阅读说明：本技术 泵送系统和方法 (Pumping system and method ) 是由 M.希斯塔德 于 2018-03-23 设计创作，主要内容包括：用于将液体或者液体和一种或多种物体(P)的混合物从浸没在水体(W)中的收集器装置(2；2’)移动到接收设施(31)的泵送系统包括第一输送管线(7)、第二输送管线(11)和泵单元(9)。泵单元(9)在水表面(S)下方第一深度(<I>d</I>)处被浸没在水体(W)中并且被布置在收集器(2；2’)和接收设施(31)之间。第一输送管线(7)被流体连接在收集器装置(2；2’)和泵单元入口(18)之间。第二输送管线(11)被流体连接在泵单元出口(17)和接收设施(31)之间。因此泵单元被配置成在第一输送管线(7)中产生吸力并且在第二输送管线(11)中产生正压力。可以通过增加第一深度(<I>d</I>)和/或通过打开可调阀(30)来增加在第一输送管线(7)中的吸力。(A pumping system for moving a liquid or a mixture of a liquid and one or more objects (P) from a collector device (2; 2') submerged in a body of water (W) to a receiving facility (31) comprises a first transfer line (7), a second transfer line (11) and a pump unit (9). The pump unit (9) has a first depth (S) below the water surface (S) d ) Is submerged in the body of water (W) and is arranged in a collector (2; 2') and a receiving facility (31). The first transfer line (7) is fluidly connected between the collector device (2; 2') and the pump unit inlet (18). The second transfer line (11) is fluidly connected between the pump unit outlet (17) and the receiving means (31). The pump unit is thus configured inSuction is generated in the first transfer line (7) and a positive pressure is generated in the second transfer line (11). Can be controlled by increasing the first depth ( d ) And/or increasing the suction in the first transfer line (7) by opening the adjustable valve (30).)

1. A pumping system for moving a liquid or a mixture of a liquid and one or more objects (P) from a collector device (2; 2 ') submerged in a body of water (W) to a receiving facility (31) arranged on a surface vessel or structure (1; 1'), the pumping system comprising a first transfer line (7), a second transfer line (11) and a pump unit (9), characterized in that:

-the pump unit (9) is at a first depth (S) below the surface (S) of the body of water (f)d) Is submerged in the body of water (W) and is arranged in the collector (2; 2') and the receiving facility (31);

-said first transfer line (7) being fluidly connected between said collector device (2; 2') and a pump unit inlet (18); and is

-the second delivery line (11) is fluidly connected between a pump unit outlet (17) and the receiving means (31);

whereby the pump unit is configured to generate a suction force in the first delivery line (7) and a positive pressure in the second delivery line (11).

2. Pumping system according to claim 1, wherein the pump unit (9) comprises a pump (22), the pump (22) being selected from the group consisting of: a centrifugal pump, a positive displacement pump, or any pump that imparts mechanical energy to the liquid.

3. Pumping system according to claim 1 or claim 2, wherein the pump unit (9) comprises a pump motor (22 a) in a sealed housing, the pump motor (22 a) being separate from the pump (22) but connected to the pump via a shaft (22 b).

4. Pumping system according to any one of claims 1-3, wherein said receiving facility (31) is at a height (S) above said surface (S)h) Is arranged in the structure (1; 1') above.

5. Pumping system according to any one of claims 1-4, wherein said collector means (2; 2') are arranged at a second depth (S) below said surface (S)t) To (3).

6. Pumping system according to any of claims 1-5, further comprising a valve (30), said valve (30) being fluidly connected to said first transfer line (7) at an inlet (18) near said pump unit (9) and being operable to allow inflow of ambient seawater into said first transfer line.

7. The pumping system of claim 6, wherein the valve is a check valve (30).

8. A pumping system according to claim 6 or claim 7, wherein the valve is operated manually or automatically, or is arranged to open and close at one or more predetermined pressures.

9. Pumping system according to any of claims 6-8, wherein the valve (30) is an adjustable valve.

10. Pumping system according to any of the claims 1-9, further comprising a flush pump (32), the flush pump (32) being arranged near the receiving facility (31) and being fluidly connected to a seawater inlet pipe (34) and the second delivery line (11), and wherein a shut-off valve (33) is arranged between the flush pump (32) and the second delivery line (11).

