NO347709B1 - Fleasing unit - Google Patents

Description

Technical area

[0001] The present invention relates to a deworming unit with spray nozzles for deworming fish.

Background technology

[0002] Lice on farmed fish is a major problem and large resources are therefore used to de-lice fish. After a de-lice, it may be necessary to rinse the fish that has been de-liced so that loose lice are washed away.

[0003] From the patent literature there are examples of methods for flushing lice from fish, an example can be found in WO 2021/201686 A1. This publication shows a deworming unit at least comprising a body carrying a channel with an angle of incidence relative to a horizontal plane. There are metal ribs arranged in parallel, the metal ribs form a B-shaped track, where the back of the B forms an upper side of the two tracks. Nozzles are attached for flushing fish to the ribs.

[0004] Patent document NO304171NO mentions a device for deworming fish, the device comprises a pool where fish to be dewormed are kept. A cleaning pipe extends vertically down from one end of the pool. The cleaning pipe is arranged concentrically to an external pipe. The cleaning pipe has a bend at a lower end. The outer concentric tube is vertical and it has a filter arranged at a lower end to catch lice.

The cleaning pipe has an open section where four nozzles are arranged, the nozzles are arranged to flush lice from fish that pass through the essentially vertical cleaning pipe. In the open part, lice that are removed can also be led over into the external concentric tube so that lice can be collected in the filter at the bottom of this tube.

[0005] US 2018/0255749 A1 shows a deworming device where fish to be dewormed is transported in a pipe with an incline in the pipe, flushing nozzles are arranged which will deworm the fish. Fish and lice from the fish will be transported together out of the pipe.

[0006] NO344621 B1 shows a deworming device for non-medicinal deworming.

The de-lice equipment is lowered into a cage and the de-lice equipment comprises panels with openings through which the fish can swim, the panels are equipped with flushing nozzles to flush away lice.

[0007] It is a problem that you need a relatively high pressure in relation to what is desirable from an animal welfare point of view.

Summary of the invention

[0008] The above-mentioned problems are solved according to the present invention by providing a deworming unit comprising at least one conveyor belt for fish to be dewormed, where the conveyor belt is surrounded by spray nozzles which are oriented from several sides in relation to fish being transported in the conveyor belt.

[0009] In one embodiment, the ablution unit may comprise a first enclosing nozzle manifold arranged at the top of the chute, a second enclosing nozzle manifold arranged downstream of the first nozzle manifold and a third nozzle manifold arranged downstream of the second nozzle manifold.

Each of the nozzle manifolds can comprise between six and eight spray nozzles which are distributed at approximately equal distances 360º around the nozzle manifold.

[0010] In one embodiment, the enclosing nozzle manifolds may have a center that coincides with the bottom of the chute.

[0011] The spray angle from the spray nozzles for the first nozzle manifold, the second nozzle manifold and the third nozzle manifold can be different from each other, and in one embodiment the spray nozzles' spray angle in relation to the fall angle α can be adjusted.

[0012] In one embodiment, a pressure sensor can measure the pressure of one or more nozzle manifolds and where an output signal representing the pressure in the nozzle manifold can be used in a feedback loop for engagement with a valve that regulates the amount of fluid that enters the nozzle manifold.

[0013] The angle of incidence α can be between 15º and 40º.

[0014] In a specific example of the invention, the first nozzle manifold can have the nozzles mounted 80 - 100° in relation to the direction of travel of fish being transported in the chute and the second nozzle manifold can have the nozzles oriented 110 - 130° in relation to the direction of travel of fish being transported in the chute, i.e. against the fish's direction of travel v, the third nozzle manifold can have the nozzles oriented 45 - 70° in relation to the fish's direction of travel v, i.e. with the fish's direction of travel.

[0015] Further advantages of the present invention will emerge from the associated patent claims.

Brief description of the figures

[0016] In what follows, a brief description of the figures follows to facilitate the understanding of the invention. The subsequent discussion will refer to the associated figures.

