JP4845855B2 - Ship ballast water sampling system - Google Patents

Description

  The present invention relates to a sampling system for ship ballast water, and more particularly, to sample ship ballast water that continuously samples ballast water in order to check whether or not the ballast water taken into the ship satisfies a standard. About the system.

  A cargo ship that transports crude oil or containers is provided with a ballast tank in order to maintain the stability of the hull during navigation. Normally, when crude oil is not loaded, the ballast tank is filled with ballast water, and the ballast water is discharged when loading crude oil, containers, etc., thereby adjusting the buoyancy of the hull and stabilizing the hull. .

  As described above, the ballast water is water necessary for the safe navigation of the ship, and the seawater of the port that performs cargo handling is usually used. The amount is estimated to be 3-4 billion tons per year worldwide.

  By the way, aquatic organisms (including microorganisms and bacteria) inhabiting the port where the water is taken are mixed in the ballast water, and these aquatic organisms are transported to different countries at the same time as the ship moves.

  Therefore, the destruction of ecosystems, such as the replacement of existing species with species that did not originally live in the sea, has become serious.

  Against this background, a convention for the regulation and management of ship ballast water and sediment was adopted at a diplomatic meeting of the International Maritime Organization (IMO). It is scheduled to be applied from shipbuilding.

  For this reason, the ship is required to drain clean ballast water that satisfies the above convention.

  Conventionally, as a technique for physically treating water containing microorganisms such as plankton, Patent Document 1 discloses a technique for sterilizing or sterilizing microorganisms in ballast water by injecting ozone gas into the ballast water. Yes.

Further, Patent Document 2 discloses a technique in which water containing aquatic organisms is passed through a slit plate by a high-pressure pump to mechanically destroy and kill aquatic organisms.
JP 2004-160437 A JP 2003-200156 A Japanese Patent Laid-Open No. 9-192680 JP 2003-326275 A

Whether or not the ballast water discharged from the ship satisfies the above-mentioned criteria must be inspected by taking a part of the ballast water as sample water. In this case, in order to determine the number of aquatic organisms contained in the ballast water, it is necessary to collect a maximum of 3 m ^{3 of} sample water at a time. For this purpose, a large storage tank having a capacity of 3 m ³ is installed in the ship. It must be installed.

However, it is extremely difficult to secure a new space for installing a large storage tank having a capacity of 3 m ³ in the ship, particularly for an existing ship.

  Moreover, directly collecting ballast water from the large ballast tank divided into a plurality of chambers is a very laborious operation.

  In addition, the inspection of the aquatic organism's abundance requires a very troublesome work of observing the sample water under a microscope and confirming the aquatic organisms living in the sample water. For this reason, when the amount of sample water becomes enormous as in the case of ballast water inspection, it is necessary to start with the work of concentrating aquatic organisms from a large amount of ballast water, and the work time will be long. . During that time, the ship cannot drain ballast water, and the situation continues where neither loading nor departure is possible, which is a big loss for shipping companies. Therefore, the most important issue is to complete the inspection of the ballast water in a short time.

  However, for microscopic inspection, aquatic organisms must be concentrated alive from the ballast water, and this concentration work is extremely time consuming and laborious, and it is extremely difficult to complete the ballast water inspection in a short time. It was.

  Therefore, the present invention does not require a large storage tank, and can easily and continuously collect ballast water, and it can sample aquatic organisms contained in ballast water while alive, and a ship ballast water sampling system and It is an object to provide a sampling method for ship ballast water.

  Other problems of the present invention will become apparent from the following description.

  The above problems are solved by the following inventions.

(Claim 1)
A ship ballast water sampling system that samples the ballast water to inspect aquatic organisms contained in the ship ballast water,
It is provided in a water injection line for injecting ballast water into the ballast tank and / or a water discharge line for discharging the ballast water in the ballast tank to the outside of the ship, and a part of the ballast water is continuously supplied from the water injection line and / or the water discharge line. A sampling nozzle to collect,
A sampling device for concentrating aquatic organisms contained in ballast water collected from the sampling nozzle,
The sampling device includes a water storage container that is stored so that the stored water can be adjusted to have a constant amount of water,
A filter cloth having an upper end opening and a lower end opening, immersed in the stored water in the water storage container so that the upper end opening is exposed, and dividing the water storage container into two spaces, an outer side and an inner side;
A supply port for supplying ballast water collected from the sampling nozzle to the inside of the upper end opening of the filter cloth;
From the outside of the filter cloth in the water storage container, a drain outlet for draining the stored water in the water storage container,
It is connected to the lower end opening of the filter cloth in the water storage container, and temporarily stores water containing aquatic organisms remaining inside the filter cloth when the stored water in the water storage container is drained from the drain port. A reservoir,
Possess a container for containing the water containing pooled aquatic organisms to the reservoir,
The supply port is a nozzle provided so as to be rotatable along the inner periphery of the filter cloth when supplying ballast water to the inside of the filter cloth and / or draining the stored water in the water storage container. Ship ballast water sampling system characterized by opening at the tip .