11. Pumping system according to any of claims 1-10, wherein the pump unit (9) is supported by a vessel or other load-bearing structure (1; 1') via supporting means (10; 27; 28); the support means are configured for moving the pump unit between a submerged operating position and a non-operating position in which the pump unit is lifted above the surface (S).

12. Pumping system according to any of the claims 1-11, the pump unit (9) further comprising a shaped housing (13) in order to reduce hydrodynamic resistance in the water.

13. Pumping system according to any of the claims 1-12, the pump unit (9) further comprising one or more counterweights (14).

14. Pumping system according to any of claims 1-13, the pump unit (9) further comprising a depth rudder (19), the depth rudder (19) being configured and operable to impart a downward force to the pump unit.

15. Pumping system according to any of the claims 1-14, wherein the receiving facility is a treatment apparatus comprising treatment means (31 a-c) for the liquid and the object (P).

16. Pumping system according to any of claims 1-15, wherein the collector is a trawl (2) configured for being towed by a trawler (1) via a trawl line (3).

17. Pumping system according to any of the claims 1-16, wherein the collector is a collector (2') resting on the seabed (B).

18. Pumping system according to any of the claims 1-17, wherein the liquid is seawater and the object (P) is selected from the group consisting of fish, krill or other biomass, scallops, rocks, iron ore blocks.

19. Use of a pumping system according to any of claims 1-18 as a vacuum pumping system to deliver the liquid or mixture to the receiving facility.

20. A method of operating a pumping system according to claims 1-18,

the method is characterized in that:

a) determining, estimating or sensing a pressure drop in the first transfer line (7); and

b) arranging the pump unit (9) at a depth providing a pump inlet pressure (d) -said pump inlet pressure is sufficient to avoid cavitation in a pump (22) in said pump unit (9).

21. A method of operating a pumping system according to claims 9-18,

the method is characterized in that:

a) determining, estimating or sensing a pressure drop in the first transfer line (7); and

b) operating an adjustable valve (30) to adjust an inlet pressure into the pump (22) to avoid cavitation in said pump (22) in the pump unit (9).

22. A method according to claim 20 or claim 21, wherein the pressure drop in the first transfer line (7) is proportional to the length of the first transfer line (7).

Technical Field

The present invention relates to the field of fluid transport by means of pumping, and in particular to the transport of objects suspended by a liquid. The invention is used for pumping such suspended objects as pellets, rocks, iron ore, food, fish, krill and other aquatic biomass.

Background

Krill is a zooplankton that lives in the ocean and is salvaged for commercial purposes. Because of their small size, krill requires a trawl made of a fine mesh plankton net to catch the krill. Trawl fishing must be performed at low speed due to the high resistance created by the fine mesh net and in order to avoid clogging and damage to the krill and net.

Initially, the krill catch is brought to a trawler by lifting the trawl off the water surface. This results in the krill being squeezed and thus losing a considerable part of its liquid, which is detrimental to the quality of the catch. Later developments in this technology involved pumping krill from the sac end of the net through large hoses and onto a trawler. This method improves the capturing capacity and krill processing rate and improves the quality of the catch as the residence time of the krill inside the trawl is reduced.

Disclosure of Invention

The invention is set forth and characterized in the independent claims, while the dependent claims describe other characteristics of the invention.

There is thus provided a pumping system for moving a liquid or a mixture of a liquid and one or more objects from a collector device submerged in a body of water to a receiving facility arranged on a surface vessel or structure, the pumping system comprising a first transfer line, a second transfer line and a pump unit, characterized in that:

-the pump unit is submerged in the body of water at a first depth below the surface of the body of water and arranged between the collector and the receiving facility;

-the first transfer line is fluidly connected between the collector device and the pump unit inlet; and is

-the second transfer line is fluidly connected between the pump unit outlet and the receiving facility;

whereby the pump unit is configured to generate a suction force in the first transfer line and a positive pressure in the second transfer line.

In one embodiment, the pump unit comprises a pump selected from the group consisting of: a centrifugal pump, a positive displacement pump, or any pump that imparts mechanical energy to the liquid. The pump unit may comprise a pump motor in a sealed housing, separate from but connected to the pump via a shaft.

In one embodiment, the receiving facility is arranged on the structure at a height above the water surface. The collector device is disposed at a second depth below the water surface.

In one embodiment, the pumping system comprises a valve fluidly connected to the first transfer line at an inlet near the pump unit and operable to allow inflow to the ambient seawater in the first transfer line. The valve may be a check valve. The valve may be operated manually or automatically, or set to open and close at one or more predetermined pressures. The valve may be an adjustable valve.

