BE1030390B1 - APPARATUS FOR SEPARATING DEAD FISH IN AN AQUACULTURE CABIN AND RECIRCULATING AQUACULTURE CABIN - Google Patents

Abstract

The utility model relates to an apparatus for separating dead fish in an aquaculture cabin, comprising a mesh cover, arranged above a drainage port at the bottom of the aquaculture cabin.

Description

DEVICE FOR SEPARATING DEAD FISH IN A CABIN

AQUACULTURE AND RECIRCULATING AQUACULTURE CABIN

BACKGROUND OF THE INVENTION

[0001] 1. Technical field

[0002] The utility model relates to an apparatus for automatically separating dead fish in an aquaculture cabin, and belongs to the technical field of aquaculture.

[0003] 2. Description of the related art

[0004] Dead fish are frequently unavoidable in aquaculture.

However, in a recirculating aquaculture system, due to high aquaculture density, if a water exchange rate is not sufficient, dead fish may accumulate at a water outlet. spent at the bottom of an aquaculture aquatic cabin with water flow. An aquaculture workboat and other aquaculture aquatic cabins generally have large volumes, and too deep a draft depth makes it difficult to manually fish for dead fish and search for dead fish. If dead fish are not removed in time, dead fish can widely pollute a body of water and breed harmful substances, such as bacteria; and they can further affect the normal drainage of the aquaculture aquaculture cabin, which in turn causes great risks to the safety of aquaculture products.

[0005] How to identify and remove dead fish in a recirculating aquaculture system is a technical problem to be urgently solved in the art.

BRIEF SUMMARY OF THE INVENTION

[0006] An object of the utility model is to provide an apparatus for automatically separating dead fish in an aquaculture cabin, so as to automatically fish and collect dead fish.

[0007] The utility model uses the following technical solution:

[0008] An apparatus for separating dead fish in an aquaculture cabin comprises a mesh cover, arranged above a drainage port at the bottom of the aquaculture cabin; a piston mechanism arranged at an upper part of the net cover, a lower end of an execution mechanism 5 of the piston mechanism being connected to the upper part of the net cover, an upper end being connected to a water-sealing plate 6, and an interior of the piston mechanism being divided, by the water-sealing plate 6, into an upper cavity 10 and a lower cavity; and an incoming and outgoing water circulation system, comprising a first pipe communicating with the upper cavity 10 and the aquaculture water and a second pipe communicating with the lower cavity and the aquaculture water, the first pipe being provided with a first water pump 1-1 having a drainage direction facing the upper cavity 10, the second pipeline being provided with a second water pump 1-2 having a drainage direction facing the lower cavity , and both the first water pump 1-1 and the second water pump 1-2 can form reverse water flow paths when not in operation.

[0009] Preferably, the apparatus further comprises an ultrasonic sensor 7 arranged in the mesh cover and configured to detect a degree of accumulation of dead fish in the mesh cover; and a control box 4 serving as an apparatus control center for separating dead fish throughout the aquaculture cabin and electrically connected to the ultrasonic sensor 7, the first water pump 1-1 and the second water pump water 1-2.

[0010] Furthermore, the apparatus further comprises a pressure sensor 11 arranged in the upper cavity 10 and also electrically connected to the control box 4, the pressure sensor 11 being configured to send a signal to the control box 4 in function of a predefined upper pressure limit, to close the second water pump 1-2.

[0011] Furthermore, the control box 4 is provided with a power supply interface 2.

[0012] Furthermore, the piston mechanism and the incoming and outgoing water circulation system are both arranged in a watertight compartment; the waterproof compartment is provided with a first water inlet and outlet 9-1 and a second water inlet and outlet 9-2 of the incoming and outgoing water circulation system; the first water inlet and outlet 9-1 communicates with a water inlet of the first water pump 1-1; and the second water inlet and outlet 9-2 communicates with a water inlet of the second water pump 1-2.

[0013] Furthermore, the first water pump 1-1 and the second water pump 1-2 are both turbine pumps; and in a case where counter-current thrust is applied to the first water pump 1-1 and the second water pump 1-2 in an off state, the vanes can rotate in the opposite direction.

[0014] A recirculating aquaculture cabin comprises the apparatus for separating dead fish in the aquaculture cabin.

