GovernorateOman
Port of BushehrBushehr ProvinceIran
Bandar-Abbas, HormozganIran
Bay of Bengal
Chennai, Tamil NaduIndia
Cuddalore, Tamil NaduIndia
Chittagong PortChittagong Bangladesh
Ennore, Tamil NaduIndia
KakinadaAndhra PradeshIndia
Machilipatnam, Andhra PradeshIndia
Mongla PortKhulnaBangladesh
Nagapattinam, Tamil NaduIndia
Paradeep, OdishaIndia
Tuticorin, Tamil NaduIndia
VisakhapatnamAndhra PradeshIndia
Gangavaram PortVisakhapatnamAndhra PradeshIndia
Dhamra, OdishaIndia
Gopalpur, OdishaIndia
Hooghly River
Haldia, West BengalIndia
Port of Kolkata, West BengalIndia
Strait of Malacca
Johor PortMalaysia
Port KlangMalaysia
Northport
West Port
Southpoint
PenangMalaysia
Port of SingaporeSingapore
Tanjung Langsat PortJohorMalaysia
Port of Tanjung PelepasMalaysia
Gulf of Martaban
YangonMyanmar
Sea of Oman
Port of ChabaharIran
Port Sultan Qaboos, Muttrah, Muscat GovernorateOman
Port of Sohar, Sohar, Dhofar GovernorateOman
Khawr Fakkan, Sharjah, UAE
Gwadar PortBalochistanPakistan
Chingari PortSindhPakistan
Persian Gulf
Bandar AbbasIran
Bandar Imam KhomeiniIran
DammamSaudi Arabia
DohaQatar
Dubai, UAE
Hamriyah Port, Sharjah, UAE
KhafjiSaudi Arabia
KhobarSaudi Arabia
Shuwaikh port, Kuwait
Jebel Ali, Dubai, UAE
JubailSaudi Arabia
Khalifa Bin Salman PortHiddBahrain
Mina Salman PortManamaBahrain
Ras TanuraSaudi Arabia
Port Phillip
GeelongVictoriaAustralia
Port of MelbourneAustralia
Red Sea
AqabaJordan
Ain SokhnaEgypt
AssebEritrea
Djibouti CityDjibouti
DubaiSaudi Arabia
Port of EilatIsrael
Farasan (city), Saudi Arabia
HurghadaEgypt
JeddahSaudi Arabia
JizanSaudi Arabia
MassawaEritrea
Port SudanSudan
RabighSaudi Arabia
SuezEgypt
YanbuSaudi Arabia
Pacific Ocean
List of ports and harbours of the Pacific Ocean
AcapulcoMexico
AucklandNew Zealand
AuroraPhilippines
BuenaventuraColombia
Cabo San LucasMexico
Cagayan FreeportPhilippines
Caldera, PuntarenasCosta Rica
CallaoPeru
CorintoNicaragua
Port of DavaoPhilippines
Port of EnsenadaMexico
EurekaCaliforniaUnited States on Humboldt Bay
Fraser PortBritish ColumbiaCanada
GuayaquilEcuador
Port of Hong Kong, People's Republic of China
HonoluluHawaiiUnited States
IquiqueChile
Port of KobeJapan
LegazpiPhilippines
Port of Long BeachCaliforniaUnited States
Port of Los AngelesCaliforniaUnited States
LytteltonNew Zealand
NapierNew Zealand See also: Port of Napier
MazatlánMexico
Panama CityPanama
Port ChalmersNew Zealand
Port HuenemeCaliforniaUnited States
Puerto MonttChile
Port of NapierNew Zealand
Port of Prince RupertBritish ColumbiaCanada
Puerto VallartaMexico
San AntonioChile
Port of San DiegoCaliforniaUnited States
SurigaoPhilippines
TabacoPhilippines
TaurangaNew Zealand
TimaruNew Zealand
ValparaísoChile
Viña del MarChile
WellingtonNew Zealand
Port of YokohamaJapan
Sai Gon New Port, Ho Chi Minh CityViet Nam
Columbia River
Port of LongviewWashingtonUnited States
Port of PortlandOregonUnited States
Drake Passage, Beagle Channel and Strait of Magellan
Puerto WilliamsChile
Punta ArenasChile
UshuaiaArgentina
Sacramento–San Joaquin rivers
SacramentoCaliforniaUnited States
Gulf of Alaska
Port of AnchorageAlaskaUnited States
JuneauAlaskaUnited States
Arafura Sea
