OWS/Pollution prevention

Question 1

What is the problem with bilge water content on modern vessels?

Answer 1

The bilge water content on modern vessels not only contains diesel oil and water but also lube oil, hydraulic oil, heavy fuel oil and oil additives. This sort of mixture has to be separated into three distinct phases. Oil, water and sludge.

The other problem is the presence of emulsions, which are mixtures of immiscible liquids such as tiny oil droplets mixed into the bilge water. This is normally able to be dealt with by gravity, which will cause these droplets to separate from the water but if the bilge water contains chemicals from cleaning products used on board will then these will prevent this process from happening.

Question 2

Why is the type of pump used for delivering oily water mixture important?

Answer 2

The type of pump used for delivering the oily water mixture is important because it controls considerably the degree of contamination in the effluent (liquid waste/sewage). The best type of pumps to use are the positive displacement pumps for example reciprocating pumps or gear pumps, which enable better performance from the OWS as they will not produce large quantities of small oil droplets. As oppose to for example centrifugal pumps which churn the oily water and produce small oil droplets dispersed throughout the water

Question 3

Draw a cross-sectional diagram of an oily-water separator system suitable for oil discharges of less than 15ppm. Indicate on the diagram the flow of fluid through the separator and label all major component parts.

/Or,

Sketch an Oily-water separator system that complies with present legislation.

Answer 3

SEE EOOW ORAL/IAMI Sketch Pack for drawing

Question 4

With reference to the disposal of bilge water from the machinery spaces:

a) Explain when it is not permissible to discharge the bilge water overboard,
even via an oily water separator; (8)

b) State the maximum permissible oil content of the overboard discharge. (2)

c) Identify the documentation to be completed and state by whom, following such an operation. (6)

Answer 4

a.) it is not permissible to discharge bilge water overboard, which contains oil from ships of 400GT and above in the event of the following circumstances

 if the ship is within the Antarctic area.

 if the ship is NOT proceeding en route (in other words, the vessel is alongside, anchored, or at rest).

 if the oil content exceeds 15ppm.

 if the oily mixture originated from cargo pump-room bilges on oil tankers.

 if the oily mixture, in the case of oil tankers, is mixed with oil cargo.

 If less than 12 miles offshore.

 if the vessel is not in compliance with MARPOL: Annexe 1. (Regulations for the prevention of pollution by oil)

 if the oil-water mixture hasn’t been processed through approved oil filtering equipment.

b.) 15 ppm (parts per million).

c.) Following such an operation, an entry has to be made in the Oil Record Book. The officer-in-charge has to complete an entry and sign after each completed operation, and the Master then countersigns every completed page and the C/E. Then, fill out the ER Log book, which is also signed by the watch-keeper and chief engineer and the master

Question 5

a) Describe the procedure for operating the oily water separator (12)

Answer 5

a.) 1. the OWS overboard discharge valve is kept locked and keys are kept with the C/E, therefore the the first step is to inform the bridge and C/E that you wish to discharge the bilge water via the OWS. you can also then verify with the bridge if the vessel is in compliance marpol annex 1 regualtions, like for example the vessels position to check if its at least 12miles from shore and not in any special area and proceeding en route. the chief engineer has overall authority on the OWS system and therefore must supervise the EOOW to ensure hes operating the system correctly.

2. Fill the OWS with fresh water to flush both 1st stage and 2nd stage compartment and test the OCM alarm ensuring the discharge stops during alarm state.
3. Sound bilge holding tank and record results.
4. Open all the other valves of the system including recirculation line/discharge to bilge.
5. Open the desired bilge tank valve from which the oily water mixture is to be discharged from OWS.
6. Open air if the control valves are air operated. then Switch on the power supply of the control panel and OCM unit.
7. Fill the separator and filter unit with fresh or sea water to prime the system and flush out any oil.
8. Start the OWS supply pump, which is a laminar flow pump that will supply the oily water mixture to OWS
9. Observe the OCM for ppm value and keep checking sounding level of bilge holding tank from where OWS is taking suction and also of the OWS sludge tank. also monitor the three-way control valve for correct operation. this valve should automtically close the O/B discharge line and direct the bilge water through the recirculation line back to bilge holding tank should the oil content exceed 15ppm.
10. OWS is put in full auto control and the O/B discharge valve is opened start suction from bilge holding tank, directing the bilge water overboard and constantly recording the results. at the same time as the O/B discharge valve is opened you need to ensure you log the time when the discharge is started as well the starting volume of the bilge holding tank and the position of vessel.
11. During discharge operation observe the level of bilge tank from where OWS is taking suction and of the OWS sludge tank by sounding the tanks. also monitor the sample valve which is provided just before overboard valve and after the 3-way valve. Keep a check on the sample for any effluent and clarity
12. After discharge quantity is reached so the operation is finished, stop OWS supply pump and close O/B discharge valve. then Flush OWS with clean water. Sound bilge holding tank for the final volume and make records in ER logbook and ORB.
13. After the operation, switch off the power, close all valves and ensure the overboard valve is closed and locked. Inform bridge and C/E that operation finished and then Keys for O/B dicharge valve are handed over to the Chief Engineer
14. An entry in the Oil Record Book (ORB) is made by C/E with his signature and Operating Officers signature and the Master for every completed page. the Oil record Book must be filled out correctly and in the correct format as its a legal document.