In one embodiment, the pumping system further comprises: a flush pump disposed proximate the receiving facility and fluidly connected to the seawater inlet pipe and the second transfer line; and a shut-off valve arranged between the flush pump and the second delivery line.

In one embodiment, the pump unit is supported by a vessel or other load-bearing structure via a support means; the support means is configured for moving the pump unit between a submerged operating position and a non-operating position in which the pump unit is lifted above the water surface.

The pump unit may comprise a shaped housing in order to reduce hydrodynamic drag in the water. In one embodiment, the pump unit comprises one or more counterweights. The pump unit may also include a depth rudder configured and operable to impart a downward force to the pump unit.

In one embodiment, the receiving facility is a treatment apparatus comprising treatment appliances for liquids and objects. In one embodiment, the collector is a trawl configured for being towed by a trawler via a trawl line. The collector may be a collector resting on the seabed.

The liquid is preferably seawater and the object is selected from the group consisting of fish, krill or other biomass, scallops, rocks, iron ore blocks.

The pumping system of the present invention may therefore be used as a vacuum pumping system to deliver the liquid or mixture to the receiving facility. This is achieved by the following actions: the pump unit is lowered to the necessary depth to obtain sufficient pressure at the pump inlet to avoid pump cavitation when water is drawn (by suction) through the first delivery line (vacuum line). The necessary depth will depend on (i.e. the length of) the first transfer line. For example, if trawling is performed at sea level (water surface), the typical length of the first transfer line is about 150 meters, and the pressure drop through this line will be much less than if trawling is performed at a deeper depth (and thus the first transfer line requires a longer length).

There is also provided a method of operating a pumping system according to the invention, characterized in that:

a) determining, estimating or sensing a pressure drop in the first transfer line; and

b) the pump unit is arranged at a depth providing a pump inlet pressure which is sufficient to avoid cavitation in the pumps in the pump unit.

There is also provided a method of operating a pumping system according to the invention, characterized in that:

a) determining, estimating or sensing a pressure drop in the first transfer line; and

b) the adjustable valve is operated to adjust the inlet pressure into the pump to avoid cavitation in the pump unit.

The pressure drop in the first transfer line may be determined or estimated based on the length, inner diameter, and inner surface characteristics of the first transfer line.

With the invention, in which the pump unit is submerged, it is possible to arrange the pump unit close to the vessel or connected thereto, which results in a number of operational advantages, such as shorter control and power cables, easier maintenance.

The prior art, which relies heavily on the pouring or spraying of additional fluid (e.g. water or air) from the surface of the water and is actually a venturi driven jet pump or air lift pump, requires relatively large diameter transfer lines. In contrast, the present invention uses only the medium being pumped and does not rely on any such externally supplied fluid. The submerged pump unit makes it possible to significantly reduce the transfer line diameter compared to the prior art, for example to 8 to 10 inches (20.3 to 25.4 cm). By lowering the pump unit deeper into the body of water, the first transfer line may tolerate a greater vacuum.

The system of the present invention in which the pump (e.g., a centrifugal pump or a positive displacement pump) is submerged in the body of water is actually a vacuum pump system capable of delivering fluid to a level well above the surface of the water.

With the system of the present invention, the need for long hoses and cables for pumps, and correspondingly large storage drums on fishing trawlers, has been reduced.

Drawings

These and other features of the invention will become apparent from the following description of preferred forms of embodiment, given as a non-limiting example, with reference to the accompanying drawings, in which:

FIG. 1 is a schematic side view of a fishing trawler towing a trawl in a body of water and an embodiment of the pumping system of the present invention;

FIG. 2 is a schematic cross-sectional side view of the embodiment of the pump unit illustrated in FIG. 1;

FIG. 3 is a schematic side view of another embodiment of a pump unit;

figures 4a and 4b are schematic and partly sectional side views of an alternative embodiment of a pump unit for levitation and operation in an operational (extended) and deactivated (retracted) position, respectively;

figures 5a and 5b are schematic and partly sectional side views of a further alternative embodiment of a pump unit for levitation and operation in an operational (extended) and deactivated (retracted) position, respectively;

FIG. 6 is a schematic sketch of an embodiment of the pumping system of the present invention;

FIG. 7 is a schematic diagram of an embodiment of the pumping system illustrated in FIG. 6;

FIG. 8 is a schematic view of an embodiment of the pumping system of the present invention illustrating normal operation;

FIG. 9 is a schematic view of an embodiment of the pumping system of the present invention corresponding to FIG. 8, illustrating a hose cleaning procedure; and

FIG. 10 is a schematic diagram of an embodiment of the pumping system of the present invention corresponding to FIGS. 8 and 9 illustrating a state in which a pump check valve or a remotely controlled pressure relief valve is enabled.