[0017] Fig. 1 shows a rinsing unit seen from the side,

[0018] fig. 2 shows a flushing unit seen in oblique perspective from above,

[0019] fig. 3a shows a nozzle manifold of octagonal type with 8 nozzles, one valve and a manometer/pressure sensor seen parallel to the direction of travel for fish sliding down a chute,

[0020] fig. 3b shows an octagonal type nozzle manifold with 8 nozzles, one valve and a manometer/pressure sensor viewed perpendicularly (from the side) to the direction of travel of fish sliding down the chute,

[0021] fig 4a shows a nozzle manifold of circular type with 8 nozzles, one valve and a manometer/pressure sensor seen parallel to the direction of travel for fish sliding down the chute,

[0022] fig 4b shows a nozzle manifold of circular type with 8 nozzles, one valve and a manometer/pressure sensor seen perpendicularly (from the side) to the direction of travel for fish sliding down the chute

[0023] Fig. 5 shows the angle of incidence α for the chute as well as the angle between the spray jets and the chute,

[0024] fig. 6 shows an octagonal nozzle manifold with a feedback loop with input signals from a pressure sensor for regulating pressure by activating a valve,

[0025] fig 7 shows an example of a simple regulation loop for regulation of pressure/water quantity that is fed into a nozzle manifold, and

[0026] fig. 8 shows a schematic picture of a de-lice unit with three nozzle manifolds, the direction of water jets from nozzles is indicated by arrows.

Detailed description of the invention

[0027] The present invention relates to a flushing unit for de-liceing fish where fish is transported down a chute with a drop.

Surrounding the chute are one or more nozzle manifolds, where nozzles on one or more nozzle manifolds are spread around the manifold so that the chute, and thus fish for de-lice removal, can be flushed from all sides, i.e. 360º so that loose or partially loose lice are released from the fish and can be taken to water treatment facilities. In one example, seawater from a pumping system for a ship can be fed to one or more high-pressure pumps. The water pressure can be increased to 13-14 bar from the pump and fed to a manifold intake under the flushing unit using pipes and hoses. The pressure can be read for each nozzle manifold. The pressure and water flow can be adjusted with a valve and/or via one or more pumps' frequency converter(s). The water that follows the fish in the chute can be filtered off and collected in a collection vessel and then taken to a water treatment system.

[0028] The present invention will now be described in more detail with support in the associated figures.

[0029] Figure 1 shows an example of a flushing unit 10. The flushing unit comprises a chute with a drop indicated by the arrow marked with v. Fish to be de-fleaed is brought in from the highest part of the chute so that the fish slides down the chute. Downstream, three octagonal nozzle manifolds 15a, 15b, 15c are arranged.

[0030] Each nozzle manifold is provided with several nozzles. In the example shown, seven nozzles 16 are arranged on each nozzle manifold. The nozzles are spread around the manifold so that fish can be flushed from all sides.

[0031] In addition, each nozzle manifold 15a, 15b, 156c has the nozzles oriented a few degrees differently. A first nozzle manifold 15a has the nozzles mounted 90° in relation to the fish's direction of travel v. The middle nozzle manifold 15b has the nozzles oriented 120° in relation to the fish's direction of travel v, i.e. towards the fish's direction of travel v. The last one has the nozzles oriented 60° in relation to the fish's direction of travel v, i.e. with the direction of the fish's movement. The nozzles can be adjustable, for example with a ball joint, so that the radiation angle towards fish in the chute can be optimised.

[0032] The nozzle manifolds are provided with manometers 14a, 14b, 14c.

The nozzle manifolds are fed with water from a manifold via branch pipes 12a, 12b, 12c. The manifold is fed via a manifold inlet 11. The branch pipes 12a, 12b, 12c can be supplied with valves 13a, 13b, 13c.

[0033] The rinsing unit 10 is provided with a collection tank/collection vessel 17. In the collection vessel, water from the de-lice process will be collected.

[0034] The rinsing unit is supported by a framework 18.

[0035] Figure 2 shows the rinsing unit 10 seen obliquely from above, parallel to the direction of travel v. It is clear from the figure that the octagonal nozzle manifolds 15a, 15b, 15c surround a chute 23. The chute 23 is U-shaped and consists of a number of elongated tubular bodies 21 which is arranged in the direction of travel v. In the example in Figure 2, the elongated tubular bodies are held in place by a series of brackets 22 which engage with the framework 18 and the elongated tubular bodies 21.

[0036] The elongated tubular bodies 21 which together form a U-shaped chute provide little sliding friction for fish being transported down the chute 23, at the same time flushing water with lice from fishing will be drained out of the chute 23.

[0037] Figure 3a shows an octagonal nozzle manifold 15 with eight nozzles 16a - 16h.

The octagonal nozzle manifold is seen parallel to the direction of travel v. Figure 2 schematically shows a manometer 14. The manometer can be replaced by a pressure sensor 14, alternatively be a combination of a manometer and a pressure sensor. A pressure sensor will be able to provide information about the pressure to monitoring systems and/or regulation systems. At the bottom of the octagonal nozzle manifold, branch pipe 12 is shown. The branch pipe leads fluid from a manifold into the nozzle manifold 15. The amount of water and water pressure into the nozzle manifold can be regulated with a valve 13.