Question 6

State TWO ways that the separator could be made to operate more
efficiently. (4)

Answer 6

1. adding a tube skimmer to prevent oil build up, continuously remove oil from the surface, and keep your oil water separator working as designed.
2. Install Dust Filter: While using OWS for discharging bilge mixture containing dust and sand, it will be difficult for the coalescer filter to pass dust and sand due to size. installing this filter will reduce the operating hours of the filter and in-turn the efficiency of the OWS.

Question 7

State the effect that EACH of the following would have on the efficiency of the separator:

i) The addition of heat to the separator (4)

ii) Agitating the bilge water before it is pumped. (4)

Answer 7

b.) i.) slightly increasing the temperature of the bilge water would give better separation because it will reduce viscosity. increasing temperature will increase the specific density differential of the oil and water, which would aid in the separation.

ii.) The larger the oil droplets, the faster the rate of separation. Agitating it will mix the water and oil, making the droplets smaller, making separation more difficult. Also, it can lead to turbulent flow inside the OWS, resulting in a fall in OWS capacity due to the formation of emulsion.

Question 8

With the aid of a sketch describe a two stage OWS

Answer 8

see sailors notebook

Question 9

What is Oily Water Separator ?

Answer 9

The oily water separator (OWS) is a very important piece of equipment / device carried on board to separate the mixtures of oil and water into their separate components.. An oily water separator is used to treat the oil — water mixture from bilge spaces , oil in any compartment in the ship which has accumulated water ,before discharging into the sea. Oily water separator is used on ship to prevent the discharge of oil overboard mainly when pumping out Bilges. It is used for de ballasting or cleaning oil tanks.

Question 10

On Which Principle Oily water separator Works?

Answer 10

Oily water separator Works on the Principle of Separation by Gravity Differential between the oil and water.

Question 11

why we use oily water separator ?

Answer 11

1.Because free oil and oily emulsions discharge in the water way can interfere with the natural process such as photosynthesis and re-aeration and induced the destruction of algae and plankton so essential to fish life .

2.Inshore discharge of oil can cause damage to birds life and Mass pollution of beaches .

Question 12

difference between oily water separator and centrifuge?

Answer 12

-Oily water separator are required to handle large quantity of water from which usually a small amount of oil must be removed

-centrifuge is required to remove usually a small quantity of water from much larger amount of oil

Question 13

what is the working principle of the OWS?

Answer 13

The fundamental principle of separation by which oil / water separators work is the difference of gravity between oil and water. The oil exists in oily water mixtures as a collection of globules (small particles) of various sizes. The force acting on such a globule which causes it to move in the water is proportional to the difference in weight between the oil particle and an equal volume water particle. The resistance to movement of the globule depends on its size and the the fluid viscosity. In the case of small particles moving under streamline flow conditions, the relationship between these properties can be expressed in Stoke ‘s Law.

Question 14

What are ways of improving and speeding up the operation?

Answer 14

a high separation rate is encouraged by the large size of the oil globule, the elevated system temperature (which increases the specific gravity differential of oil and water and reduces the viscosity of the oil) and the use of seawater. Turbulence or agitation should be avoided as it causes the oil to be mixed and causes a large amount of small oil droplets. Laminar or streamlined flow (uninterpted flow, flow rate is the same and direction remain unchanged at all times) is beneficial for good operation of OWS. In addition, the heating coils can provided to improve separation by increasing temperature and reducing viscosity.