Detailed Description

The following description will use terms such as "horizontal," "vertical," "lateral," "rear and front," "upper and lower," "upper," "lower," "inner," "outer," "forward," "rear," and the like. These terms generally refer to the viewing angles and orientations as shown in the figures and are associated with normal use of the present invention. These terms are used for the convenience of the reader only and should not be limiting.

Fig. 1 illustrates a trawler 1 towing a trawl in a body of water W (e.g. sea) 2 by means of a trawl line 3. The trawl wires are connected to the open trawl end 20 via a connecting member, such as the boom 4 or a net panel. The trawl comprises a net as known in the art, and the flow sensors 5a, 5b are arranged towards the bladder end 21. One or more weights 6 are attached to the open end 20 in a manner known in the art. Reference P designates the biomass to be captured by the trawl, such as fish or krill.

The pump unit 9 is arranged at a distance below the water surface S immediately behind the trawler 1dTo (3). In the illustrated embodiment, the pump unit 9 is connected to the trawler 1 via a haul line 10 and towed behind it. The umbilical 12 (including hydraulic lines and other required power, control and signal lines) is connected as required between the power, control, support and utility systems (not shown) on the trawler and the pump unit. Extending between the pocket end (i.e. the narrow rear end) 21 of the trawl and the pump unit 9 is a first delivery hose 7. Reference numeral 8 indicates means (stitching or the like) by which the first delivery hose can be connected to or partially embedded in the trawl 2. Extending between the pump unit 9 and the trawler 1 is a second transfer hose 11. On the trawler, the second transfer hose 11 may terminate in a cargo hold or a processing facility (not shown in fig. 1).

Turning now to fig. 2, the pump unit 9 comprises a housing 13, which housing 13 is, in the illustrated embodiment, light bulb-shaped so as to reduce hydrodynamic resistance as the pump unit is pulled through water.

Inside the housing 13 is a centrifugal pump 22, which centrifugal pump 22 comprises an impeller 23, which impeller 23 is driven by an internal motor (not shown in fig. 2), preferably hydraulically driven and controlled via an umbilical 12 (see fig. 1; not shown in fig. 2). It should be understood that the motor may also be an electric motor. Because impeller and motor configurations are well known in the art, they need not be described in detail herein. It should be understood that the pump may also be a positive displacement pump.

In use, the pump 22 generates a partial vacuum and therefore a suction in the first delivery hose 7 and an overpressure (discharge pressure) in the second delivery hose 11. Thus, the first delivery hose 7 is connected to the suction end (inlet) 18 of the pump unit and the second delivery hose 11 is connected to the discharge end (outlet) 17 of the pump unit. The pump also comprises a check valve 30, which check valve 30 is fluidly connected to the suction side of the impeller, i.e. in fluid communication with the first delivery hose 7 and the pump inlet 18.

FIG. 2 illustrates a fluid inflow Q_iHow to bring the krill P through the first transfer hose 7 into the pump, and a fluid outflow Q_oHow to flow out of the pump through the second transfer hose 11 for transferring the krill P to a trawler (see fig. 1; not shown in fig. 2).

It will be appreciated that the first delivery hose 7 must be able to withstand suction without collapsing, and that a helical reinforcing cord or the like may be provided for this purpose. The second transfer hose 11 need not have such a capability, since it is only subjected to positive pressure, but can nevertheless be designed to withstand large positive pressures and external forces, such as wave action in splash zones and wear caused by the vessel hull. As a non-limiting example, the first delivery hose 7 may be a vacuum hose having a length of 600 meters and having an internal diameter of 8 to 10 inches (20.3 to 25.4 cm) and capable of withstanding a vacuum (i.e., negative pressure) of 3 bar. The second delivery hose 11 may be a pressure hose having a length of approximately 60 meters and having an internal diameter of 8 to 10 inches (20.3 to 25.4 cm).