(Claim 2)
A ship ballast water sampling system that samples the ballast water to inspect aquatic organisms contained in the ship ballast water,
It is provided in a water injection line for injecting ballast water into the ballast tank and / or a water discharge line for discharging the ballast water in the ballast tank to the outside of the ship, and a part of the ballast water is continuously supplied from the water injection line and / or the water discharge line. A sampling nozzle to collect,
A sampling device for concentrating aquatic organisms contained in ballast water collected from the sampling nozzle,
The sampling device includes a water storage container that is stored so that the stored water can be adjusted to have a constant amount of water,
A filter cloth having an upper end opening and a lower end opening, immersed in the stored water in the water storage container so that the upper end opening is exposed, and dividing the water storage container into two spaces, an outer side and an inner side;
A supply port for supplying ballast water collected from the sampling nozzle to the inside of the upper end opening of the filter cloth;
From the outside of the filter cloth in the water storage container, a drain outlet for draining the stored water in the water storage container,
It is connected to the lower end opening of the filter cloth in the water storage container, and temporarily stores water containing aquatic organisms remaining inside the filter cloth when the stored water in the water storage container is drained from the drain port. A reservoir,
A storage container for storing water containing aquatic organisms stored in the storage unit;
The sampling device has water flow generating means for generating a water flow from the outside to the inside of the filter cloth and peeling off aquatic organisms attached to the inside of the filter cloth on the outside of the filter cloth in the water storage container. Ship ballast water sampling system, characterized by

(Claim 3)
The supply port is a nozzle provided so as to be rotatable along the inner periphery of the filter cloth when supplying ballast water to the inside of the filter cloth and / or draining the stored water in the water storage container. 3. A ship ballast water sampling system according to claim 2 , wherein the ship ballast water is opened at the tip.

(Claim 4)
A drain tank for temporarily storing the water drained from the water storage container;
The ship ballast water sampling system according to claim 1 , further comprising a drain pump that continuously drains the stored water in the drain tank to the water injection line or the drainage line .

(Claim 5)
A sampling valve for opening and closing the flow path of the ballast water supplied to the sampling device;
A flow meter for measuring the supply amount of ballast water supplied to the sampling device;
The ship ballast water sampling system according to any one of claims 1 to 4, further comprising first control means for controlling opening and closing of the sampling valve based on a measurement result of the flow meter.

(Claim 6)
A drain valve for opening and closing the drain port;
The first control means closes the sampling valve based on the measurement result of the flow meter, then opens the drain valve, and drains the stored water in the water storage container from the drain port. 6. The ship ballast water sampling system according to claim 5, wherein control is performed.

(Claim 7)
A plurality of the ballast tanks are provided,
An on-off valve that opens and closes each of the water injection line and / or the drainage line of each ballast tank;
A visualization means for visualizing information;
The on-off valve is controlled to open and close so as to inject or drain ballast water for each of the plurality of ballast tanks, acquire information on the ballast tank that is injecting or draining water, and ballast water is collected by the sampling nozzle. A second control means for making a one-to-one correspondence between the ballast tank that performs the water injection or drainage and the ballast water collected by the sampling nozzle, and outputs the result to the visualization means. The ship ballast water sampling system according to any one of claims 1 to 6, further comprising:

(Claim 8)
8. The ship ballast water sampling system according to claim 7, wherein the visualization means is a monitor for displaying information on a screen and / or a printer for printing information.

  According to the present invention, it is not necessary to provide a large storage tank, and a ballast water sampling system that can easily and continuously collect ballast water and sample live aquatic organisms contained in the ballast water, and A method for sampling ship ballast water can be provided.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a configuration diagram showing an outline of a ballast water system pipe provided with a ship ballast water processing apparatus and a ship ballast water sampling system according to the present invention in plan view on an existing ballast water system pipe. Here, the container ship which loads a container as a ship is illustrated. In the figure, 1 is a hull, and 2 is a plurality of ballast tanks arranged near the bow of the hull 1.

  Ballast water is taken into each ballast tank 2 by operation of the ballast pump 4 from a sea chest 3 provided near the bottom of the ship. The ballast water to be treated in the present invention is, for example, seawater, fresh water, etc., and the ballast water includes aquatic organisms such as zooplankton and phytoplankton, microorganisms and bacteria (hereinafter, these are simply referred to as aquatic organisms). .)It is included. The ballast pump 4 is provided in a water intake pipe 5 that takes in ballast water from the sea chest 3 into the hull 1, and a strainer 6 is provided in a portion 5 ′ on the primary side (inlet side of the ballast pump 4) of the water intake pipe 5. It is installed.

  The strainer 6 is for removing relatively large contaminants in the ballast water flowing into the ballast pump 4. For example, holes of 5 to 10 mmφ, preferably 8 mmφ are opened at a pitch of 5 to 15 mm, preferably 11 mm. You can use what you have.

  Reference numeral 7 denotes a pipe arranged so as to cross the hull 1, and both ends thereof are connected to drains 8 and 8 ′ provided on both sides of the hull 1. A portion 5 ″ on the secondary side (outlet side) of the ballast pump 4 of the intake pipe 5 is connected to the middle portion of the pipe 7.

  Reference numeral 9 denotes a main pipe provided between the pipe 7 and each ballast tank 2, for injecting ballast water into each ballast tank 2 and draining the ballast water from each ballast tank 2. Connected midway. The other end is connected to a water pouring / nozzle 10 disposed in each ballast tank 2 for water pouring and draining of each ballast tank 2.