Most systems are fitted with a back flushing connection. Backflushing allows the separator to be filled with clean water before and after operation and backflushing should be carried out each time the
separator is used. The separator should also be backflushed after a malfunction such as high oil
content in the water discharge. The water and oil from backflushing is normally discharged into the
bilge waste tank. According to regulations there MUST be a procedure for operating the OWS
posted next to the machinery.

Question 15

what is meant by Stoke ‘s law?

Answer 15

Stoke’s Law is a mathematical equation that expresses the settling velocities of the small particles in a fluid medium. it consider the forces acting on a particular particle as it sinks through the liquid under the influence of gravity. the velocity or rise and hence the separation rate is directly proportional to the
difference in density of the oil and the continuous fluid, and the size of the droplets of oil. It also states that rate of rise is inversely proportional to the
viscosity of the surrounding fluid.

Question 16

what 3 units does the OWS consist of

Answer 16

1.Separator unit
2. coalescing Filter unit
3.control unit (oil content monitoring)

Question 17

what could be the reason for improper functioning of Oily water separator

Answer 17

a High rate of separation is favoured by large size oil droplets, elevated temperature of the system which affects both specific gravity differential of the oil and viscosity. the rate of separation also depends on the size of oil droplets and any disintegration of oil droplets in the feed to the separator should be avoided and this factor can be seriously affected by the type and rating of the pump used. A positive displacement pump for example screw, reciprocating or gear pump should therefore be used to improve OWS performance as they do not produce large quantity of small oil droplets as oppose to centrifugal pumps. from the above its evident that the following factors can cause improper functioning of the separator.

1.Throughput of the separator is excessive, this agitates the bilge water and may cause turbulence leading to an increase in small oil droplets.

2.excessive rolling and pitching of the ship will causing disintegration of oil droplets and again lead to a large amount of small oil droplets

3.pump type or and rating is not matching causing too much turbulence.Turbulence caused due to high pumping rate.

4. bilge water containing cleaning chemicals is one of the primary reasons for oily water filtration system failure. Cleaning fluids based on detergents may form chemically stabilized oil emulsions that cannot be separated on board ships just by gravity. Avoiding the use of surfactant-based cleaning chemicals is the greatest strategy to optimize the effectiveness of oily bilge water separation equipment, which is why bilge management is very important you need to ensure there are no chemical detergents in the bilges.

Question 18

Describe the OWS, 1st stage Separator unit

Answer 18

Separator Unit

This unit contains catch plates and and oil collection chamber both of which are inside the 1st stage separating compartment. The OWS supply pump delivers clean sea water to the first stage separation compartment through the inlet valve. The air vent located on top of the separation compartment is kept open till all the air is removed from the separator and then the oily water mixture is pumped through the separator central inlet pipe into course separating compartment . Here, because of its lower density, large oil globules separate and rise into the oil collection spaces. The remaining oil-water mixture now flows down into the fine separating compartment and passes gradually between the catch plates. Almost all the oil passes through the central pipe and leaves the separator unit. The purity at this point will be 100ppm or less. An automatically operated valve releases the oil into the separate oil tank. The oil drain valve from the top of the first stage separated is a diaphragm controlled piston valve so control air must be supplied to the diaphragm for valve to operate. For the solenoid operated valve, the capacitance probe senses oil quantity in the oil collection space and solenoid valve energizes. Steam or electric heating coils are provided in the upper and sometimes the lower part of the separator, depending upon the type of oil to be separated. (heating reduces viscous drag of oil and thus makes separation of oil and water easier)

Question 19

Describe the OWS Filter unit

Answer 19

The Filter Unit

This is a separate unit whose input comes from the discharge of the first unit. The unit consists of three stages — the filter stage, the coalescer stage and the oil collection chamber. The impurities and the particles are separated by a filter and settled down to the bottom for removal. The second stage filter uses coalescer filter for final de-oiling. Coalescence is the breakdown of surface tension between oil droplets in and oil water mixture which causes them to join and increase in size.

Question 20

Describe the OWS OCM unit

Answer 20

Oil Content Monitoring unit

Regulations on the discharge of oily water, set a concentration limit of ,up to 15 parts per million. A monitor is required to measure these values and to provide both continuous recordings and alarms when the level exceeded. The principle used is ultra-violet fluorescence. This is the emission of light by a light-absorbing molecule. An OCM takes a sample from the OWS overboard discharge line and shines a UV light
through the sample to an optical sensor. Since
small oil droplets will diffract and diffuse light,
a change in signal at the sensor will indicate the
presence of oil. the fluorescence of oil is monitored by a photoelectric cell. The measured value is compared to that of the maximum desired value in the control unit. When an excessive level of contamination is detected, the alarm is sounded and the 3 way diverting valve is operated. The discharging liquid is then passed to bilge holding tank via recirculation line. If the 15 ppm oil content monitoring device detect discharge of oil content over 15 ppm, it shuts the unit down and activates the alarm.