[0015] A method for separating dead fish in an aquaculture cabin uses the device to separate dead fish in the aquaculture cabin:

[0016] If dead fish appear at the bottom of the aquaculture cabin, the ultrasonic sensor 7 in the mesh cover detects a change in an ultrasonic wave. In a case where the accumulation of dead fish causes the ultrasonic wave to decrease to a predefined value a of the ultrasonic sensor 7, the first water pump 1-1 starts via the control box 4, then pushes, under the action of water pressure, the execution mechanism 5 to move upwards to lift the mesh cover. The water in the upper cavity 10 is drained to the second water inlet and outlet 9-2 through the second water pump 1-2, and then drained to the aquaculture cabin. The mesh cover is separated from a drainage pipe; and dead fish are sucked up and evacuated through the drainage pipe.

[0017] If the ultrasonic sensor 7 detects that the ultrasonic wave reaches a predefined value b after the dead fish adsorbed on the mesh cover are clearly eliminated, the first water pump 1-1 is closed and the second pump is closed. water 1-2 starts to push, under the action of water pressure, the execution mechanism 5 downwards; the water in the upper cavity 10 is drained to the first water inlet and outlet 9-1 through the first water pump 1-1, and then drained to the aquaculture cabin; and the water seal plate 6 of the execution mechanism drives the mesh cover to move to an initial position.

If the pressure sensor 11 arranged in the upper cavity 10 detects an increase in pressure up to a defined value, the pressure sensor 11 sends a signal to the control box 4, then the second water pump 1-2 is closed. At this time, the mesh cover moves to the original position.

[0019] The utility model has the following beneficial effects:

[0020] 1) Using water pressure as energy, an automatic lifting and lowering function of the mesh cover is achieved; and furthermore, when the mesh cover is in an open state, dead fish can directly enter the drainage pipe under the action of water flow; while live fish are able to swim against the current and cannot enter the drainage pipe, allowing dead fish to be evacuated and collected.

[0021] 2) As a preferred solution, the ultrasonic sensor is used to detect the degree of accumulation of dead fish at the bottom, and the activation or deactivation of the first water pump and the second water pump. Water is controlled automatically using an electric control box.

[0022] 3) The pressure sensor is ingeniously arranged in the upper cavity of the piston mechanism, in order to evaluate and determine whether the execution mechanism snaps back into place.

[0023] 4) The incoming and outgoing water circulation system is designed in the form of a single loop water flow system. In a case where one of the first water pump and the second water pump does not work, the incoming and outgoing water circulation system is still a link in the water flow path. The entire incoming and outgoing water circulation system is provided with only two water inlets and outlets communicating with the outside, which makes the structure of the entire incoming and outgoing water circulation system more concise outgoing, simplifies the layout of the pipes and makes the design more ingenious.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0024] Figure 1 is a diagram of the structure of a device for separating dead fish in the aquaculture cabin of the present utility model; And

[0025] Figure 2 is a detailed view of part A-A in Figure 1.

[0026] Reference numbers in the drawings: 1. water pump, 2. power interface, 3. switch, 4. control box, 5. execution mechanism, 6. water sealing plate , 7. ultrasonic sensor, 8. bottom cavity communication hole, 9-1. first entry and exit of water, 9-2. second water inlet and outlet, 10. upper cavity, and 11. pressure sensor.

DETAILED DESCRIPTION OF THE INVENTION

[0027] The utility model will be further illustrated below with reference to the appended drawings and specific embodiments.

Referring to Figures 1 and 2, an apparatus for separating dead fish in an aquaculture cabin comprises a mesh cover, arranged above a drainage port at the bottom of the aquaculture cabin; a piston mechanism arranged at an upper part of the net cover, a lower end of an execution mechanism 5 of the piston mechanism being connected to the upper part of the net cover, an upper end being connected to a water-sealing plate 6, and an interior of the piston mechanism being divided, by the water-sealing plate 6, into an upper cavity 10 and a lower cavity; and an incoming and outgoing water circulation system, comprising a first pipe communicating with the upper cavity 10 and the aquaculture water and a second pipe communicating with the lower cavity and the aquaculture water, the first pipe being provided with a first water pump 1-1 having a drainage direction facing the upper cavity 10, the second pipeline being provided with a second water pump 1-2 having a drainage direction facing the lower cavity , and both the first water pump 1-1 and the second water pump 1-2 can form reverse water flow paths when not in operation.

[0029] In this embodiment, referring to Figure 2, the apparatus further comprises an ultrasonic sensor 7 arranged in the mesh cover and configured to detect a degree of accumulation of dead fish in the mesh cover. net ; and a control box 4 serving as an apparatus control center for separating dead fish throughout the aquaculture cabin and electrically connected to the ultrasonic sensor 7, the first water pump 1-1 and the second water pump water 1-2.