  Reference numeral 11 denotes a bypass pipe used for draining the ballast water in each ballast tank 2 to the outside of the hull 1 by operation of the ballast pump 4, and a secondary side (outlet side) portion 5 of the strainer 6 of the intake pipe 5. And the primary side (inlet side) of the ballast pump 4 and the main pipe 9 are connected to each other.

  In addition, the component of code | symbol 12a-12g is an on-off valve.

  When the ballast water is poured into each ballast tank 2 by such ballast water system piping, the on-off valves 12a, 12b, 12e, and 12g are opened, the on-off valves 12c, 12d, and 12f are closed, and then the ballast pump 4 is turned on. The ballast water is taken from the sea chest 3 through the intake pipe 5. Ballast water flowing into the intake pipe 5 from the sea chest 3 is transferred to the main pipe 9 through the pipe 7 provided so as to cross the hull 1 after large dust is removed by the strainer 6. The ballast water transferred to the main pipe 9 is poured into each ballast tank 2 from a pouring / draining nozzle 10 provided in each ballast tank 2.

  Therefore, in this case, the water intake pipe 5, the pipe 7, and the main pipe 9 constitute a water injection line for injecting ballast water into the ballast tank 2 in the ballast water system pipe.

  Further, when draining the ballast water in each ballast tank 2, when the on / off valves 12b, 12c, 12d and 12g are opened and the on / off valves 12a and 12e are closed and then the ballast pump 4 is operated, Ballast water in the tank 2 flows into the pipe 7 through the main pipe 9, the bypass pipe 11, the water intake pipe 5 and the ballast pump 4 from the pouring / drain nozzle 10, and from the drain outlets 8 and 8 ′ on both sides of the hull 1. It will be drained to the outside.

  Therefore, in this case, the main pipe 9, the bypass pipe 11, the intake pipe 5, and the pipe 7 constitute a drainage line for draining the ballast water in the ballast tank 2 outside the ship in the ballast water system pipe.

  The existing ballast water system piping is provided with a ballast water treatment device 13.

  The processing apparatus 13 branches from the midway part in the piping part 7 'between the connection site | part with the intake pipe 5 and the connection site | part with the main piping 9 among the piping 7 in the existing ballast water system piping demonstrated above. The ballast water is taken in, and aquatic organisms and bacteria in the ballast water are removed, sterilized or killed, and then returned to the pipe portion 7 ′.

  For example, a filter for removing relatively large aquatic organisms in the ballast water, or ozone generated by an ozone generator in the ballast water is injected into the treatment apparatus 13 at a predetermined concentration, thereby aquatic organisms and bacteria. Can be sterilized or killed by the strong oxidizing action of ozone, or a device that destroys aquatic organisms by shearing force generated during passage by passing ballast water through a slit plate having a slit-like opening, after ozone injection An apparatus for removing and decomposing undissolved ozone can be provided.

  Reference numerals 13 a, 13 b, and 13 c in the drawing are open / close valves for taking in and discharging ballast water between the pipe 7 and the processing device 13.

  The treatment of the ballast water by the treatment device 13 is performed when the ballast water is taken into the ship. Therefore, when the ballast water treatment is performed, the on / off valves 12a, 12b, 12e, 12g, 13b, and 13c are opened, and the on / off valves 12c, 12d, 12f, and 13a are closed, and then the ballast pump 4 is operated. The ballast water is taken from the sea chest 3 through the intake pipe 5. Ballast water that has flowed into the intake pipe 5 from the sea chest 3 is removed by the strainer 6 and then flows into the treatment device 13 through the pipe 7, where aquatic organisms and bacteria in the ballast water are removed. Sterilized or killed.

  In the present embodiment, the ship ballast water sampling system 14 according to the present invention is provided to inspect whether the ballast water after being processed by the processing device 13 satisfies the IMO standard. . This sampling system 14 is provided so that ballast water drained to the outside of the hull 1 can be collected from a pipe portion 7 ″ between a portion of the pipe 7 to which the main pipe 9 is connected and the drain port 8 ′. Yes. Details of the sampling system 14 will be described later.

  When draining the ballast water outside the hull 1, in order to remove oxidants containing harmful bromine oxides in the ballast water, it is preferable to provide a removal device 15 for removing oxidants with activated carbon as shown in FIG. . Oxidizing substances such as harmful oxidants (for example, bromine oxide) contained in the treated ballast water can be removed by the removing device 15.

  In FIG. 1, the removal device 15 is interposed between the sampling system 14 and the connection portion of the pipe portion 7 ″ of the pipe 7 with the main pipe 9. The removal device 15 is provided with, for example, an activated carbon tank, and is configured to take in ballast water drained through the pipe 7 and pass it through the activated carbon tank and then return it to the pipe 7 again.

  The removing device 15 is provided on the front side of the sampling system 14, but may be provided between the sampling system 14 and the drain 8 '.

  FIG. 2 is a configuration diagram showing an outline of the sampling system 14. Here, only four ballast tanks 2A, 2B, 2C, and 2D are shown. In addition, the same reference numerals as those in FIG.

  A part of the ballast water flowing in the pipe portion 7 ″ of the pipe 7 is collected in the sampling system 14.