DarwinNorthern TerritoryAustralia
Bering Strait
NomeAlaskaUnited States
Bohai Sea
Tianjin, People's Republic of China
Dongying, People's Republic of China
Qinhuangdao, People's Republic of China
Jinzhou, People's Republic of China
Yingkou, People's Republic of China
Hangu, People's Republic of China
Gulf of Carpentaria
WeipaQueenslandAustralia
Coral Sea
BundabergQueenslandAustralia
Port of BrisbaneQueenslandAustralia
GladstoneQueenslandAustralia
Hay PointQueenslandAustralia
Port MoresbyPapua New Guinea
TownsvilleQueenslandAustralia
East China Sea
Ningbo, People's Republic of China
KaohsiungTaiwan
KeelungTaiwan
Gulf of Thailand
BangkokThailand
Laem ChabangThailand
Sihanoukville Autonomous Port, Kingdom of Cambodia
Korea Bay
Dalian, People's Republic of China
Lushun/Lushunkou, People's Republic of China
Namp'o, North Korea
Sinǔiju, North Korea
Yangtze River / Changjiang
Chongqing, People's Republic of China
Port of Shanghai, People's Republic of China
Wuhan, People's Republic of China
Gulf of California
Port of Pichilingue/La Paz, Mexico (UNESCO Whale Sactuary and Bio-Reserve)
Sea of Japan
Port of BusanSouth Korea
RasonNorth Korea
HungnamNorth Korea
GangneungSouth Korea
NakhodkaRussia
VladivostokRussia
VostochnyRussia
WonsanNorth Korea
Puget Sound/Strait of Georgia
Port of VancouverCanada
Port of BellinghamWashingtonUnited States
Port of EverettWashingtonUnited States
Port of SeattleWashingtonUnited States
SurreyBritish ColumbiaCanada
Port of TacomaWashingtonUnited States
Port of VancouverBritish ColumbiaCanada
VictoriaBritish ColumbiaCanada
San Francisco Bay
Port of OaklandCaliforniaUnited States
Port of Redwood CityRedwood CityCaliforniaUnited States
RichmondCaliforniaUnited States
San FranciscoCaliforniaUnited States
VallejoCaliforniaUnited States
StocktonCaliforniaUnited States
PittsburgCaliforniaUnited States
South China Sea
BatangasPhilippines
Cam RanhVietnam
CebuPhilippines
Da NangVietnam
Hai PhongVietnam
IloiloPhilippines
Ka-Ho, Macau (People's Republic of China)
Kemaman PortTerengganuMalaysia
Ho Chi Minh City (Saigon port), Vietnam
Port of Kaohsiung, Republic of China (Taiwan)
Kota Kinabalu, SabahMalaysia
Kuantan PortPahangMalaysia
Kuching PortSarawakMalaysia
Miri PortSarawakMalaysia
Rejang PortSarawakMalaysia
Bintulu PortSarawakMalaysia
Kwai Chung, Hong Kong, People's Republic of China
Port of ManilaPhilippines
Muara PortBrunei
Puerto PrincesaPhilippines
Port of ShenzhenGuangdong, People's Republic of China
Subic BayPhilippines
Tuen Mun, Hong Kong People's Republic of China
Van PhongVietnam
Yantian, ShenzhenGuangdong, People's Republic of China
Zamboanga, Philippini
Pearl River / Zhujiang
Port of GuangzhouGuangdong, People's Republic of China
Tasman Sea
Botany Bay (Port Botany), New South WalesAustraliaHobartTasmaniaAustralia
NelsonNew Zealand
NewcastleNew South WalesAustralia
New PlymouthNew Zealand
Port Jackson (Sydney Harbour), New South WalesAustralia
Port KemblaNew South WalesAustralia
Yellow Sea
HaenamSouth Korea
Port of IncheonSouth Korea
Qingdao, People's Republic of China
Rizhao, People's Republic of China
Tianjin, People's Republic of China
Weihai, People's Republic of China