Question 21

State the MARPOL requirements for an OWS

Answer 21

The rules and Regulations that govern the operation of an Oily Water Separator are all stated in MARPOL Annex I: “Prevention of pollution by oil”. MARPOL ANNEX I, limits the oil content in the bilge water that a vessel can legitimately discharge into the sea to 15ppm. It is also now a requirement for all vessels to have an oil discharge monitoring and control system along with oil filtering equipment known as the Oily Water Separator (OWS).

The rules stated under MARPOL annexe 1 include the following;

1.Vessels above 400 GT and less than 1000 GT must have approved oil filtering equipment that is Approved by an Administration (competent authority). in addition to this any oily mixture being discharged into the sea after passing through the equipment has an oil content not exceeding 15 ppm

2.Vessels above 1000 GT must also have oil filtering equipment but in addition to the above the OWS must be provided with alarm arrangements to indicate when the level cannot be maintained and arrangements to ensure that any discharge of oily mixture is automatically stopped when the oil content of the effluent exceeds 15 ppm

3.Any discharge into the sea of oil or oily mixtures from ships of 400 gross tonnage and above is prohibited except when all the following conditions are met

The ship is en route
(travelling from one port to another)

The oily mixture is processed through an oil filtering system

The oil content of the effluent ( liquid waste or sewage discharged into the sea) without dilution does not exceed 15ppm.

In case of oil tankers, oily mixtures must not originate from the cargo pump room bilges and must not be mixed with oil cargo residues

As per the MEPC 107(49), the bilge alarm or an Oil Content Monitor (OCM), which provides for internal recording of alarm conditions, must be certified by an authorized organization

The OCM must activate and sound an alarm whenever freshwater is used for cleaning purposes

The OWS must only be operated by officers who are familiar with the equipment and who are directly supervised by the Chief Engineer, who bears sole responsibility for its maintenance and operation.

When the equipment is not in use, the Chief Engineer is responsible for ensuring that a procedure is in place to lock it out to prevent unauthorized operation with keys in possession of the Chief Engineer.

It should be emphasized that sailing from a port without a functional OWS is illegal and that appropriate spares for the unit must be carried onboard.

4.In respect ofthe Antarctic area,any discharge into the sea of oil or oily mixtures from any ship shall be prohibited.

5.Exceptions

The discharge into the sea of oil or oily mixture is necessary for the purpose of securing the safety of a ship or saving life at sea; or

the discharge into the sea of oil or oily mixture is as a result of damage to a ship or its equipment. provided that all reasonable precautions have been taken after the occurrence of the damage or discovery of the discharge for the purpose of preventing or minimizing the discharge and the master must not have acted either with intent to cause damage, or recklessly and with knowledge that damage would probably result; or

the discharge into the sea of substances containing oil, approved by the Administration, when being used for the purpose of combating specific pollution incidents in order to minimize the damage from pollution. Any such discharge shall be subject to the approval of any Government in whose jurisdiction it is contemplated the discharge will occur.

Question 22

What is the Dismantling Procedure for cleaning oil water separator

Answer 22

1. First stop the O.W.S Bilge pump
2. stop the steam flow to heating coils
3. Shut the main overboard valve
4. Open vent for both separation and filtration chamber
5. Slowly open the drain valve of each section at the bottom
6. Oil must be drained out
7. All electric and pipe connections must be removed
8. Nut and bolts of the top cover of the separation chamber must be opened.
9. Baffle plates should be taken out and cleaned with a brush and oil.
10. Now open all the nuts and bolts of the top cover of the separation chambers.
11. The condition of the coalescer filters must be inspected.
12. If necessary, put back a new filter.
13. After everything is over, assemble the whole system and fill the O.W.S with fresh, clean water to check for any leakage.