  FIG. 3 is an enlarged view of a portion A in FIG. 2, and as shown in FIG. 3, a sampling nozzle 141 is provided in the pipe portion 7 '' so as to face the flow direction of the ballast water. A part of the ballast water in the pipe portion 7 ″ (hereinafter sometimes referred to as sample water) is sampled at an equal flow rate and sent to the sampling device 143 through the water sampling pipe 142. The uniform flow rate sampling is to perform sampling so that the flow rate of the ballast water flowing in the pipe portion 7 ″ and the flow rate of the sample water collected by the sampling nozzle 141 are equal. For collecting the sample water, a pressure generated by driving the ballast pump 4 is used.

Sampling nozzle 141 is for collecting successively a pipe section 7 '' part of the ballast water flowing through the of the pipe 7, in one example, the inner diameter of the pipe 7 was 300 mm In this case, the tube diameter of the sampling nozzle 141 can be set to 25 mm, for example.

  The sampling pipe 142 is provided with a flow meter 144 that measures the flow rate (integrated flow rate) of sample water and a sampling valve 145 that opens and closes the flow path of the sampling pipe 142. The measurement result of the flow meter 144 is sent to the control unit 100.

The control unit 100 checks whether or not a predetermined amount of ballast water, for example, 3 m ³ of ballast water has been sent to the sampling device 143 from the measurement result of the flow meter 144, and controls the opening and closing of the sampling valve 145. (First control means).

  Further, the control unit 100 individually controls opening / closing of the on-off valves 12g (second control means) so as to inject and drain the ballast tanks 2A to 2D one by one, and also opens and closes the pipe 7 The opening degree of the valve 14a is controlled.

  Next, details of the sampling device 143 are shown in FIG.

  In FIG. 4, reference numeral 300 denotes a water storage container, and 301 denotes a lid provided on the upper part of the water storage container 300. The water storage container 300 is formed in, for example, a cylindrical shape, and a filter cloth 303 for collecting aquatic organisms to be collected is installed therein.

  The filter cloth 303 has an upper end opening 303a and a lower end opening 303b. Preferably, the filter cloth 303 is formed in a substantially inverted conical shape that is tapered toward the lower end opening 303b from the upper end opening 303a. By being detachably attached to the upper inner peripheral surface of the water storage container 300, the water storage container 300 is installed in a suspended manner. Thereby, the inside of the water storage container 300 is partitioned into a space 300 </ b> A outside the filter cloth 303 and a space 300 </ b> B inside the filter cloth 303.

  A commercially available product can be used for the filter cloth 303. For example, a material in which warp and weft made of resin such as nylon are crossed and woven into a net shape, and the crossing part of the warp and weft is welded and fixed by heating to prevent misalignment is preferable. . The mesh of the filter cloth 303 is determined according to the size of the aquatic organism to be collected. For example, when collecting aquatic organisms having a size exceeding 50 μm, the mesh is formed to be 50 μm. As shown in FIG. 5, this scale is defined by the diagonal distance A of the lattice formed between the warp yarn 303A and the weft yarn 303B of the filter cloth 303.

A reservoir 304 is connected to the lower end opening 303 b of the filter cloth 303. The storage unit 304 is a container that temporarily stores water (concentrated water) containing aquatic organisms that finally remains inside the filter cloth 303 in the water storage container 300 and collects concentrated aquatic organisms, such as synthetic resin. For example, it is formed in a funnel shape that is sufficiently smaller than the water storage container 300. A water collection pipe 305 that is opened and closed by an on-off valve 306 is connected to the bottom of the storage unit 304. By opening the on-off valve 306, water containing aquatic organisms stored in the storage unit 304 (concentrated water). Can be stored in a storage container 307 outside the water storage container 300 . The storage container 307 is detachably provided on the water sampling pipe 305.

  The other end of the water sampling pipe 142 provided with the sampling nozzle 141 at one end reaches the inside of the water storage container 300 from above the side of the water storage container 300 and is disposed inside the upper end opening 303 a of the filter cloth 303. The nozzle 308 provided at the other end of the water sampling pipe 142 is disposed inside the filter cloth 303 below the upper end opening 303a of the filter cloth 303, and a supply port 308a opening at the end thereof has a filter cloth 303. It is bent so as to face the inner peripheral surface. The nozzle 308 is preferably provided so as to be able to rotate 360 degrees in the horizontal direction by a driving means (not shown), and the supply port 308 a is preferably rotatable along the inner periphery of the filter cloth 303.

  A liquid level sensor 309 serving as a liquid level detection means is provided below the upper end opening 303a of the filter cloth 303 and above the nozzle 308, and detects the water level inside the filter cloth 303. The detection signal of the liquid level sensor 309 is output to the control unit 100 shown in FIG.

  In the middle of the water sampling pipe 142, a switching valve 310 is interposed outside the water storage container 300, and a branch pipe 311 is branched from the switching valve 310. The branch pipe 311 is disposed from the upper side to the inside of the water storage container 300, and its tip 311 a is located outside the filter cloth 303, and is sent from the water collection pipe 142 into the water storage container 300 outside the filter cloth 303. Sample water is supplied.

In the water storage container 300, an overflow pipe 312 is provided on the outside of the filter cloth 303, penetrates the bottom 300 a of the water storage container 300, and is connected to the drain pipe 146. The overflow pipe 312 adjusts so that the excess water is overflowed and discharged out of the water storage container 300 when the water content in the water storage container 300 exceeds a certain level, and the water content in the water storage container 300 is always constant. The water level in the water storage container 300 is determined by the position of the upper end opening 312a. The upper end opening 312 a is provided below the upper end opening 303 a of the filter cloth 303, below the liquid level sensor 309, and above the lower end opening 303 b of the filter cloth 303.