In practice, the horizontal distance between the trawler and the open end 20 of the trawl may typically be between approximately 100 and 600 meters. Also, for example, when fishing krill with a trawl, the trawl depthtMay be typically zero (sea level) to 300 meters below the water surface S and the distance below the water surfaced(the pump unit 9 is arranged at this distancedAt) may be 10 to 30 meters. Typical elevation height above water surfaceh(see fig. 1) may be 5 to 10 meters. The invention will not be limited to these values, but by arranging the pump unit in the sea near the trawler or at least at a distance in front of the trawl, the first transfer hose can be accommodated therein compared to prior art systemsAllowing for greater pressure drop. This is because the pump unit must be lowered to the necessary depth in order to avoid cavitation in the pump. Also, the check valve 30 may be controlled (e.g., remotely) to avoid cavitation. It should therefore be understood that the check valve 30 may be operated by or replaced by a pressure relief valve. Operating the check valve (pressure reducing valve) results in less flow in the first delivery hose 7, i.e. the vacuum hose, as a controlled flow of water is allowed through the valve.

As mentioned above, the pump unit housing 13 is shaped to minimize hydrodynamic drag. Furthermore, in order to move the pump unit 9 in the water in a stable and predictable manner, the housing is fitted with stabilizing wings, in the illustrated embodiment a ventral wing 15 and a dorsal wing 16. It will be appreciated that other wing configurations may be advantageous. To further enhance the hydrodynamic properties of the pump unit 9, one or more balancing weights 14 may be attached to the pump housing. Although fig. 2 shows only one weight, it should be understood that the weight may be added to the pump unit in many ways. In a non-limiting example, the weight 14 may generate a downward force F of 3 metric tons_w. Pulling force F in the haul-off line 10_pIs 5.8 metric tons, the drag D produced by the trawl and the first delivery hose₁Is 4 metric tons and the resistance D generated by the second delivery hose₂Is 1 metric ton.

Since it may be desirable to lower the weight of the pump unit, it may be desirable to remove the clump weight 14 or reduce its mass, for example when lifting the pump unit into and out of the sea. This may be achieved with the embodiment illustrated in fig. 3. Here, the depth rudder 19 is fitted to the pump unit. The depth rudder may be powered via hydraulic or electric power in a manner known per se in the art, for example via the above mentioned umbilical. The depth rudder may be operated to generate a downward force that reduces or removes reliance on the counterweight.

Although the pump unit 9 has been described above as being towed by a haul line, the invention is not limited to such a connection means, as it will be appreciated that the pump unit may be connected to the trawler in many ways. For example, the pump unit may be connected to an outboard bracket on a trawler, or to a telescopeAn arm or other structure that allows the pump unit to be lowered below the surface of the water. It is also conceivable that the pump unit 9 may be arranged in a tank (not shown) or moon pool inside the trawler, and that the tank is open to the surrounding sea. The pump unit will be arranged in a tank or moon pool and lowered to a depth below the water surface SdIn order to achieve the necessary pressure at the pump inlet 18 to avoid cavitation when the mixture of water and biomass is transported through the first transfer hose 7 (vacuum hose) and the trawl outlet.

One such alternative connection means is shown in fig. 4a and 4 b. Here, the pump unit 9 is connected to a carrying arm 27, which is pivotably supported by an axle or other pivoting member 25. A hoisting line 28 extends between the pump unit (or the lower part of the carrying arm) and the overhead winch 24. A second delivery hose 11 (positive pressure) and an umbilical 12 are arranged along the carrying arm, reference numeral 26 indicating a second delivery hose opening. Thus, by operating the winch 24, the pump unit can be operated between an extended position (fig. 4a, operating state) and a retracted position (fig. 4b, deactivated state) below the trawler.

Fig. 5a and 5b show another such alternative connection means. Here, the pump unit 9 is connected to a lifting line 28 which passes through a guide structure 29. The winch 24 is arranged at the top of the guiding structure 29 and the lower part of the guiding structure is led to the sea through the trawler hull. A second delivery hose 11 (positive pressure) and an umbilical 12 are arranged along the guiding structure. Thus, by operating the winch 24, the pump unit can be operated between an extended position (fig. 5a, an operating state) and a retracted position (fig. 5b, a deactivated state) below the trawler.

