Patent Description:
Krill are a type of zooplankton that live in the oceans and which are being harvested for commercial purposes. Because of their small size, krill need to be caught with trawls made of fine-meshed plankton nets. Trawling must be performed at low speeds due to high drag forces produced by the fine-meshed nets and in order to avoid clogging and damage to the krill and net.

Originally, the krill catch was brought on board the trawler by hoisting the trawl out of the water. This caused the krill to be compressed and thus losing a considerable part of the its liquids, which was detrimental to the quality of the catch. Later developments in the technology included pumping the krill from the cod end of the net, through a large hose and onto the trawler. This method increases the capture capacity and the krill processing rate, and improves the quality of the catch as the krill residence time inside the trawl net is reduced.

The prior art also includes <CIT>, which describes a system having a hose between the end of a trawl net and a pumping station. A pressure duct extends between the pumping station and a surface vessel. The pumping station is used for adjusting the vertical position of the trawl in the body of water, by operating ballasting chambers and via trawl boards suspended in the pumping station via cables. The pumping station is arranged next to the trawl opening.

The prior art also includes <CIT>, which describes a trawling method and device by means of which the catch is transferred continuously from the trawl net to the trawling vessel during the trawling process. An open fish pump is disposed on the open end of the trawl net, the pump being directed toward the trawl net at the suction side, and the pressure side of which is connected to a delivery hose. The pump is operated by hydraulic oil or other hydraulic fluid supplied under pressure from the surface, or by an electric motor. The caught product guided toward the end of the trawl net during the trawling process is continuously pumped into the delivery hose as a caught product/water mixture during the trawling process, and transported on board the trawling vessel.

The prior art also includes <CIT>, which describes a trawl equipped with an elongate, preferably rigid or flexible collecting cage which at an inlet opening is connected to the rear end of the trawl, and from the inlet opening extends into a second portion, defined by walls, roof and bottom which have openings for straining water, and is terminated in a downstream portion. A conveying hose or pipe for conveying biomass from the collecting cage up to a surface vessel opens into the downstream or aft portion of the cage via a funnel. Air or other fluid is supplied from the vessel via a supply hose for injection into the conveying hose or pipe in order, by injector effect, or air lift pump effect (in which the fluid is lifted when the injected air is expanding in the hose, to cause suction of the biomass from the collecting cage to the vessel.

The prior art also includes <CIT>, which describes a pump assembly for the conveying of a fish-water mixture, comprising an entrance and an exit, a jet pipe arranged between said entrance and exit, a passage system leading from a first position between the downstream end of the jet pipe and said exit to a propellant water ring nozzle at a second position between the upstream end of the jet-pipe and said entrance, and a pump rotor in said passage system for pumping water around said system and forcing it through said propellant water ring nozzle.

The prior art also includes <CIT>, which describes an apparatus for emptying a trawl net during trawling operations. The apparatus comprises a high-pressure water pump which draws water in through an opening and supplies water under pressure through an outlet to propel fish and water through an ejector and transport tube back to a collection point on board a trawler. An hydraulic motor may be used for the operation of the pump. <CIT> discloses a pumping system for moving sediment from a dredging machine submerged in sea to a storage tank arranged on a boat, wherein said dredging machine is configured for being towed by the boat.

One disadvantage with the prior art is the need for large-diameter tubes and hoses for transferring the fish or biomass between the trawl and the surface vessel. Another disadvantage is the need for very long hoses, control and power lines and correspondingly large storage drums on the trawler, in view of the fact that the distance between the trawler and the trawl may be <NUM> to <NUM> meters or more.

The invention provides certain improvements over the prior art.

The invention is disclosed in the independent claims, while dependent claims disclose preferred embodiments of the invention. It 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 , comprising a first delivery line, a second delivery line and a pump unit, characterized by.

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

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

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

According to the invention, the pumping system comprises a valve fluidly connected to the first delivery line at an inlet in the vicinity of the pump unit and operable to allow an inflow of ambient seawater into the first delivery line. The valve may be a check valve. The valve may be manually or automatically operated, 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 flushing pump arranged in the vicinity of the receiving facility and being fluidly connected to a seawater inlet pipe and the second delivery line, and a shut-off valve being arranged between the flushing pump and the second delivery line.

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

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

In one embodiment, the receiving facility is a processing plant comprising processing means for the liquid and objects. In one embodiment, the collector is a trawl configured for being towed by a trawler via a trawl wire. The collector may be a collector at rest on a seabed.