[0030] In this embodiment, again referring to Figure 2, the apparatus further comprises a pressure sensor 11 arranged in the upper cavity 10 and also electrically connected to the control box 4, the pressure sensor 11 being configured to send a signal to the control box 4 according to a predefined upper limit of pressure, to close the second water pump 1-2. When the water sealing plate 6 moves upward again, the pressure in the upper cavity 10 can be gradually increased; and if the arranged pressure sensor 11 detects that the pressure has increased to a set value, the pressure sensor 11 sends a signal to the control box 4, and then the second water pump 1-2 is closed. At this time, it is certain that the mesh cover is moving towards the vicinity of an initial position.

[0031] In this embodiment, again referring to Figure 2, the control box 4 is provided with a power supply interface 2.

[0032] In this embodiment, again referring to Figures 1 and 2, the piston mechanism and the incoming and outgoing water circulation system are both arranged in a watertight compartment; the waterproof compartment is provided with a first water inlet and outlet 9-1 and a second water inlet and outlet 9-2 of the incoming and outgoing water circulation system; the first water inlet and outlet 9-1 communicates with a water inlet of the first water pump 1-1; and the second water inlet and outlet 9-2 communicates with a water inlet of the second water pump 1-2.

[0033] In this embodiment, the first water pump 1-1 and the second water pump 1-2 are both turbine pumps; and in a case where counter-current thrust is applied to the first water pump 1-1 and the second water pump 1-2 in an off state, the vanes can rotate in the opposite direction. Therefore, the incoming and outgoing water circulation system is designed as a single-loop water flow system. In a case where one of the first water pump and the second water pump does not work, the incoming and outgoing water circulation system is still a link in the water flow path.

The entire incoming and outgoing water circulation system is provided with only two water inlets and outlets communicating with the outside, which makes the structure of the entire incoming and outgoing water circulation system outgoing more concise and simplifies the layout of the pipes.

[0034] In this embodiment, a recirculating aquaculture cabin includes the apparatus for separating dead fish in the aquaculture cabin.

[0035] A method for separating dead fish in an aquaculture cabin uses the device to separate dead fish in the aquaculture cabin:

[0036] A specific operating method is described in the following.

[0037] Referring to Figures 1 and 2, if dead fish appear at the bottom of the aquaculture cabin, the ultrasonic sensor 7 in the mesh cover detects a change in an ultrasonic wave. In a case where the accumulation of dead fish causes the ultrasonic wave to decrease to a predefined value a of the ultrasonic sensor 7, the first water pump 1-1 starts via the control box 4 , then pushes, under the action of water pressure, the execution mechanism 5 to move upwards to lift the mesh cover. The water in the upper cavity 10 is drained to the second water inlet and outlet 9-2 through the second water pump 1-2, and then drained to the aquaculture cabin. The mesh cover is separated from a drainage pipe; and the dead fish are sucked up and discharged to a designated position through the drainage pipe.

[0038] If the ultrasonic sensor 7 detects that the ultrasonic wave reaches a predefined value b after the dead fish adsorbed on the mesh cover are clearly eliminated, the first water pump 1-1 is closed and the second pump is closed. water 1-2 starts at the same time to push, under the action of water pressure, the execution mechanism 5 downwards; the water in the upper cavity 10 is drained to the first water inlet and outlet 9-1 through the first water pump 1-1, and then drained to the aquaculture cabin; and the water-tight plate 6 of the execution mechanism drives the mesh cover to return to the original position.

The pressure sensor 11 is arranged in the upper cavity 10 of a piston liner. If the pressure in the upper cavity 10 reaches a set value after moving the mesh cover to the initial position, the pressure sensor 11 sends a signal to the control box 4, and then the second water pump 1-2 is closed. In the whole process, the normal circulation of water in an aquaculture water circulation system is not affected.

