A device for recovering and maintaining goldfish after artificial propagation

By designing a rehabilitation and care device for goldfish after artificial breeding, and using driving and blocking components to achieve automatic transfer and isolation of fish, the problem of stress response caused by repeated fishing is solved, and the recovery quality and efficiency of goldfish are improved.

CN224460900UActive Publication Date: 2026-07-07BEIJING ACADEMY OF AGRICULTURE & FORESTRY SCIENCES

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING ACADEMY OF AGRICULTURE & FORESTRY SCIENCES
Filing Date
2025-07-28
Publication Date
2026-07-07

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Abstract

The utility model relates to aquatic products breeding equipment technical field provides a kind of goldfish artificial propagation post-rehabilitation maintenance device.The goldfish artificial propagation post-rehabilitation maintenance device includes box, drives component and partition component.The inside of box has cavity, and top is equipped with opening;Drive component is located in the inside of cavity, for driving fish;Partition component is located in box, for switching between first state and second state, in first state, partition component divides cavity into not intercommunicating feeding area and medicated bath area;In second state, feeding area and medicated bath area are communicated.The utility model solves the defect that repeated fishing operation leads to stress reaction intensification in prior art, realizes the rehabilitation nursing operation of exempting from transfer processing, improves goldfish recovery quality and efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of aquaculture equipment technology, and in particular to a rehabilitation and maintenance device for goldfish after artificial breeding. Background Technology

[0002] In the artificial breeding of fish, especially during the postoperative recovery stage of ornamental fish such as goldfish, optimizing the rehabilitation and nursing process is of great significance for improving the survival rate and health of the fish.

[0003] Current rehabilitation devices primarily rely on conventional aquaculture ponds or simple medicated bath containers for post-operative treatment. Specific methods include directly administering medicated baths within the aquaculture pond or using temporary medicated bath tubs to soak the fish. The entire process requires repeated manual catching of the fish to complete the transfer and medicated bath steps.

[0004] However, this existing technology suffers from the problem of repeated fishing operations exacerbating stress responses, which in turn increases the risk of fish mortality and prolongs the recovery period. Utility Model Content

[0005] This invention provides a rehabilitation and care device for goldfish after artificial breeding, which solves the problem of repeated fishing operations in the prior art that aggravate stress response, realizes rehabilitation and care operations without transfer, and improves the quality and efficiency of goldfish recovery.

[0006] This utility model provides a rehabilitation and care device for goldfish after artificial breeding, comprising:

[0007] The box has an internal cavity and an opening at the top;

[0008] A repelling component, located inside the cavity, is used to repel fish;

[0009] A partition component is disposed in the housing and is used to switch between a first state and a second state. In the first state, the partition component divides the cavity into a non-communicating feeding area and a medicated bathing area; in the second state, the feeding area and the medicated bathing area are connected.

[0010] According to the present invention, a goldfish post-artificial breeding rehabilitation and care device is provided, wherein the box is provided with a sliding component;

[0011] The driving component is located inside the feeding area and is slidably connected to the sliding component; under the guidance of the sliding component, the driving component drives the fish to the medicated bath area.

[0012] According to the present invention, a goldfish rehabilitation and care device after artificial breeding is provided, wherein the sliding component is located on the inner wall of the cavity;

[0013] The driving-away component includes a fence, and sliding portions are provided on both sides of the bottom of the fence, the sliding portions slidingly engaging with the sliding component.

[0014] According to the present invention, a goldfish rehabilitation and care device after artificial breeding is provided, wherein the inner wall of the cavity is provided with a limiting groove, and the partition component is inserted into the limiting groove.

[0015] According to the present invention, a goldfish post-artificial breeding rehabilitation and care device is provided, wherein the partition component includes:

[0016] A baffle is inserted into the limiting groove;

[0017] A sealing element is provided, covering the outer edge of the baffle, to seal the gap between the baffle and the limiting groove.