The liquid is preferably seawater and the objects are selected from the group consisting of fish, krill or other biomass, scallop, rock, pieces of iron ore.

The invented pumping system may thus be used as a vacuum pump system to deliver said liquid or mixture to said receiving facility. This is achieved by lowering the pump unit to a necessary depth to obtain sufficient pressure at the pump inlet in order to avoid pump cavitation when drawing (by suction) water through the first delivery line (vacuum line). The necessary depth will depend on (i. ) the length of the first delivery line. For example, it trawling is performed at the sea level (surface), a typical length for the first delivery line is on the order of <NUM> meters, and the pressure drop through this line will be much less than if the trawling is performed at greater depths (and thus requiring greater length for the first delivery line).

It is also provided a method of operating the pumping system according to the invention, characterized by.

It is also provided a method operating the pumping system according to the invention, characterized by.

The pressure drop in the first delivery line may be determined or estimated based on the length, internal diameter and internal surface properties of the first delivery 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 to it, which result in several operational advantages, such as shorter control cables and power cables, easier maintenance.

The prior art, which to a large extent relies on the infusion or injection of an additional fluid (e.g. water or air) from the surface, and in effect are venturi-driven injector pumps or air-lift pumps, require comparably large-diameter delivery lines. By contrast, the invention only uses the medium which is being pumped and is not dependent on any such externally-supplied fluids. The submerged pump unit makes it possible to reduce the delivery line diameter considerably compared to the prior art, to e.g. <NUM> to <NUM> inches (<NUM> to <NUM>). By lowering the pump unit deeper into the body of water, the first delivery line may tolerate a greater vacuum.

The invented system, in which the pump (e.g. a centrifugal pump or a positive displacement pump) is submerged into the body of water, is in effect a vacuum pump system which is capable of delivering fluids to levels well above the water surface.

With the invented system, the need for long hoses and cables for the pump, and correspondingly large storage drums on the trawler, has been mitigated.

These and other characteristics of the invention will become clear from the following description of a preferential form of embodiment, given as a non-restrictive example, with reference to the attached drawings, wherein:.

The following description will use terms such as "horizontal", "vertical", "lateral", "back and forth", "up and down", "upper", "lower", "inner", "outer", "forward", "rear", etc. These terms generally refer to the views and orientations as shown in the drawings and that are associated with a normal use of the invention. The terms are used for the reader's convenience only and shall not be limiting.

<FIG> illustrates a trawler <NUM> towing a trawl <NUM> in a body of water W (e.g. the sea) by means of a trawl wire <NUM>. The trawl wire is connected to the open trawl end <NUM> via a connection member, such as a boom <NUM> or otter board. The trawl comprises a net as known in the art, and flow sensors 5a, 5b are arranged towards the cod end <NUM>. One or more weights <NUM> are connected to the open end <NUM>, in a manner well known in the art. The reference letter P designates the biomass which is to be caught by the trawl, the biomass being for example fish or krill.

Arranged immediately behind the trawler <NUM> and a distance d below the water surface S, a pump unit <NUM> is arranged. In the illustrated embodiment, the pump unit <NUM> is connected to, and towed behind, the trawler <NUM> via a towing wire <NUM>. An umbilical <NUM>, comprising hydraulic lines and other required power, control and signaling lines, as required, is connected between power, control, support and utility systems (not shown) on the trawler and the pump unit. Extending between the cod end (i.e. rear, narrow, end) <NUM> of the trawl and the pump unit <NUM> is a first delivery hose <NUM>. Reference number <NUM> indicate means (stitching, etc.) by which the first delivery hose may be connected into, or partly embedded into, the trawl <NUM>. Extending between the pump unit <NUM> and the trawler <NUM> is a second delivery hose <NUM>. On the trawler, the second delivery hose <NUM> may terminate into a cargo hold or a processing facility (not shown in <FIG>).

Turning now to <FIG>, the pump unit <NUM> comprises a housing <NUM> which in the illustrated embodiment is bulb-shaped in order to lower the hydrodynamic drag when the pump unit is pulled through the water.

Inside the housing <NUM> is a centrifugal pump <NUM> which comprises an impeller <NUM> driven by an internal motor (not shown in <FIG>), preferably hydraulically driven and controlled via the umbilical <NUM> (see <FIG>; not shown in <FIG>). It should be understood that the motor may also be an electric motor. As impeller-and-motor configurations are well known in the art, they need not be described in detail here. It should be understood that the pump may also be a positive displacement pump.