[0038] Note that a fish 31 is shown centered in the octagonal nozzle manifold, the distance r between nozzles 16 and fish 16 is approximately the same for all nozzles 16. The bottom of the chute 23 corresponds to the center of the octagonal nozzle manifold. The location of the chute in a center of the nozzle manifold ensures equal flushing conditions from all nozzles towards a fish 31 in the chute 23.

[0039] Figure 3b shows the same octagonal nozzle manifold as in Figure 3a, but here seen from the side. The nozzles 16a – 16h for flushing fish are shown to the left of the nozzle manifold itself. That is, downstream of the nozzle manifold pipe itself. In another embodiment, the nozzles 16a - 16h can be arranged upstream of the nozzle manifold pipe. One can also imagine a combination of nozzles arranged upstream and downstream of the nozzle manifold pipe.

[0040] It is suggested that the nozzles 16a - 16h can be angularly adjusted in relation to an incidence angle α. The angle adjustment makes it possible to optimize the flushing direction so that rinsing can be effective without the water pressure having to be increased.

The angle adjustment is an option, when the most effective angles are determined based on experience then these angles can be fixed.

[0041] Figure 3b also shows a pressure gauge 14, which for other embodiments can be combined with a pressure sensor or replaced by a pressure sensor.

[0042] Figure 4a shows a circular nozzle manifold 45. The circular nozzle manifold corresponds functionally to the octagonal nozzle manifold 15 shown in Figure 3a. Note that here too the bottom of the chute 23 is in the center and thus the fish is transported down the chute 23 in the direction of travel v in the center of the nozzle manifolds 45.

[0043] Figure 4b shows the circular nozzle manifold 45 seen from the side. The only thing that distinguishes the circular nozzle manifold 45 from the octagonal one 15 in figure 3b is the shape. Both enclose the chute 23.

[0044] Figure 5 shows an angle of incidence α for the chute 23. The spray nozzles 16 are shown at an angle in relation to the direction of travel v. The angles for a first, a second and a third nozzle manifold can be different, as discussed at the outset.

[0045] Figure 6 shows an octagonal nozzle manifold where a pressure sensor 64 forms part of a feedback loop 61 in that the signal from the pressure sensor 64 is in communication with the valve 13 via a controller that is not shown in the figure. A control loop with feedback from the pressure sensor 64 can ensure an optimal water pressure for the flushing nozzles, and the signal can also be used to monitor the pressure in the system.

[0046] Figures 6 and 7 show examples of pressure control using a pressure sensor that provides an output signal representing a pressure. Typically, the sensor output of a pressure transmitter will be optional between 4 – 20 mA, 0 – 5 V, 1 – 5 V, 1 – 6 V, 0 – 10 V and 10 – 90% ratiometric. The pressure sensor may have additional functions provided by microcontrollers that offer diagnostic functions and intelligent performance functions.

[0047] A variable frequency drive (VFD) is a type of motor controller that drives an electric motor by varying the frequency and voltage of the power supply. The VFD also has the capacity to control the ramp-up and de-ramp of the motor during start or stop respectively.

The frequency can be correlated with operating parameters from the flushing unit 10 such as the output signal from one or more pressure sensors.

The output signal from pressure sensors can be transformed into frequencies that represent fluid pressure.

[0048] The frequency converter controls the frequency and the voltage that is supplied to a motor, thus you have a speed regulation of the motor.

[0049] Figures 1 - 7 show valves for controlling liquid pressure and liquid flow, however, one or more pumps can be used for the same purpose.

Liquid pressure and liquid flow can be effectively controlled with one or more pumps that control liquid pressure and liquid flow into the manifold inlet 11. Pumps used can be controlled by a variable frequency control from an AC induction motor. Variable frequency control provides an economically sound and operationally efficient solution for speed regulation of motors.

[0050] There are many reasons why we might want to adjust this engine speed.

[0051] Figure 7 shows a simple regulation loop schematically.

[0052] In the examples above octagonal and circular nozzle manifolds are shown, but the nozzle manifolds can for example be oval or have other shapes, the point is to optimize the flushing effect by having a nozzle manifold that encloses the chute 23. However, as indicated above, it is not just a advantage that the fish can be flushed from all sides, it is also a point that the distance between nozzle and fish is the same from all nozzles on the same nozzle manifold, the water pressure will then be the same on all sides of the fish.