[0018] According to the present invention, a goldfish rehabilitation and care device after artificial breeding is provided, wherein the bottom of the medicated bath area is provided with an excretion hole, and the excretion hole is provided with a detachable filter structure.

[0019] According to the present invention, a goldfish artificial breeding post-rehabilitation and maintenance device further includes a temperature control system, which is connected to the cavity and is used to control the temperature of the liquid inside the cavity.

[0020] According to the present invention, a goldfish rehabilitation and care device after artificial breeding also includes a lighting system, which is located above the medicated bath area.

[0021] According to the present invention, a goldfish post-artificial breeding rehabilitation and care device includes a sliding component comprising:

[0022] The track is located on the inner wall of the cavity and extends from the end of the feeding area away from the medicated bath area to the end closer to the medicated bath area;

[0023] A sliding member is slidably disposed on the track, and the driving component is connected to the sliding member.

[0024] According to the present invention, a goldfish rehabilitation and care device after artificial breeding is provided, wherein the cavity is provided with an oxygen supply system.

[0025] This invention provides a goldfish rehabilitation and care device after artificial breeding. The device achieves zoned control through sequential operation: the initial connected state maintains normal fish activity; the vertical sliding of the driving component forces the fish to concentrate in the medicated bath area, after which the insert plate forms a physical isolation barrier. This mechanical operation eliminates the manual harvesting step, avoids mechanical damage and stress to the fish's body surface, reduces the risk of postoperative infection, and shortens the recovery period. Attached Figure Description

[0026] To more clearly illustrate the technical solutions in this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.

[0027] Figure 1 This is a cross-sectional view of the goldfish rehabilitation and maintenance device provided by this utility model after artificial breeding.

[0028] Figure 2 This is a schematic diagram of the structure of the box of the goldfish rehabilitation and maintenance device after artificial breeding provided by this utility model.

[0029] Figure 3 This is a schematic diagram of the structure of the fence of the goldfish rehabilitation and maintenance device after artificial breeding provided by this utility model.

[0030] Figure 4 This is a schematic diagram of the partition component of the goldfish rehabilitation and maintenance device after artificial breeding provided by this utility model.

[0031] Figure label:

[0032] 100: Box body; 110: Feeding area; 120: Medicated bathing area; 130: Sliding parts; 140: Limiting groove; 150: Drainage hole;

[0033] 200: Driving component; 210: Fence; 220: Sliding part;

[0034] 300: Partition component; 310: Baffle; 320: Seal;

[0035] 400: Temperature control system;

[0036] 500: Illumination system. Detailed Implementation

[0037] To make the objectives, technical solutions, and advantages of this utility model clearer, the technical solutions of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.

[0038] The following is combined Figures 1-4 Describe the structure and working principle of this utility model.

[0039] Reference Figure 1 and Figure 2The goldfish artificial breeding and rehabilitation device provided by this utility model includes a box 100, a repelling component 200, and a partition component 300. The box 100 has an interior cavity with an opening at the top; the repelling component 200 is located inside the cavity and is used to repel fish; the partition component 300 is located in the box 100 and is used to switch between a first state and a second state. In the first state, the partition component 300 divides the cavity into a non-connected feeding area 110 and a medicated bath area 120; in the second state, the feeding area 110 and the medicated bath area 120 are connected.

[0040] Specifically, the enclosure 100 is integrally molded from PVC or fiberglass, with a reinforced flange at the top opening edge. The driving component 200 is a rectangular mesh structure, with its two sides vertically sliding against the inner wall of the enclosure 100. PVC grooves are fixedly installed in the middle of the inner walls on both sides of the enclosure 100, and these grooves are connected to the enclosure 100 by stainless steel bolts that penetrate the wall, with the bolt heads recessed into pre-embedded holes in the wall. T-shaped sliders matching the grooves are located on both sides of the mesh, embedding themselves in the concave tracks of the grooves to form a sliding pair. A lifting handle is located at the center of the top of the mesh. The partition component 300 adopts a plug-in structure. Two rows of L-shaped stainless steel guide rails are welded to the front and rear inner walls at the junction of the feeding area 110 and the medicated bath area 120 within the enclosure 100. T-shaped flanges that fit with the guide rails are located on both sides of the PVC plug-in, with limiting blocks at the top of the flanges.