FIG. 6 is a schematic illustration of some portions of the system illustrated in FIG. 1 (certain features, such as drag means, have been omitted). The trawl 2 is shown suspended in the body of water W above the seabed B. However, it will be appreciated that the invention is equally applicable to situations and configurations where the trawl is moving through the water, resting in the water, moving along the seabed B or resting on the seabed B. This is indicated in fig. 6 by reference numeral 2' and the dashed line illustrating the seafloor collector. Furthermore, although the above description refers to a trawl 2 for fish or other biomass P, it should be understood that the trawl may be replaced by any suitable collector designed to collect any objects suspended in water and for feeding a mixture of water and such objects into the first conveying hose 7. Thus, the trawl 2 will in some cases be referred to hereinafter in a simplified manner as a "collector" 2. In addition to fish, krill and other biomass, the objects P may be rocks, gravel, iron ore, scallops, etc., and the skilled person will understand that the collector 2 will have to be designed for its specific intended catch. For example, if the intended catch is an object resting on the seabed, the collector may be provided with means (e.g. a mechanical shovel) configured to throw the object up from the seabed immediately in front of the first transfer hose inlet.

Thus, the above-mentioned trawler 1 can be virtually any vessel, vessel or structure above the water surface, and the treatment device 31 is designed to treat the applicable catch (mixture of object P and water). Fig. 6 thus illustrates a collector 2, which collector 2 is arranged in a body of water (or 2' on the seabed) and is fluidly connected to a submerged pump unit 9 by means of a first transfer hose 7, and the pump unit 9 is fluidly connected to a treatment apparatus 31 on the vessel 1 by means of a second transfer hose 11.

Although in practical application the mixture of objects P and water is transported from the collector 2 to the treatment device 31 by means of flexible hoses 7, 11, the invention shall not be limited to such pipes. In general, any known fluid conduit may be used. The first and second hoses will therefore also be referred to as first and second transfer lines 7, 11 in the following.

Fig. 7 is essentially a schematic diagram of the pumping system illustrated in fig. 6. Reference numeral 1' denotes a deck (e.g. of a ship) or platform, which is at a distance above the water surface ShTo (3). The pump unit 9 comprises a pump 22 driven by a motor 22a via a shaft 22 b. The motor 22a may be an electric motor, a hydraulic motor, or any other suitable motor known in the art. The motor 22a is arranged inside its own casing, sealed with respect to the pump 22 and therefore with respect to the pumpingThe medium is sealed. The only connection between the pump motor 22a and the pump 22 is via a shaft 22b, which shaft 22b also extends through a seal (not shown). This separation of motor and pump is particularly advantageous in embodiments where the motor utilizes hydraulic fluid (oil): the leakage will not harm the pumped medium (fish and water). The pump motor 22a may be connected to the shaft 22b via a splined connection, whereby the motor may be removed or replaced without having to disconnect the pump 22 from the delivery line.

Vertical distance (depth) of pump unit 9 below water surfacedIs arranged in the water and the collector 2 (or 2') is arranged at a vertical distance below the water surfacetTo (3). Although not illustrated in fig. 6 and 7, the horizontal distance between the collector 2 and the deck 1' may be about 600 meters.

The pump 22, which may be a centrifugal pump or a positive displacement pump, generates a partial vacuum and thus a suction in the first delivery line 7 and an overpressure (discharge pressure) in the second delivery line 11. As mentioned above with reference to fig. 2, the first transfer line (transfer hose) 7 must be able to withstand suction without collapsing and may be equipped for this purpose with a helical reinforcing rope or the like. The second transfer line (transfer hose) 11 need not have such a capability since it is only subjected to a positive pressure.

As a practical and non-limiting example, if the length of the first transfer line 7 can be 600 meters, the diameter of this line (suction hose) is 8 inches (20.3 cm), and the flow rate is 400 metric tons/hour, a pressure drop of approximately 1.8 bar is generated in the first transfer line 7 (i.e. from the collector 2 to the pump 22). If the pump unit 9 (and pump 22) is arranged at depthdAt = 30 meters (i.e. at 4 bar pressure), the pump will have a pressure margin of 2.2 bar before cavitation occurs in the pump. If the deck 1' is arranged approximately above the water surfaceh At a height of = 6 meters, approximately 0.6 bar is required to lift the contents of the transfer line (water and objects P) from the water and onto the deck. Thus, there is still sufficient margin before cavitation occurs (in contrast, if the submerged pump is replaced by an on-deck vacuum pump as known in the art, the required vacuum will be 2.4 barThis will result in cavitation).