In use, the pump <NUM> generates a partial vacuum, and hence suction, in the first delivery hose <NUM>, and an overpressure (discharge pressure) in the second delivery hose <NUM>. Thus, the first delivery hose <NUM> is connected to a suction end (inlet) <NUM> of the pump unit, and the second delivery hose <NUM> is connected to a discharge end (outlet) <NUM> of the pump unit. The pump also comprises a check valve <NUM>, fluidly connected to the suction side of the impeller, i.e. in fluid communication with the first delivery hose <NUM> and the pump inlet <NUM>.

<FIG> illustrates how a fluid inflow Qi flows into the pump through the first delivery hose <NUM>, carrying with it krill P, and how a fluid outflow Qo flows out of the pump through the second delivery hose <NUM>, delivering the krill P to the trawler (see <FIG>; not shown in <FIG>).

It should be understood that the first delivery hose <NUM> must be able to withstand suction without collapsing, and may to that end be furnished with spiral reinforcement strings, or similar. The second delivery hose <NUM> does however not need to have such capabilities, as it is being subjected to only positive pressures, but may be designed to withstand high positive pressures and external forces, such as wave action in the splash zone and abrasion caused by the vessel hull. As a non-limiting example, the first delivery hose <NUM> may be a vacuum hose of <NUM> metres length and an internal diameter of <NUM> to <NUM> inches (<NUM> to <NUM>) and capable of withstanding a vacuum of <NUM> bar (i.e. negative pressure). The second delivery hose <NUM> may be a pressure hose of approximately <NUM> metres length and an internal diameter of <NUM> to <NUM> inches (<NUM> to <NUM>).

In a practical application, the horizontal distance between the trawler and the open end <NUM> of the trawl may typically be between approximately <NUM> and <NUM> meters. Also, for example when trawling for krill, the trawl depth t may typically from zero (sea level) to <NUM> meters below the water surface S, and the distance d below the water surface at which the pump unit <NUM> is arranged may be <NUM> to <NUM> meters. Typical lifting height h above the water surface (see <FIG>) may be <NUM> to <NUM> meters. The invention shall not be limited to these numerical values, but by arranging the pump unit in the sea near the trawler or at least a distance in front of the trawl, a greater pressure drop in the first delivery hose can be tolerated, compared to the prior art systems. This is because the pump unit must be lowered to the necessary depth in order to avoid cavitation in the pump. The check valve <NUM> is be controlled (e.g. remotely) in order to avoid cavitation. It should therefore be understood that the check <NUM> valve may be operated by or be replaced by a relief valve. Operating the check valve (relief valve) causes less flow in the first delivery hose <NUM> (i.e. the vacuum hose) because a controlled water flow is allowed through the valve.

As mentioned above, the pump unit housing <NUM> is shaped so as to minimize hydrodynamic drag. In addition, in order for the pump unit <NUM> to move in a steady and predictable manner in the water, the housing is fitted with stabilizer fins, in the illustrated embodiment a ventral fin <NUM> and a dorsal fin <NUM>. It will be appreciated that other fin configurations may be advantageous. In order to further augment the hydrodynamic properties of the pump unit <NUM>, one or more clump weights <NUM> may be attached to the pump housing. Although <FIG> shows only one clump weight, it should be understood that weight may be added to the pump unit in a number of ways. In a non-limiting example, the clump weight <NUM> may generate a downward force Fw of <NUM> tonnes. The pulling force Fp in the towing wire <NUM> is <NUM> tonnes, the drag D<NUM> produced by the trawl and first deliver hose is <NUM> tonnes and the drag D<NUM> produced by the second delivery hose is <NUM> tonne.

As it may be desirable to lower the weight of the pump unit, for example when lifting the pump unit in and out of the sea, it may be desirable to remove the clump weight <NUM> or lower its mass. This may be achieved with the embodiment illustrated in <FIG>. Here, a depth rudder <NUM> is fitted to the pump unit. The depth rudder may be powered via hydraulics or electricity, for example via the umbilical mentioned above, in a manner which per se is well known in the art. The depth rudder may be operated to generate a downward force that reduces or removes the dependence on the clump weight.