[0041] Initially, the insert plate of the partition component 300 is completely detached from the guide rail, connecting the rearing area 110 and the medicated bath area 120. During the medicated bath procedure, hold the lifting handle of the repelling component 200 and push the mesh plate vertically down the slide to the bottom of the tank, driving the fish to the medicated bath area 120. Then, insert the insert plate down the guide rail to the bottom, switching to the first state to isolate the two areas. After the medicated bath is complete, lift the insert plate to the limit stop position to restore connection between the two areas, and then raise the mesh plate to the initial height to allow the fish to swim back to the rearing area 110 on their own.

[0042] This invention achieves zoned control through sequential operation: the initial connected state maintains normal fish activity; the vertical sliding of the driving component 200 forces the fish to concentrate in the medicated bath area 120, after which the insert plate is inserted to form a physical isolation barrier. This mechanical operation eliminates the manual harvesting process, avoids mechanical damage and stress to the fish's body surface, reduces the risk of postoperative infection, and shortens the recovery period.

[0043] Reference Figure 1 and Figure 2In some embodiments of this utility model, the housing 100 is provided with a sliding component 130; the sliding component 130 includes a track and a sliding member, the track is disposed on the inner wall of the cavity and extends from the end of the feeding area 110 away from the medicated bath area 120 to the end closer to the medicated bath area 120; the sliding member is slidably disposed on the track, and the driving component 200 is connected to the sliding member. The driving component 200 is located inside the feeding area 110 and is slidably connected to the sliding component 130; under the guiding action of the sliding component 130, the driving component 200 drives the fish to the medicated bath area 120.

[0044] Specifically, the sliding component 130 can be fixedly mounted on the top of the side wall of the tank 100 using bolts or plastic welding to ensure structural stability and prevent metal corrosion from affecting water quality. The sliding component 130 can be made of water-resistant engineering plastics (such as PVC or PP). In another embodiment, the sliding component 130 can be equipped with a cantilevered guide rail, and the driving component 200 slides along the guide rail via a pulley assembly. The pulley assembly uses a waterproof bearing structure and is fixed to the top of the driving component 200 via a stainless steel or plastic shaft. This method is suitable for larger tanks 100 and provides more stable sliding guidance.

[0045] In use, the operator pushes the driving component 200 along the guide direction of the sliding component 130, allowing it to move smoothly within the rearing area 110. The mesh or grid structure of the driving component 200 forms a continuous obstruction surface during movement, gradually driving the fish towards the medicated bath area 120. When the driving component 200 moves to the boundary between the rearing area 110 and the medicated bath area 120, the fish are fully inside the medicated bath area 120. After driving is complete, the driving component 200 can be reset to its initial position along the sliding component 130 for subsequent operations.

[0046] In this embodiment, the sliding component 130 and the driving component 200 are slidably connected to achieve directional movement of the driving component 200 within the rearing area 110. The guiding function of the sliding component 130 ensures the stability of the movement trajectory of the driving component 200, avoiding blind spots or fish escape during the driving process. In some other possible embodiments, the sliding component 130 may be provided with an arc-shaped guide rail, and the sliding end of the driving component 200 is adapted to this arc-shaped structure, so that the driving component 200 moves in a curved path.

[0047] Reference Figure 3 In some embodiments of this utility model, the sliding component 130 is located on the inner wall of the cavity; the driving component 200 includes a fence 210, and sliding portions 220 are provided on both sides of the bottom of the fence 210, and the sliding portions 220 are slidably engaged with the sliding component 130.