Question 23

what are the Factors Affecting Separation Of Oil From Bilge Water

Answer 23

Several factors affect the separation of oil from bilge water, such as :

1. Density: the density of oil should be kept low as possible as Lighter oil will have a higher rate of rise than heavier oil and therefore will be easier to separate. this can be adjusted by increasing temperature as the relationship between temperarature and density is inversely proportional.
2. Adequate Density Difference: the continous fluid (Seawater or fresh water), to use is sea water as it has more density than that freshwater. Thus, by using seawater, we can increase the rate of separation by maintianing a good density difference.
3. The viscosity of Continous Fluid: we know a less dense fluid with less viscosity offers better conditions for oil to move towards the surface than a dense fluid with more viscosity. The viscosity of fresh water is less than that of seawater so techically this contradicts the above point about sea water being used as the continous fluid. By increasing temperature we can reduce viscosity and density so it doesnt really matter which continous fluid is used.
4. Temperature: Temperature plays a vital role. It is a significant factor that affects both density and viscosity.
   Low temperature of the continuous fluid has a negative effect on the separation of oil globules due to additional viscous drag and increased viscosity of continuous fluid in cold temperature. Oil separation is better in warmer temperatures and increasing the temperature of the bilge water would give better
   separation. temeprature can be increased by heating coils or by warming the bilge water in the bilge holding tank. however its important to only slighlty heat the bilge water as a high temperature will lead to formation of emulsion and agitation of bilge water.
5. Size of particles: The separation of oil from water is directly proportional to the size of oil particles. the larger the oil droplets the faster the rate of seperation.

Question 24

Describe the Maintenance carried out on Oily Water Separator

Answer 24

if the bilge management is not proper the Oily Water Separator (OWS) is bound to malfunction. Good bilge management practices helps in optimizing the performance of the Oily Water Separator.
In the engine room the bilges and bilge wells are located at the very bottom of the engine room and collect all oil and water from leakages of machinery, as well as condensate and wastes so that they can be pumped to the bilge holding tank. therefore bilge management is very important.

the bilge can be managed by doing the following

Waste oil should not be intentionally put in the bilges
or bilge tank. all waste oil can be directed into seperate oil tank or sludge tank.Thereafter it can either be burnt in the incinerator or transfered ashore.

cleaning chemical detergents should not be put in the bilge as pH of water above 10 and below 4 can cause
chemical emulsification of the bilge water and lead to
difficulty in separation of oil and water.

Put drip trays where there are leakages and thereafter
rectify and stop the leakages.

Primary bilge tank is provided on new ships and this should be used properly and not bypassed. this uses gravity differential just like the OWS to seperate some of the oil before hand from the water before it goes to OWS. The primary bilge tank helps in separation of the oil from the water and the oil can be visually seen and put in dirty oil tank and the cleaner bilge
water can be put to the bilge tank. Steam coils are provided in the primary bilge tank and they can be used for effective separation.

Use clean drain tank effectively. In tropical climates there is condensation of more than 1-2 cubic meters per day and this water if allowed to go to the bilge tank will increase the load of the oily water separator. As this is mostly clean water, it should not be allowed to go to the bilge tank; instead it should be put to the clean drain tank and thereafter properly disposed. The leakages from the fresh water and sea water pumps should also be put in the clean drain tank

To remain in excellent operating condition, an oily water separator must be properly and routinely maintained. When devices are not drained and cleaned consistently, oils and other debris clog them and make them inoperable. This may result in oil levels in the discharged water exceeding the effluent limitations (15ppm).

OWS catch plates will need to be cleaned once all of this has been completed. They may be cleaned outside the unit by dismantiling OWS. Remove any debris from the catch plates.

While maintenance is being performed inside the OWS, do not damage the anti-corrosive surface (normally provided where the liquid is in contact with the body) by doing welding or brushing.

Keep checking the back pressure for the coalescers and if the pressure exceeds the rated pressure, renew the same. Periodic cleaning of OWS to be performed by removing any water scale, sludge, dust, bacteria etc. from the internal surfaces.

Don’t avoid maintenance routines on the bilge pump as increase in the wear of the pump will result in leakage of fine particles which are difficult to be separated by filters and which will later affect the separator’s performance.

Clean the oil level sensor electrode at regular interval
The solenoid valve may malfunction due to fouling,which may occur after a long period of operation. The solenoid valve must be cleaned at regular interval.

The outlet pipe of the OWS (distance pipe between OWS and overboard discharge valve) should be opened up once a month to check for traces of oil. If found, it can be because OCM is malfunctioning or misoperation of OWS is being performed

The alarm and function of the three way valve and solenoid valves must be checked every week.

Do not forget to record all operation and maintenance
performed on OWS in the Oil Record Book (ORB).

Question 25

What are the annexes of MARPOL?