Although the pump unit <NUM> has been described above as being towed by a towing wire, the invention shall not be limited to this connection means, as it should be understood that the pump unit may be connected to the trawler in a number of ways. For example, the pump unit may connected to outriggers on the trawler, or to telescopic arms or other structures that allow the pump unit to be lowered below the water surface. It is also conceivable that the pump unit <NUM> may be arranged in a tank or (not shown) or moon pool inside the trawler, and the tank is open to the surrounding sea. The pump unit would be arranged in the tank or moon pool and be lowered to a depth d below the water surface S, in order to achieve the necessary pressure at the pump inlet <NUM> to avoid cavitation when the mixture of water and biomass is transported through the first delivery hose <NUM> (vacuum hose) and the trawl outlet.

<FIG> show one such alternative connection means. Here, the pump unit <NUM> is connected to a carrier arm <NUM> which is pivotally supported by an axle or other pivot member <NUM>. A lifting wire <NUM> extends between the pump unit (or a lower portion of the carrier arm) and an overhead winch <NUM>. The second delivery hose <NUM> (positive pressure) and umbilical <NUM> are arranged along the carrier arm, reference number <NUM> indicates the second delivery hose opening. Thus, by operating the winch <NUM>, the pump unit may be operated between an extended position (<FIG>, operating state) below the trawler, and a retracted position (<FIG>, inactive state).

<FIG> show another such alternative connection means. Here, the pump unit <NUM> is connected to a lifting wire <NUM> which runs through a guide structure <NUM>. Arranged at the top of the guide structure <NUM> is a winch <NUM>, and the lower part of the guide structure is open towards the sea, through the trawler hull. The second delivery hose <NUM> (positive pressure) and umbilical <NUM> are arranged along the guide structure. Thus, by operating the winch <NUM>, the pump unit may be operated between an extended position (<FIG>, operating state) below the trawler and a retracted position (<FIG>, inactive state).

<FIG> is a schematic illustration of certain parts of the system illustrated in <FIG> (certain features, e.g. towing means, have been omitted). The trawl <NUM> is shown as being suspended in the body of water W, above the seabed B. However, it should be understood that the invention is equally applicable to situations and configurations in which the trawl is moving in the water, at rest in the water, moving along a seabed B, or being stationary on a seabed B. This is indicated in <FIG> by reference number <NUM>' and the dotted lines illustrating a seabed collector. Also, while the description above refers to a trawl <NUM> for fish or other biomass P, it should be understood that the trawl may be replaced by any suitable collector designed for collecting any objects suspended in water, and for feeding a mixture of water and such objects into the first delivery hose <NUM>. Therefore, the trawl <NUM> will in some instances in the following simply be referred to as a "collector" <NUM>. In addition to fish, krill and other biomass, objects P may be rocks, gravel, iron ore, scallop, etc., and the skilled person will understand that the collector <NUM> will have to be designed for its specific intended catch. For example, if the intended catch are objects resting on the seabed, the collector may be furnished with a device (e.g. a mechanical shovel) configured to throw the objects up from the seabed immediately in front of the first delivery hose inlet.

Consequently, the above mentioned trawler <NUM> may in fact be any boat, vessel or structure above the water surface, and the processing plant <NUM> is designed for processing the applicable catch (mixture of objects P and water). <FIG> therefore illustrates a collector <NUM> arranged in a body of water (or <NUM>' on the seabed), fluidly connected by means of a first delivery hose <NUM> to a submerged pump unit <NUM>, and the pump unit <NUM> being fluidly connected by means of a second delivery hose <NUM> to a processing plant <NUM> on a vessel <NUM>.

While in a practical application, the mixture of objects P and water is transported from the collector <NUM> to the processing plant <NUM> by means of flexible hoses <NUM>, <NUM>, the invention shall not be limited to such conduits. In general, any known fluid conduit may be used. Therefore, the first and second hoses will in the following also be referred to as first and second delivery lines <NUM>, <NUM>.

<FIG> is essentially a schematic diagram of the pumping system illustrated in <FIG>. Reference number <NUM>'denotes a deck (of e.g. a vessel) or platform a distance h above the water surface S. The pump unit <NUM> comprises a pump <NUM> driven by a motor 22a via a shaft 22b. 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 housing, sealed from the pump <NUM> and hence the pumped medium. The only connection between the pump motor 22a and the pump <NUM> is via the shaft 22b, which is also extending through seals (not shown). This separation of motor and pump is particularly advantageous in an embodiment in which the motor is utilizing hydraulic fluids (oils): a leakage will not compromise the pumped medium (fish and water). The pump motor 22a may be connected to the shaft 22b via a spline connection, whereby the motor may be removed or exchanged without having to disconnect the pump <NUM> from the delivery lines.