[0048] Specifically, the fence 210 can be made of flexible polyvinyl chloride (PVC) or silicone, with evenly distributed grid gaps to prevent fish from getting stuck or injured. The fence 210 is connected to the sliding part 220 by a snap-fit ​​or plastic bolt for easy disassembly and cleaning. In another embodiment, the fence 210 can have an adjustable height structure, with height changes achieved through the telescopic rod or folding mechanism of the sliding part 220.

[0049] During operation, the operator holds the top of the fence 210 and smoothly pushes it along the guide direction of the sliding component 130. As the fence moves, it forms a continuous blocking surface, gradually driving the fish to the target area. When the height of the fence 210 needs to be adjusted, the telescopic mechanism or folding section can be operated to accommodate different fish sizes. After driving the fish away, the fence 210 is returned to its initial position for future use.

[0050] This embodiment achieves stable fish herding through the sliding engagement of the fence 210 and the sliding component 130. The flexible material and reasonable grid design of the fence 210 reduce mechanical damage to the fish while effectively preventing them from escaping. The low-friction structure of the sliding part 220 ensures effortless operation and is not easily worn over long-term use. The height-adjustable fence 210 adapts to the needs of different fish groups, improving the versatility of the device. The overall structure is simple and reliable, and easy to maintain and clean.

[0051] In other possible embodiments, the fence 210 may be equipped with a detachable auxiliary net, which is attached to the main frame of the fence 210 by hooks or magnets. The mesh size of the auxiliary net can be changed according to the size of the fish to separate fish of different sizes. The main frame of the fence 210 may be hollow, with buoyancy material inside to keep the fence 210 upright in the water. This embodiment, through replaceable nets and a self-floating design, makes the repelling operation more flexible and is suitable for scenarios involving mixed-species fish of different sizes. The quick-release function of the auxiliary net allows for adjustment of the repelling effect according to different operational needs.

[0052] Reference Figure 2 In some embodiments of this utility model, the inner wall of the cavity is provided with a limiting groove 140, and the partition component 300 is inserted into the limiting groove 140.

[0053] Specifically, the limiting groove 140 is fixedly disposed on the inner wall of the cavity and can be manufactured by integral injection molding with the cavity to ensure structural integrity and sealing. The limiting groove 140 has a U-shaped or T-shaped cross-section, and its width is slightly larger than the thickness of the insertion end of the partition component 300. The limiting groove 140 is made of high-density polyethylene (HDPE) or polypropylene (PP) material, which has sufficient strength and wear resistance. The insertion end of the partition component 300 is provided with a flange structure that matches the limiting groove 140. The flange thickness is 0.5-1mm smaller than the width of the limiting groove 140, which facilitates insertion and maintains a moderate tight fit. The partition component 300 can be made of transparent polycarbonate (PC) material for easy observation of the internal situation. In another embodiment, the limiting groove 140 can be provided with a guide slope, and the width at the entrance is slightly larger than the internal width, which facilitates the initial alignment and insertion of the partition component 300.

[0054] In use, the operator aligns the insertion end of the partition component 300 with the entrance of the limiting groove 140 and inserts it smoothly in a vertical direction. Once the partition component 300 is fully inserted into the limiting groove 140, its flange structure forms a tight fit with the limiting groove 140, achieving fixation. To remove, hold the upper part of the partition component 300 and pull it out smoothly in the opposite direction of insertion. Throughout the insertion and removal process, the guiding structure of the limiting groove 140 ensures that the partition component 300 maintains the correct movement trajectory.

[0055] This embodiment achieves rapid installation and disassembly through the plug-in connection between the limiting groove 140 and the partition component 300. The U-shaped or T-shaped cross-section design of the limiting groove 140 provides stable guidance and limiting function, ensuring that the partition component 300 will not shake or shift after installation. The limiting groove 140, made of HDPE or PP material, has good corrosion resistance and wear resistance, making it suitable for long-term use in aquatic environments. The transparent PC material partition component 300 ensures structural strength without obstructing observation of the internal conditions of the cavity. This structure is simple, reliable, easy to operate, and has low maintenance costs.