[0040] The utility model detects a situation of accumulation of dead fish at the drainage pipe using the ultrasonic sensor; a piston rod is driven by water pressure to perform transmission, and in turn drives the mesh cover to move upward, so as to completely expose a port of the drainage pipe d an aquatic aquaculture cabin; and at this time, without interception of the mesh cover at the drainage pipe port, the dead fish can be discharged outside the aquaculture water cabin with the flow of water. If the ultrasonic sensor cannot monitor the dead fish, it indicates that the dead fish have been completely removed, and the ultrasonic sensor sends a signal to the electrical control box and controls the water pumps to drive the piston rod, which moves the mesh cover down to a home position. It should be noted that if the mesh cover is in an open state, dead fish may directly enter the drainage pipe under the action of water flow; while live fish are able to swim against the current and cannot enter the drainage pipe. The piston liner is divided, by the piston rod, into an upper cavity and a lower cavity, and a sealing part is provided between a piston and the piston liner. The electrical control box, water pumps and other devices are arranged in a waterproof housing, so as to ensure the safety and reliability of the whole system.

[0041] From the above embodiments, it is easy to see that the utility model has the following several exceptional design points:

[0042] 1) The device is integrated into the drainage pipe, and capable of automatically carrying out detection, automatically eliminating dead fish and automatically restoring the initial state.

[0043] 2) Compared to artificial removal, the fish in the aquaculture cabin are not frightened, which does not affect aquaculture.

[0044] 3) The operation of the device is simple, and it is compact and easy to install and dismantle.

[0045] 4) The device has a wide range of applications and is suitable for all types of recirculating aquaculture cabins, including aquatic aquaculture cabins on aquaculture workboats.

[0046] 5) As a fully automatic device, the device saves labor and reduces management costs.

[0047] 6) The design is ingenious because the accumulation of dead fish is detected using an ultrasonic wave, and the fish net cover is opened and closed using the pressure of the water pumps.

[0048] 7) By combining the water flow characteristics of recirculating aquaculture with the counter-current swimming characteristic of fish, the risk of removing live fish from the water is reduced.

Claims (7)

1. Apparatus for automatically separating dead fish in an aquaculture cabin, characterized in that the apparatus comprises: a mesh cover arranged above a drainage port at the bottom of the aquaculture cabin; a piston mechanism arranged at an upper part of the net cover, in which a lower end of an execution mechanism (5) of the piston mechanism is connected to the upper part of the net cover, an upper end is connected to a water-sealing plate (6), and an interior of the piston mechanism is divided, by the water-sealing plate (6), into an upper cavity (10) and a cavity lower; and an incoming and outgoing water circulation system comprising a first pipeline communicating with the upper cavity (10) and the aquaculture water and a second pipeline communicating with the lower cavity and the aquaculture water, in which the first pipeline is provided with a first water pump (1-1) having a drainage direction facing the upper cavity (10), the second pipeline is provided with a second water pump (1-2) having a drainage direction facing the lower cavity, and the first water pump (1-1) and the second water pump (1-2) can both form reverse water flow paths when not in operation not. 2. Apparatus for separating dead fish in the aquaculture cabin according to claim 1, characterized in that the apparatus further comprises: an ultrasonic sensor (7) arranged in the mesh cover and configured to detect a degree of accumulation of dead fish in the mesh cover; and a control box (4) serving as an apparatus control center for separating dead fish throughout the aquaculture cabin and electrically connected to the ultrasonic sensor (7), the first water pump (1-1) and to the second water pump (1-2). 3. Apparatus for separating dead fish in the aquaculture cabin according to claim 2, characterized in that the apparatus further comprises a pressure sensor (11) arranged in the upper cavity (10) and also electrically connected to the housing control unit (4), the pressure sensor (11) being configured to send a signal to the control box (4) according to a predefined upper pressure limit, to close the second water pump (1-2). 4. Apparatus for separating dead fish in the aquaculture cabin according to claim 2, characterized in that the control box (4) is provided with a power interface (2). 5. Apparatus for separating dead fish in the aquaculture cabin according to claim 4, characterized in that the piston mechanism and the incoming and outgoing water circulation system are both arranged in a watertight compartment ; the waterproof compartment is provided with a first water inlet and outlet (9-1) and a second water inlet and outlet (9-2) of the incoming and outgoing water circulation system ; the first water inlet and outlet (9-1) communicates with a water inlet of the first water pump (1-1); and the second water inlet and outlet (9-2) communicates with a water inlet of the second water pump (1-2). 6. Apparatus for separating dead fish in the aquaculture cabin according to claim 2, characterized in that the first water pump (1-1) and the second water pump (1-2) are both water pumps. turbine; and in a case where counter-current thrust is applied to the first water pump (1-1) and the second water pump (1-2) in an off state, the vanes can rotate in the opposite direction. 7. Recirculating aquaculture cabin, comprising the apparatus for separating dead fish in the aquaculture cabin according to any one of claims 1 to 5.