The pump unit <NUM> is arranged in the water at a vertical distance (depth) d below the water surface, and the collector <NUM> (or <NUM>') is arranged at a vertical distance t below the water surface. Although not illustrated in <FIG>, the horizontal distance between the collector <NUM> and the deck <NUM>' may be on the order of <NUM> metres.

The pump <NUM>, which may be a centrifugal pump or a positive displacement pump, generates a partial vacuum, and hence suction, in the first delivery line <NUM>, and an overpressure (discharge pressure) in the second delivery line <NUM>. As mentioned above with reference to <FIG>, the first delivery line (delivery hose) <NUM> must be able to withstand suction without collapsing, and may to that end be furnished with spiral reinforcement strings, or similar. The second delivery line (delivery hose) <NUM> does however not need to have such capabilities, as it is being subjected to only positive pressures.

As a practical and non-limiting example, if the length of the first delivery line <NUM> may be <NUM> metres, the diameter of this line (suction hose) is <NUM> inches (<NUM>), and the flow rate is <NUM> tonnes/hour, a pressure drop of approximately <NUM> bar is generated in the first delivery line <NUM> (i.e. from the collector <NUM> to the pump <NUM>). If the pump unit <NUM> (and pump <NUM>) is arranged at depth d = <NUM> metres (i.e. at <NUM> bar pressure), the pump will have a pressure margin of <NUM> bar before cavitation occurs in the pump. If the deck <NUM>' is arranged a height above the water surface of approximately h = <NUM> metres, approximately <NUM> bar is required to lift the contents of the delivery lines (water and objects P) from the water and onto the deck. Hence, there is still ample margin before cavitation occurs (By contrast, should the submerged pump be replaced that a vacuum pump on deck, which is known in the prior art, the required vacuum would be <NUM> bar, which would result in cavitation).

Based on the above, it will be understood that lowering the pump to even further depths (d), the margin with respect to pump cavitation will increase. Also, if the length of the first delivery line <NUM> is shorter (say <NUM> meters), the pressure drop in the first delivery line <NUM> is reduced proportionally (to say <NUM> bar) and the depth d requirement decreases correspondingly. Such shorter delivery lines are applicable when trawling for fish in shallower depths.

It should thus be understood that submerging the pump into the body of water as described above, in effect generates a vacuum pump system which is capable of delivering fluids to levels well above the water surface.

A basic principle of the invention is to lower the pump unit <NUM> to a depth d which is sufficient for avoiding cavitation. Thus the required depth d may be determined based on the pressure drop in the first delivery line <NUM> (including the collector <NUM>).

Referring now to <FIG>, an inlet valve <NUM> and a gate valve <NUM> are arranged in the second delivery line <NUM>, and the delivery line is connected consecutively to a water separator 31a, a storage tank 31b and a processing facility 31c. The skilled person will know that these components may be designed, configured and dimensioned for the applicable catch (i.e. nature of objects P), and that the processing plant <NUM> in fact may be any receiving facility. A water discharge pipe <NUM> is configured for returning water to the sea. A flushing pump <NUM> is configured to feed water into the second line <NUM>, between the inlet valve <NUM> and the gate valve <NUM>, via a pipe <NUM>, and a shut-off valve <NUM> is arranged between the flushing pump <NUM> and the second line <NUM>. The flushing pump <NUM> is typically arranged on the vessel and configured to deliver a flow of between <NUM> and <NUM> tonnes/hour at approximately <NUM> bar.

Fluidly connected to the first line <NUM>, hence on inlet side of the pump <NUM>, and arranged in the pump unit <NUM>, is a check valve <NUM>. The check valve <NUM> is preset or operated to prevent a collapse of the first line <NUM>, and will as such serve as a safety valve for the system. A typical opening pressure for the check valve is <NUM> bar, but this pressure may be set according to the applicable requirements. In addition to performing the safety valve function, the check valve may be operated (manually or automatically, e.g. based on sensor inputs) to control the mixture of seawater and fish passing through the pump, and thus in fact serve as a mixing valve. If it is desirable to increase the water flow, the valve may be opened fully or partially for a desired period of time.