[0056] Reference Figure 2 and Figure 4 In some embodiments of this utility model, the partition component 300 includes a baffle 310 and a sealing member 320. The baffle 310 is inserted into the limiting groove 140; the sealing member 320 covers the outer edge of the baffle 310 and is used to seal the gap between the baffle 310 and the limiting groove 140.

[0057] Specifically, the baffle 310 is injection molded from polypropylene (PP) or polycarbonate (PC), and its insertion end has a flange structure that matches the limiting groove 140. The thickness of the baffle 310 is 3-5mm, and the flange extends outward to form a 2-3mm step. The seal 320 is made of food-grade silicone material and is fixed to the outer edge of the baffle 310 by injection molding, with a covering thickness of 1.5-2mm. The cross-section of the seal 320 is semi-circular, forming an interference fit with the inner wall of the limiting groove 140. In another embodiment, the baffle 310 may have a dovetail groove structure, and the seal 320 is fixed by extrusion into the dovetail groove. The outer side of the seal 320 may have a wavy sealing lip, which can produce a better sealing effect under pressure.

[0058] During operation, first align the flange of the baffle 310 with the entrance of the limiting groove 140 and insert it smoothly in a vertical direction. Once the baffle 310 is fully inserted, the seal 320 is deformed by the compression of the inner wall of the limiting groove 140, forming a sealing interface. When disassembly is required, hold the upper edge of the baffle 310 and slowly apply force to pull it out of the limiting groove 140. During insertion and removal, the elastic deformation of the seal 320 ensures that the inner wall of the limiting groove 140 will not be damaged.

[0059] This embodiment achieves rapid installation through the insertion and engagement of the baffle 310 and the limiting groove 140, while the covering design of the seal 320 effectively prevents liquid leakage. The rigid structure of the baffle 310 provides support, and the elastic properties of the seal 320 ensure a good seal. The baffle 310, made of PP or PC material, has good corrosion resistance, and the seal 320, made of food-grade silicone, is safe and reliable. This structure is easy to install, has good sealing performance, is reusable, and is easy to maintain.

[0060] In some possible embodiments, the baffle 310 may have a double-layer structure, with an inner rigid support plate and an outer elastic sealing layer. The seal 320 and the baffle 310 are integrally formed using a co-extrusion process, creating a seamless connection. This embodiment, through its double-layer structure design, ensures both the structural strength of the baffle 310 and the durability of the seal 320. The co-extrusion process ensures a firm bond between the seal 320 and the baffle 310, avoiding the detachment problems that may occur with traditional encapsulation processes. This design is particularly suitable for applications requiring frequent disassembly and reassembly.

[0061] Reference Figure 2 In some embodiments of this utility model, the bottom of the medicated bath area 120 is provided with a drain hole 150, and the drain hole 150 is provided with a detachable filter structure.

[0062] Specifically, the drain hole 150 is located at the lowest point of the bath area 120 and is manufactured using an integral injection molding process with the housing. The edge of the drain hole 150 has a 45-degree chamfer for easy drainage. The filter structure is made of 304 stainless steel and is fixed to the drain hole 150 via threaded connection or snap-fit ​​structure. In another embodiment, the drain hole 150 can be connected to a drain pipe made of soft PVC material, which is sealed to the drain hole 150 via heat fusion. A control valve can be installed at the end of the drain pipe, the valve body of which is made of PP material and connected to the drain pipe via threads.

[0063] Before use, first check that the filter structure is installed correctly. When drainage is needed, open the control valve or drain directly through the drain hole 150. During drainage, the filter structure effectively blocks fish and impurities from passing through. After drainage, the filter structure can be disassembled for cleaning and maintenance. If a drainage pipe is installed, the drainage speed can be controlled by adjusting the opening of the control valve.