  A drain port 313 is formed at the bottom 300a of the space 300A in the water storage container 300, and the stored water inside is drained to the drain pipe 146 by opening the drain valve 314. The drain valve 314 is controlled to be opened and closed by the control unit 100 shown in FIG.

  A water flow generator 315 is disposed outside the filter cloth 303 inside the water storage container 300. The water flow generator 315 generates water flow from the outside to the inside of the filter cloth 303 by injecting water toward the outer peripheral surface of the filter cloth 303 in a state where water is stored in the water storage container 300. The aquatic organism attached to the inner side of the filter cloth 303 is peeled off to assist in smoothly storing and collecting in the storage unit 304, and is preferably provided in the present invention.

  The jet of water from the water flow generator 315 can be performed using stored water outside the filter cloth 303 stored in the water storage container 300 by a driving unit such as a pump (not shown).

  The water flow generator 315 is preferably provided in a ring shape over the outer periphery of the filter cloth 303, but an appropriate number of water flow generators are divided and arranged at predetermined intervals along the outer periphery of the filter cloth 303. May be.

  The water flow generator 315 is also preferably provided so as to be movable up and down in the water storage container 300.

  Next, the effect | action of this sampling apparatus 143 is demonstrated using FIGS.

  First, as shown in FIG. 6, by operating the switching valve 310, water is supplied from the sampling pipe 142 to the space 300 </ b> A outside the filter cloth 303 in the water storage container 300 through the branch pipe 311, and the water stored in the water storage container 300 is stored. W1 is stored. The stored water W1 is preferably ballast water from the viewpoint of maintaining the habitat environment of aquatic organisms in the water storage container 300.

  The stored water W <b> 1 supplied to the outside of the filter cloth 303 in the water storage container 300 enters the space 300 </ b> B inside the filter cloth 303 through the filter cloth 303. When the stored water W1 exceeds the upper end opening 312a of the overflow pipe 312, it is stored in the water storage container 300 so as to have a constant amount of water by being drained from the overflow pipe 312.

  At this time, the upper end opening 303a of the filter cloth 303 is located above the stored water surface and is exposed from the stored water W1. In addition, even if aquatic organisms are contained in the stored water W1 in the space 300A outside the filter cloth 303, the aquatic organisms having a size exceeding the mesh of the filter cloth 303, that is, the filter cloth 303, are inside the filter cloth 303. Aquatic organisms of the size to be collected will not enter.

  When a predetermined amount of stored water W1 is stored in the water storage container 300, the sample water W2 sent from the sampling nozzle 141 through the sampling pipe 142 is filtered from the nozzle 308 through the filter cloth by operating the switching valve 310 as shown in FIG. It is supplied to the space 300B inside 303. At this time, it is preferable that the nozzle 308 is rotated in the horizontal direction. The rotation of the nozzle 308 can be set, for example, once / second.

  By supplying the sample water W2 from the nozzle 308 to the inside of the filter cloth 303, the amount of water stored in the water storage container 300 is increased, but the increased amount overflows from the overflow pipe 312 and is drained to the outside of the water storage container 300. The inside of the water storage container 300 is always kept at a constant water amount. For this reason, regardless of the volume of the water storage container 300, a desired large amount of sample water W2 can be continuously supplied.

  When the sample water W2 continues to be supplied from the nozzle 308 to the inside of the filter cloth 303 in this way, the excess amount overflows from the overflow pipe 312, so that the excess water moves from the inside of the filter cloth 303 to the outside, and the filter water is filtered. The amount of aquatic organisms of a size to be collected that cannot pass through the filter cloth 303 will increase in the cloth 303.

  At this time, since the stored water W1 is initially stored in the water storage container 300, aquatic organisms contained in the sample water W2 supplied to the inside of the filter cloth 303 are suddenly filtered and pressed against the filter cloth 303. In this case, the aquatic organism is prevented from being damaged by the filter cloth 303, and the aquatic organism is not killed.

  Further, by supplying the sample water W2 while rotating the nozzle 308, a swirl flow can be created inside the filter cloth 303. For this reason, even if aquatic organisms adhere to the inner peripheral surface of the filter cloth 303, the sample water W2 can be supplied while being peeled off by the swirling flow, so that the filter cloth 303 can be prevented from being clogged, It is possible to concentrate aquatic organisms efficiently.

  In the unlikely event that the water level inside the filter cloth 303 rises due to clogging of the filter cloth 303 or the overflow pipe 312, the liquid level sensor 309 detects it. With this detection as a trigger, the control unit 100 shown in FIG. 2 can automatically stop the supply of the sample water W2. This prevents the sample water W2 supplied to the inside of the filter cloth 303 from overflowing from the upper end opening 303a of the filter cloth 303.