<FIG> shows a situation in which the system is operating, i.e. feeding a mixture of water and objects P from the collector <NUM> to the processing plant <NUM>. The shut-off valve <NUM> is closed and the flushing pump <NUM> is off. Inlet valve <NUM> and gate valve <NUM> are open. The pump <NUM> is operating and the check valve <NUM> is closed, such that no seawater passes through the valve <NUM>. In this state, the system is operating within acceptable tolerances for avoiding cavitation. The valve <NUM> may be designed to open or close at predetermined pressures, or may be remotely operated.

During operation (e.g. trawling), the first delivery line <NUM> or the trawl outlet may become clogged by aggregation of objects P or by debris or other unwanted objects. The invented system makes it possible to resolve this problem without having to take the pumps and lines out of the water. <FIG> illustrates such cleaning procedure to remove obstacles from the delivery lines. In this configuration, the submerged pump <NUM> is not operating and the gate valve <NUM> is closed. The inlet valve <NUM> and the shut-off valve <NUM> are open and the flushing pump <NUM> is running. Therefore, the seawater is pumped by the flushing pump <NUM>, through the pipe <NUM>, down into the second line <NUM>, through the inactive pump <NUM> and into the first delivery line <NUM>, thereby flushing the first delivery line and the trawl outlet back into the trawl.

<FIG> illustrates the safety feature inherent in the check valve <NUM>. The shut-off valve <NUM> is closed and the flushing pump <NUM> is off, and inlet valve <NUM> and gate valve <NUM> are open, as is the case during normal operation. In the case of a blockage occurring in the first line <NUM> or at the inlet in the collector <NUM>, causing the vacuum in the first line to exceed the check valve <NUM> opening pressure, the check valve will open. In a practical application, sensors and control systems (not shown) will shut off the submerged pump <NUM>. Then, the blockage may be removed by the procedure described above with reference to <FIG>.

Although the invented system has been described above with the pump unit <NUM> being connected to the trawler (via a wire, carrier arm or similar), the invention shall not be limited to such physical connection. It should be understood that the invention is equally applicable to a system in which the pump unit is arranged in front of the trawl (collector), i.e. in the direction towards the trawler, and a second delivery line is connected between the pump unit and the collector.

Claim 1:
A pumping system for moving a liquid, or a mixture of a liquid and one or more objects (P), from a collector device (<NUM>; <NUM>') submerged in a body of water (W), to a receiving facility (<NUM>) arranged on a surface vessel or structure (<NUM>; <NUM>'), said collector device configured for being towed by the surface vessel or structure via towing means (<NUM>), or being suspended in the body of water, or moving along a seabed (B) below the body of water, or being stationary on the seabed (B);
said collector device (<NUM>) being a trawl or any suitable collector designed for collecting any objects suspended in water and for feeding a mixture of water and such objects into a first delivery line (<NUM>);
said system comprising the collector device (<NUM>; <NUM>'), the receiving facility (<NUM>), and the surface vessel or structure (<NUM>; <NUM>'), and further comprising the first delivery line (<NUM>), a second delivery line (<NUM>) and a pump unit (<NUM>) comprising a pump (<NUM>), wherein:
- the first delivery line (<NUM>) being fluidly connected between the collector device (<NUM>; <NUM>') and a pump unit inlet (<NUM>); and
- the second delivery line (<NUM>) being fluidly connected between a pump unit outlet (<NUM>) and the receiving facility (<NUM>);
whereby the pump unit is configured to generate suction in the first delivery line (<NUM>) and a positive pressure in the second delivery line (<NUM>),
wherein the pumping system is characterized by:
- the pump unit (<NUM>) being configured for being submerged in the body of water (W) at a first depth (d) below a surface (S) of the body of water and arranged between the collector device (<NUM>; <NUM>') and the receiving facility (<NUM>), while the collector device (<NUM>; <NUM>') is arranged at a second depth (t) below the surface (S); and
- the pump unit (<NUM>) is supported by the vessel or other structure (<NUM>; <NUM>') via connection means (<NUM>; <NUM>; <NUM>); and
- the pump unit is arranged at a depth necessary to obtain sufficient pressure at the pump inlet in order to avoid pump cavitation when drawing water through the first delivery line, and
- the pumping system further comprises a valve (<NUM>) fluidly connected to the first delivery line (<NUM>) at an inlet (<NUM>) in the vicinity of the pump unit (<NUM>) and operable to allow an inflow of ambient seawater into the first delivery line.