[0064] This embodiment achieves convenient drainage of the medicated bath area 120 through the design of the drain hole 150. The one-piece molded drain hole 150 structure ensures a tight seal. The detachable filter structure prevents fish from escaping and facilitates cleaning and maintenance. The combined use of the drain pipe and control valve allows for controllable adjustment of the drainage speed.

[0065] Reference Figure 1 In some embodiments of this utility model, a temperature control system 400 is also included, which is connected to the cavity and is used to control the temperature of the liquid inside the cavity.

[0066] Specifically, the temperature control system 400 is fixedly installed on the outside of the cavity and communicates with the inside of the cavity through an inlet and an outlet. The temperature control system 400 includes a heating unit, a circulation pump, and a temperature sensor, with all components connected via PVC piping to form a closed loop. The heating unit uses a stainless steel heating element and is fixedly connected to the circulation pump via a flange. The inlet and outlet of the circulation pump are equipped with quick-connect couplings for easy connection and disconnection to the inlet and outlet water pipes of the cavity. The temperature sensor is located inside the cavity and is connected to the control unit of the temperature control system 400 via a waterproof cable. In another embodiment, the temperature control system 400 can have a dual-heating-unit structure, with two heating units arranged in parallel and connected to the circulation pump via a three-way valve.

[0067] Before use, first check that all connections of the temperature control system 400 are properly sealed. Start the circulation pump to allow the liquid in the chamber to flow through the temperature control system 400. Set the target temperature through the control unit, and the heating unit adjusts the heating power according to the feedback signal from the temperature sensor. When maintenance is required, disconnect the quick connector to separate the temperature control system 400 from the chamber.

[0068] This embodiment achieves precise control of the liquid temperature inside the cavity through a temperature control system 400. A circulation pump ensures uniform liquid flow, preventing localized overheating or underheating. The stainless steel heating element offers excellent corrosion resistance and heating efficiency. The quick-connect design facilitates system installation and maintenance. This structure operates stably and provides precise temperature control, meeting the requirements for different bath temperatures.

[0069] Reference Figure 1 In some embodiments of this utility model, the goldfish artificial breeding post-rehabilitation and care device also includes a lighting system 500, which is located above the medicated bath area 120.

[0070] Specifically, the lighting system 500 is fixedly installed above the medicated bath area 120 and connected to the top of the housing 100 via a bracket structure. The bracket structure is made of stainless steel and is fixed to the top frame of the housing 100 with bolts. The lighting system 500 includes LED light groups and a waterproof lampshade. The LED light groups are fixed inside the waterproof lampshade via slots. The waterproof lampshade is made of transparent PC material with silicone sealing rings on the edges and is fixedly connected to the bracket structure with screws. In another embodiment, the lighting system 500 can be equipped with a height adjustment mechanism, which includes a sliding guide rail and a positioning pin. The sliding guide rail is fixed to the inside of the housing 100, and the positioning pin is located on the bracket structure. The height of the lighting system 500 can be adjusted through positioning holes of different heights.

[0071] This embodiment provides a suitable lighting environment for the medicated bath area 120 through the lighting system 500. The LED light assembly is energy-efficient and can provide light of different spectra to meet the recovery needs of fish. A waterproof lampshade ensures the safe use of the lighting system 500 in humid environments. The rigid connection of the support structure ensures the stability of the lighting system 500. This structure is easy to install, safe to use, and effectively promotes the recovery process of fish.

[0072] In some embodiments of this utility model, the cavity is provided with an oxygen supply system (not shown in the figure).

[0073] Specifically, the oxygen supply system is fixedly installed at the bottom of the inner wall of the cavity and connected to an external oxygen source via an oxygen supply pipeline. The oxygen supply system includes microporous aerator heads and a distributor. The microporous aerator heads are made of silicone and are fixed to the outlet of the distributor via a threaded connection. The distributor has a T-shaped structure, is made of ABS engineering plastic, and is connected to the oxygen supply pipeline via a clamp. The oxygen supply pipeline is a food-grade flexible hose and is connected to the external oxygen source via a quick connector. In another embodiment, the oxygen supply system can be equipped with an annular air distribution pipe, which is arranged circumferentially along the inner wall of the cavity and fixed to the bottom of the cavity by a bracket. Microporous aerator heads are evenly distributed on the annular air distribution pipe, and the airflow of each aerator head is controlled by an independent valve.