The flow rate of the sample water W2 supplied from the nozzle 308 to the inside of the filter cloth 303 is measured by the flow meter 144 provided in the water sampling pipe 142 shown in FIG. 2, and the sampling valve is controlled by the control unit 100 based on the measurement result. The opening and closing of 145 is controlled. For this reason, for example, when measuring aquatic organisms contained per 3 m ³ of water, measuring 3 m ³ with this flow meter 144 requires a large-capacity tank or the like for storing the sample water W2. Therefore, a desired amount of water can be easily supplied. Moreover, since the water storage container 300 is adjusted by the overflow pipe 312 so that the inside always has a constant amount of water, regardless of the volume of the water storage container 300, it is possible to accurately supply a desired amount of water per unit water quantity. Aquatic organisms can be sampled.

  Next, when a desired amount of sample water W2 is supplied from the nozzle 308 to the inside of the filter cloth 303, the sampling valve 145 is closed by the control of the control unit 100 to stop the supply of the sample water W2, and then as shown in FIG. Furthermore, the drain valve 314 is opened by the control unit 100 and the stored water W1 in the space 300A in the water storage container 300 is drained from the drain port 313.

  During drainage, not only the stored water W1 outside the filter cloth 303 but also the sample water W2 inside the filter cloth 303 moves from the inside to the outside of the filter cloth 303 and is drained from the drain port 312. Accordingly, aquatic organisms that cannot pass through the filter cloth 303 remain in the filter cloth 303.

  At this time, the aquatic organisms adhering to the inner side of the filter cloth 303 are supplied from the rotating nozzle 308 by supplying cleaning water or the like free of aquatic organisms toward the inner peripheral surface of the filter cloth 303. It is preferable to wash it off.

  Further, in addition to or instead of watering from the nozzle 308, a water flow is generated from the water flow generator 315 toward the outer peripheral surface of the filter cloth 303, thereby peeling off aquatic organisms attached to the inside of the filter cloth 303. It is also preferable to drain.

  In addition, although not shown, a fine vibration means for applying a slight vibration to the filter cloth 303 is provided so as to be controllable by the control unit 100, and the filter cloth 303 is slightly vibrated during drainage to promote separation of aquatic organisms. Is also preferable. The fine vibration of the filter cloth 303 by the fine vibration means may be performed when the sample water W2 is supplied to the inside of the filter cloth 303.

  When draining the stored water W1 in the water storage container 300 from the drain port 313 or draining the stored water W1 to a level lower than the storage unit 304, as shown in FIG. Only the concentrated water W <b> 3 including the remaining aquatic organisms is stored in the storage unit 304. Since the concentrated water W3 concentrates aquatic organisms without substantially applying a pressure that is filtered out by the filter cloth 303, the aquatic organisms are concentrated alive without being damaged.

  The concentrated water W <b> 3 in the storage unit 304 is stored in the storage container 307 from the water collection pipe 305 by opening the on-off valve 306 by the control unit 100. The concentrated water W3 can be stored in the storage container 307 by the control unit 100 receiving a detection signal from a water level detection means (water level detection sensor) (not shown) provided in the water storage container 300. In addition, the amount of drainage discharged from the drain valve 314 may be measured, or the elapsed time from the opening of the drain valve 314 may be used as a trigger.

  The aquatic organisms contained in the concentrated water W3 are collected and concentrated alive without damaging the individual organisms. Moreover, since the concentration work only needs to supply a desired amount of ballast water (sample water), the work can be performed easily and in a short time.

  Further, since the water storage amount is adjusted so that the inside of the water storage container 300 has a constant water amount, it can be formed compactly regardless of the amount of the sample water W2 to be supplied, and there is an advantage that it can save space.

  As a means for adjusting the water storage amount in the water storage container 300 to a constant water amount, an overflow drain port is opened on the side wall of the water storage container 300, although not shown, instead of the overflow pipe 312. A structure that directly overflows to the outside may be used.

  Further, as shown in FIG. 10, when two water level detection sensors 316A and 316B are arranged at upper and lower positions at predetermined positions in the water storage container 300 and the upper water level detection sensor 316A detects the water level, the water amount control unit 317 discharges the drain valve. When the lower water level detection sensor 316B does not detect the water level by opening 314 and the lower water level detection sensor 316B does not detect the water level, the water amount control unit 317 controls the drain valve 314 to be closed, and the stored water in the water storage container 300 is discharged. The structure adjusted so that it may become a fixed amount of water may be sufficient. The function of the water amount control unit 317 may be included in the control unit 100 shown in FIG.

  Instead of the configuration in which the reservoir 304 is connected to the lower end opening 303b of the filter cloth 303, a configuration in which the water sampling pipe 305 is directly connected to the lower end opening 303b of the filter cloth 303 may be used. In this case, the inside of the water sampling pipe 305 between the lower end opening 303b of the filter cloth 303 and the on-off valve 306 functions as a storage unit for storing the concentrated water W3.

  Further, the configuration for supplying the stored water W1 to the outside of the filter cloth 303 in the water storage container 300 is replaced with a ballast water by a separate pipe from the water sampling pipe 142 instead of the branch pipe 311 branched from the water sampling pipe 142. Or the structure which supplies other water may be sufficient.

  As shown in FIG. 2, a drain tank 147 is connected to a drain pipe 146 that drains drainage (including overflow water) from the sampling device 143, and the drainage is temporarily stored in the drain tank 147. Is done. The drain tank 147 is provided with a water level detector (not shown). When the inside reaches a predetermined water level, the drain part 148 is continuously controlled by the drain pump 148 driven and controlled by the control unit 100. Returned to ''.