[0053] Figure 8 shows an ablution unit with three nozzle manifolds. From the figure, it can be seen that the jet direction 83 for water from the nozzles on the first nozzle manifold is partly upstream. On the second nozzle manifold, the direction of the water jets from the nozzles 16 is directed approximately perpendicular to the direction of travel v. The jet direction 81 for water jets from the third nozzle manifold is partially countercurrent.

[0054] The figure also shows that pressure sensors 14 are used for reading water pressure. The signals from the pressure sensors are shown in communication with a controller 85. The controller 85 may be a frequency converter which converts analog or digital signals from the pressure sensors into variable frequency signals. Where the frequency is associated with the value of the input signal. The frequency converter can be a standard VFD converter. The controller 85 controls the input to the pump 86. The pump 86 receives water from a reservoir 87.

[0055] The figure shows that the valves are controlled by the controller 85. If the pressure and amount of liquid into the purge unit is controlled by the controller 85 in communication with the pump 86, then valve control will be an option that will be able to provide individual control of pressure in each of the nozzle manifolds 15a, 15b, 15c. The valves 13 are shown with commands from the controller 85, they can also be manual. Furthermore, the valves 13 may include an actuator that enables regulation of the valves 13 from the controller 85, alternatively the actuator may be a separate part. The actuator is not shown in any of the figures.

[0056] Selection of the number of nozzles on the nozzle manifolds can be determined based on specific installations and needs.

[0057] Figure 1 and Figure 2 show three nozzle manifolds, but one can imagine anything from one nozzle manifold to more than three nozzle manifolds.

[0058] The chute 23 is shown produced with a number of elongated tubular bodies, this is one embodiment of many possible embodiments. One can imagine that the chute 23 is provided by an elongated U-shaped plate with a number of openings, mesh variants can also be imagined.

[0059] Reference numbers, mapping list

Claims (9)

Patent claims 1. A deworming unit (10) comprising at least: a. a framework (18) which carries a U-shaped chute with parallel arranged ribs where the chute has an angle of incidence α in relation to a horizontal plane, b. enclosing the chute, there is arranged at least one enclosing nozzle manifold (15) and there c. the nozzle manifold (15) includes at least two spray nozzles (16) for removing fish and where at least one nozzle (16) can spray towards the chute from the underside of the chute. 2. A deworming unit according to patent claim 1, where the deworming unit comprises a first enclosing nozzle manifold (15a) arranged at the top of the chute, a second enclosing nozzle manifold (15b) arranged downstream of the first nozzle manifold and a third nozzle manifold (15c) arranged downstream of the second the nozzle manifold. 3. An ablution unit according to patent claim 1 or 2, where each of the nozzle manifolds (15a, 15b, 15c) comprises between six and eight spray nozzles (16) which are distributed at approximately equal distances 360º around the nozzle manifold. 4. A de-lice assembly according to any one of claims 1-3, wherein the enclosing nozzle manifolds (15a, 15b, 15c) have a center coinciding with the bottom of the chute. 5. A deworming unit according to any one of claims 1 - 4 wherein the spray angle from the spray nozzles (16) of the first nozzle manifold (15a), the second nozzle manifold (15b) and the third nozzle manifold (15c) is different from each other. 6. An ablution unit according to any of the preceding patent claims where the spray angle of the spray nozzles (16) in relation to the angle of incidence α can be adjusted. 7. A de-bug unit according to any one of the preceding patent claims wherein a pressure sensor (14) measures the pressure of one or more nozzle manifolds (15a, 15b, 15c) and wherein an output signal representing the pressure in the nozzle manifold (15a, 15b, 15c) ) is used in a feedback loop for engagement with a valve (13) which regulates the amount of fluid admitted into the nozzle manifold (15a, 15b, 15c). 8. A de-lice device according to any one of the preceding claims wherein the angle of incidence α is between 15º and 40º. 9. A de-lice unit according to any one of the preceding patent claims where the first nozzle manifold (15a) has the nozzles (16) mounted 80 - 100° in relation to the direction of travel of fish transported in the chute the second nozzle manifold (15b) has the nozzles (16) oriented 110 - 130° in relation to the direction of movement of fish being transported in the chute, i.e. towards the direction of movement of the fish v the third nozzle manifold (15c) has the nozzles (16) oriented 45 - 70° in relation to the direction of movement of the fish v, i.e. with the direction of the fish direction of travel.