[0074] Before use, reliably connect the oxygen supply line to the external oxygen source. Open the oxygen source valve and adjust the flow control valve on the distributor to the appropriate opening. Observe the air output from the microporous aerator head to ensure that the bubbles are evenly distributed. After use, first close the oxygen source valve, and disconnect the oxygen supply line after all residual gas in the system has been expelled. Regularly check the microporous aerator head for blockage, and clean or replace it if necessary.

[0075] This embodiment provides sufficient dissolved oxygen to the water within the chamber through an oxygen supply system. The tiny bubbles generated by the microporous aerator head increase the gas-liquid contact area, improving oxygen dissolution efficiency. The silica gel aerator head exhibits excellent corrosion resistance and flexibility. The distributor structure ensures uniform oxygen distribution, preventing localized oxygen deficiency. This structure provides stable oxygen supply, is easy to install and maintain, and effectively improves the dissolved oxygen status of the water.

[0076] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model, and not to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.

Claims

1. A rehabilitation and care device for goldfish after artificial breeding, characterized in that, include: The box (100) has an internal cavity and an opening at the top; A repelling component (200) is disposed inside the cavity and is used to repel fish; A partition component (300) is provided on the housing (100) for switching between a first state and a second state. In the first state, the partition component (300) divides the cavity into a non-communicating feeding area (110) and a medicated bath area (120). In the second state, the feeding area (110) and the medicated bath area (120) are connected.

2. The goldfish post-artificial breeding rehabilitation and care device according to claim 1, characterized in that, The housing (100) is provided with a sliding component (130); The driving component (200) is located inside the feeding area (110) and is slidably connected to the sliding component (130); under the guidance of the sliding component (130), the driving component (200) drives the fish to the medicated bath area (120).

3. The goldfish post-artificial breeding rehabilitation and care device according to claim 2, characterized in that, The sliding component (130) is located on the inner wall of the cavity; The driving component (200) includes a fence (210), and sliding parts (220) are provided on both sides of the bottom of the fence (210). The sliding parts (220) are slidably engaged with the sliding component (130).

4. The goldfish post-artificial breeding rehabilitation and care device according to claim 1, characterized in that, The inner wall of the cavity is provided with a limiting groove (140), and the partition component (300) is inserted into the limiting groove (140).

5. The goldfish post-artificial breeding rehabilitation and care device according to claim 4, characterized in that, The partition component (300) includes: A baffle (310) is inserted into the limiting groove (140). A seal (320) is wrapped around the outer edge of the baffle (310) to seal the gap between the baffle (310) and the limiting groove (140).

6. The goldfish post-artificial breeding rehabilitation and care device according to any one of claims 1-5, characterized in that, The bottom of the medicated bath area (120) is provided with a drain hole (150), and the drain hole (150) is provided with a detachable filter structure.

7. The goldfish post-artificial breeding rehabilitation and care device according to claim 6, characterized in that, It also includes a temperature control system (400), which is connected to the cavity and is used to control the temperature of the liquid inside the cavity.

8. The goldfish post-artificial breeding rehabilitation and care device according to claim 7, characterized in that, It also includes a lighting system (500) located above the medicinal bath area (120).

9. The goldfish rehabilitation and care device after artificial breeding according to claim 2 or 3, characterized in that, The sliding component (130) includes: The track is located on the inner wall of the cavity and extends from the end of the feeding area (110) away from the bathing area (120) to the end closer to the bathing area (120); A sliding member is slidably disposed on the track, and the driving component (200) is connected to the sliding member.

10. The goldfish post-artificial breeding rehabilitation and care device according to claim 6, characterized in that, The cavity is equipped with an oxygen supply system.