Answer 25

Annex I - Prevention of Pollution by Oil

Annex II - Control of Pollution by Noxious Liquid Substances in Bulk

Annex III - Prevention of Pollution by Harmful Substances Carried at Sea in Packaged Form

Annex IV - Prevention of Pollution by Sewage from ships

Annex V - Prevention of Pollution by Garbage from Ships

Annex VI - Prevention of Air Pollution from Ships

Question 26

What does Annex I contain?

Answer 26

1) Special tanks for sludge and tank protection.

2) Oil filtering equipment including ORB.

3) Control of discharge of oil and segregation of tanks.

4) Construction specifications for oil tankers.

5) Requirements for cargo areas of tankers.

6) SOPEP.

7) Oil transfer between tankers at sea.

8) Requirements in polar waters.

Question 27

What does Annex II contain?

Answer 27

1) Categorising of substances.

2) Design and construction of equipment.

3) Cargo record book.

4) Port state controls.

5) Reception facilities.

6) Shipboard Marine Pollution Emergency Plan.

7) Verification of compliance.

Question 28

How are the categories of noxious liquid substances divided?

Answer 28

Category X has the most severe pollution hazards, category Y has moderate pollution hazards, category Z has low pollution hazards and category OS has no hazards when discharged from tank cleaning or de-ballasting operations.

Question 29

What does Annex III contain?

Answer 29

Correct packing, labelling, documentation, stowage and quantity limitations.

Question 30

What does Annex IV contain?

Answer 30

1) Sewage systems and control of discharge.
2) Reception facilities
3) Port state control

Question 31

What does Annex V contain?

Answer 31

1) Areas for garbage discharge
2) Garbage record keeping
3) Polar waters

Question 32

What does Annex VI contain?

Answer 32

1) Emission requirements for NOx, SOx, , particulate matter and Ozone Depleting Substances

2) Fuel availability and quality.

3) Energy efficiency.

4) Detection of violations and enforcement.

5) Garbage record book for incineration.

Question 33

What are the Annex I ECAs?

Answer 33

1) Mediterranean sea
2) Baltic sea
3) Black sea
4) Red sea
5) Gulf
6) Gulf of Eden
7) Antarctic
8) North-West European Waters
9) Oman area of the Arabian Sea
10) Southern South African Waters

Question 34

How can you reduce the effect of air pollution when in port?

Answer 34

1) Switch to low-sulphur fuel.
2) Turn engines off as soon as is safe to do so.
3) Utilise shore-side power
4) Use scrubbers.

Question 35

How are nitrogen oxides generated in combustion?

Answer 35

The heat from combustion acts as a catalyst which binds the Nitrogen and Oxygen.

Question 36

What are ways to reduce NOx emissions on ship?

Answer 36

1) Exhaust gas recirculation - Reduces oxygen content of air.
2) Water injection - Reduces the temperature of combustion.
3) High scavenge pressure and compression ratio - Lower combustion temperature.
4) Selective catalytic reduction - 90-95% reduction exhaust gas mixed by water solution of urea and passed through catalytic reactor. Requires low sulphur fuel and exhaust gas over 300 degrees.

Question 37

What equipment should be in the SOPEP locker?

Answer 37

1) Oil dispersant
2) Sawdust
3) Rags
4) Absorbent pads
5) Oil kit bags
6) Scoops
7) Shovel
8) Brooms & brushes
9) Buckets
10) Drums
11) Rubber suits / boots / gloves
12) Wilden pump with hoses

Question 38

What areas on a vessel are that most risk of potential oil pollution?

Answer 38

• Engine room bilges.
• Bunker operations.
• Cargo operations on oil tankers.
• Tank washing and ballasting operations on oil tankers.
• Tanker accidents.

Question 39

what is an ORB?

Answer 39

Oily Record Book - ORB

Every ship (400 GRT and above) is required to have what is known as Oil Record Book Part I. It is an
official document where entries are made on following occasions:

1. Ballasting or cleaning of fuel oil tanks.
2. Discharge of dirty ballast or cleaning water from oil fuel tanks.
3. Collection and disposal of oil residues (sludge).
4. Discharge overboard of machinery space bilge water.
5. Bunkering of fuel.
6. Bunkering of bulk lubricating oil.
7. Any failure of the oil filtering equipment

Question 40

what is an International Oil Pollution Prevention (IOPP) Certificate?

Answer 40

An IOPP Certificate is issued to all the ships (400 GRT and above) by the flag
state administration. The possession of this certificate on board a ship is a
testament to her compliance with the provisions of Annex I of MARPOL.