  The drain tank 147 is a so-called buffer tank for temporarily storing the water drained from the sampling device 143 so as to be sent out to the pipe portion 7 ″ by the drain pump 148. Can be configured with a capacity tank. The drain tank 147 is provided with an air vent 147a.

  Next, an example of sampling operation control by the sampling system 14 will be described.

  When draining the ballast water stored in each of the ballast tanks 2A to 2D, the control unit 100 appropriately controls the opening degree of the on-off valve 14a and first opens only the on-off valve 12g of the ballast tank 2A, for example. The operation starts drainage of ballast water from the ballast tank 2A. This ballast water at the time of drainage is ballast water that has already been processed by the processing device 13, and is collected by the sampling nozzle 141 in the process of passing through the pipe portion 7 '' of the pipe 7 toward the drain port 8 '. It flows into the water sampling pipe 142. For collecting the sample water, a pressure generated by driving the ballast pump 4 is used.

  When a predetermined amount of sample water is continuously collected from the sampling nozzle 141, the aquatic organisms are concentrated and collected by the sampling device 143 as described above and stored in the storage container 307.

  Here, the sampling system 14 has a monitor 201 and a printer 202 which are visualization means in the vicinity of the sampling device 143, and is electrically connected to the control unit 100. The monitor 201 is composed of a liquid crystal monitor, for example, and visualizes the information on the ballast tank 2A that is currently draining ballast water from the control unit 100 by displaying it on the screen. The printer 202 prints information on the ballast tank 2A that drains ballast water sent from the control unit 100, prints it on a label sheet 202a, etc., and visualizes it.

  The amount of sample water collected is monitored by the control unit 100 using the flow meter 144. During this time, sample water continuously collected overflows one after another from the water storage container 300 of the sampling device 143 and is stored in the drain tank 147, and then continuously returned to the pipe portion 7 ″ of the pipe 7.

  When a predetermined amount of sample water is collected from the sampling nozzle 141 to the sampling device 143, the sampling valve 145 is closed, while the opening of the on-off valve 14a is returned to the original position, and the collection of the ballast water into the sampling device 143 is completed. To do.

  When a predetermined amount of sample water is collected from the ballast water drained from the ballast tank 2A, the operator checks the monitor 201 or prints information for identifying the ballast tank 2A output from the printer 202. By sticking the labeled sheet 202a to the storage container 307 removed from the sampling device 143, the one-to-one correspondence between the ballast tank 2A and the sample water can be performed.

  Such a one-to-one correspondence between the ballast tank 2A and the sample water may be only one of the monitor 201 and the printer 202. In addition, information directly on the storage container 307 may be provided. A printable printer may be used.

  Thereafter, in the other ballast tanks 2B to 2D as well, sample water is collected from the ballast water sequentially drained in the same manner as described above.

  Here, when the sample water in the storage container 307 is inspected and the ballast water does not satisfy the IMO standard, ozone injection (not shown) is injected into the pipe portion 7 ″ before the drain port 8 ′. A portion is provided, and ozone is injected into the ballast water to remove, sterilize or kill the remaining aquatic organisms, and then drain out of the hull 1. Also, the ballast water to be drained is treated again with the processing device 13. It is also preferable that the processing device 13 performs reprocessing.

  As described above, according to the ship ballast water sampling system according to the present invention, the sample water is continuously collected from the ballast water flowing in the pipe 7 by the sampling nozzle 141, and therefore directly from each ballast tank 2. Sampling of ballast water can be easily performed without taking time and effort.

  In this embodiment, the sampling water is collected by the sampling system 14 when the ballast water is drained. However, the sampling system 14 may collect the sample water when the ballast water is poured. Therefore, in this case, for example, piping of the piping 7 is performed so that the sampling water is collected from the ballast water after being processed by the processing device 13 and before being poured into each ballast tank 2. What is necessary is just to make it provide between the connection parts of the processing apparatus 13 and the main piping 9 in part 7 '.

  For safety, sample water may be collected both when the ballast water is poured and when the water is drained. In this case, a sampling pipe 14 may be arranged so that sample water can be collected from both the ballast water injection line and the drainage line by one sampling system 14, or the ballast water injection line and By separately arranging the sampling systems 14 in both drainage lines, the separate sampling systems 14 may be operated when the ballast water is poured and drained.

The block diagram which shows the outline of the principal part of the ship provided with the sampling system of the ship ballast water based on this invention in planar view The block diagram which shows the detail of the sampling system of the ship ballast water based on this invention Part A enlarged view in FIG. Schematic showing an example of a sampling device Diagram explaining the texture of the filter cloth Diagram explaining operation of sampling device Diagram explaining operation of sampling device Diagram explaining operation of sampling device Diagram explaining operation of sampling device Schematic showing another aspect of means for constantly adjusting the amount of water stored in the water storage container to a constant amount of water