Based on the foregoing, it will be appreciated that in lowering the pump to even deeper depths (d) The margin with respect to pump cavitation will increase. Furthermore, if the length of the first transfer line 7 is short (e.g. 150 meters), the pressure drop in the first transfer line 7 is proportionally reduced (to e.g. 0.45 bar) and the depthdThe requirements are correspondingly reduced. Such a shorter transfer line is suitable for use when trawling fish in shallow depths.

It will therefore be appreciated that submerging the pump into the body as described above actually creates a vacuum pumping system that is capable of delivering fluid to a level well above the surface of the water.

The basic principle of the invention is to lower the pump unit 9 to a depth sufficient to avoid cavitationd. Thus, the required depth may be determined based on the pressure drop in the first transfer line 7 (including the collector 2)d。

Referring now to fig. 8, an inlet valve 37 and a gate valve 36 are arranged in the second delivery line 11, and the delivery line is continuously connected to the water isolator 31a, the storage tank 31b and the treatment facility 31 c. The skilled person will appreciate that these components may be designed, configured and dimensioned for the applicable catch, i.e. the nature of the object P, and that the processing device 31 may in fact be any receiving facility. The water discharge pipe 35 is configured to return water to the sea. The flush pump 32 is configured to feed water via a pipe 34 into the second line 11 between an inlet valve 37 and a gate valve 36, and a shut-off valve 33 is arranged between the flush pump 32 and the second line 11. The flush pump 32 is typically arranged on the vessel and is configured to deliver a flow of between 500 and 1000 tonnes/hour at a pressure of approximately 3 bar.

The check valve 30 is fluidly connected to the first line 7 and thus on the inlet side of the pump 22 and is arranged in the pump unit 9. The check valve 30 is preset or operated to prevent collapse of the first line 7 and will itself act as a safety valve for the system. A typical opening pressure for the non-return valve is 2 bar, but this pressure can be set according to applicable requirements. In addition to performing the safety valve function, the check valve may be operated (manually or automatically, e.g., based on sensor input) to control the mixture of seawater and fish passing through the pump, and thus, in effect, function as a mixing valve. If increased water flow is required, the valve may be fully or partially opened for a desired period of time.

Fig. 8 shows the situation where the system is operating, i.e. a mixture of water and objects P is fed from the collector 2 to the treatment device 31. The shut-off valve 33 is closed and the flush pump 32 is shut off. The inlet valve 37 and gate valve 36 are opened. The pump 22 is operating and the check valve 30 is closed so that no seawater passes through the valve 30. In this state, the system operates within acceptable tolerances for avoiding cavitation. The valve 30 may be designed to open or close at a predetermined pressure, or may be remotely operated.

During operation (e.g. trawl fishing), the first transfer line 7 or the trawl outlet may be blocked by a build-up of objects P or by debris or other unwanted objects. The system of the present invention makes it possible to solve this problem without having to take the pump and the lines out of the water. Fig. 9 illustrates such a cleaning procedure to remove obstacles from the transfer line. In this configuration, the submerged pump 22 is not operating and the gate valve 36 is closed. The inlet valve 37 and shut-off valve 32 are opened and the flush pump 32 is operated. Thus, seawater is pumped by the flush pump 32 through the pipe 34, down into the second line 11, through the deactivated pump 22 and into the first transfer line 7, thereby flushing the first transfer line and the trawl outlet back into the trawl.

Fig. 10 illustrates the safety features inherent in the check valve 30. The shut-off valve 33 is closed and the flush pump 32 is shut off, and the inlet valve 37 and gate valve 36 are opened, as is the case during normal operation. In case a blockage occurs in the first line 7 or at the inlet in the collector 2, resulting in a vacuum in the first line exceeding the opening pressure of the check valve 30, the check valve will open. In actual use, the sensor and control system (not shown) will shut off the submerged pump 22. The obstruction may then be removed by the procedure described above with reference to fig. 9.

Although the system of the invention has been described above in which the pump unit 9 is connected to the trawler (via a line, carrying arm or the like), the invention is not intended to be limited to such physical connections. It will be appreciated that the invention is equally applicable to systems in which the pump unit is arranged in front of the trawl (collector), i.e. in a direction towards the fishing trawler, and the second transfer line is connected between the pump unit and the collector.

Although the invention has been described with reference to a centrifugal pump, it should be understood that the invention is equally applicable to centrifugal pumps and positive displacement pumps and other pumps that impart mechanical energy to the pumped seawater.