Explanation of symbols

1: Hull 2, 2A-2D: Ballast tank 3: Sea chest 4: Ballast pump 5: Intake pipe 6: Strainer 7: Pipe 8, 8 ': Drain 9: Main pipe 10: Injection / drain nozzle 11: Bypass pipe 12a -12 g: Open / close valve 13: Processing device 13a, 13b, 13c: Open / close valve 14: Sampling system 141: Sampling nozzle 142: Sampling pipe 143: Sampling device 144: Flow meter 145: Open / close valve 146: Return pipe 147: Drain tank 148 : Drain pump 15: removal device 100: control unit 201: display device 202: printer 202 a: label sheet 300: water storage container 301: lid 303: filter cloth 303 A: warp 303 B: weft 303 a: upper end opening 303 b: lower end opening 304: reservoir 305: Tomizukan 306: on-off valve 307: container 308: Bruno Le 308a: supply port 309: liquid level sensor 310: switching valve 311: branch pipe 311a: supply port 312: overflow pipe 312a: upper end opening 313: drain outlet 314: on-off valve 315: water flow generator 316A, 316B: water detection meter 317: Water volume control unit

Claims (8)

A ship ballast water sampling system that samples the ballast water to inspect aquatic organisms contained in the ship ballast water,
It is provided in a water injection line for injecting ballast water into the ballast tank and / or a water discharge line for discharging the ballast water in the ballast tank to the outside of the ship, and a part of the ballast water is continuously supplied from the water injection line and / or the water discharge line. A sampling nozzle to collect,
A sampling device for concentrating aquatic organisms contained in ballast water collected from the sampling nozzle,
The sampling device includes a water storage container that is stored so that the stored water can be adjusted to have a constant amount of water,
A filter cloth having an upper end opening and a lower end opening, immersed in the stored water in the water storage container so that the upper end opening is exposed, and dividing the water storage container into two spaces, an outer side and an inner side;
A supply port for supplying ballast water collected from the sampling nozzle to the inside of the upper end opening of the filter cloth;
From the outside of the filter cloth in the water storage container, a drain outlet for draining the stored water in the water storage container,
It is connected to the lower end opening of the filter cloth in the water storage container, and temporarily stores water containing aquatic organisms remaining inside the filter cloth when the stored water in the water storage container is drained from the drain port. A reservoir,
Possess a container for containing the water containing pooled aquatic organisms to the reservoir,
The supply port is a nozzle provided so as to be rotatable along the inner periphery of the filter cloth when supplying ballast water to the inside of the filter cloth and / or draining the stored water in the water storage container. Ship ballast water sampling system characterized by opening at the tip . A ship ballast water sampling system that samples the ballast water to inspect aquatic organisms contained in the ship ballast water,
It is provided in a water injection line for injecting ballast water into the ballast tank and / or a water discharge line for discharging the ballast water in the ballast tank to the outside of the ship, and a part of the ballast water is continuously supplied from the water injection line and / or the water discharge line. A sampling nozzle to collect,
A sampling device for concentrating aquatic organisms contained in ballast water collected from the sampling nozzle,
The sampling device includes a water storage container that is stored so that the stored water can be adjusted to have a constant amount of water,
A filter cloth having an upper end opening and a lower end opening, immersed in the stored water in the water storage container so that the upper end opening is exposed, and dividing the water storage container into two spaces, an outer side and an inner side;
A supply port for supplying ballast water collected from the sampling nozzle to the inside of the upper end opening of the filter cloth;
From the outside of the filter cloth in the water storage container, a drain outlet for draining the stored water in the water storage container,
It is connected to the lower end opening of the filter cloth in the water storage container, and temporarily stores water containing aquatic organisms remaining inside the filter cloth when the stored water in the water storage container is drained from the drain port. A reservoir,
A storage container for storing water containing aquatic organisms stored in the storage unit;
The sampling device has water flow generating means for generating a water flow from the outside to the inside of the filter cloth and peeling off aquatic organisms attached to the inside of the filter cloth on the outside of the filter cloth in the water storage container. Ship ballast water sampling system, characterized by The supply port is a nozzle provided so as to be rotatable along the inner periphery of the filter cloth when supplying ballast water to the inside of the filter cloth and / or draining the stored water in the water storage container. 3. A ship ballast water sampling system according to claim 2 , wherein the ship ballast water is opened at the tip. A drain tank for temporarily storing the water drained from the water storage container;
The ship ballast water sampling system according to claim 1 , further comprising a drain pump that continuously drains the stored water in the drain tank to the water injection line or the drainage line. A sampling valve for opening and closing the flow path of the ballast water supplied to the sampling device;
A flow meter for measuring the supply amount of ballast water supplied to the sampling device;
The ship ballast water sampling system according to any one of claims 1 to 4, further comprising first control means for controlling opening and closing of the sampling valve based on a measurement result of the flow meter. A drain valve for opening and closing the drain port;
The first control means closes the sampling valve based on the measurement result of the flow meter, then opens the drain valve, and drains the stored water in the water storage container from the drain port. 6. The ship ballast water sampling system according to claim 5, wherein control is performed. A plurality of the ballast tanks are provided,
An on-off valve that opens and closes each of the water injection line and / or the drainage line of each ballast tank;
A visualization means for visualizing information;
The on-off valve is controlled to open and close so as to inject or drain ballast water for each of the plurality of ballast tanks, acquire information on the ballast tank that is injecting or draining water, and ballast water is collected by the sampling nozzle. A second control means for making a one-to-one correspondence between the ballast tank that performs the water injection or drainage and the ballast water collected by the sampling nozzle, and outputs the result to the visualization means. The ship ballast water sampling system according to any one of claims 1 to 6, further comprising:   8. The ship ballast water sampling system according to claim 7, wherein the visualization means is a monitor for displaying information on a screen and / or a printer for printing information.

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