CN116897878A - An automatically controlled temporary care system - Google Patents

Abstract

The application discloses an automatic control temporary rearing system, which comprises the following steps: s1, obtaining the number of temporary rearing barrels required by the cultivation of fresh and alive aquatic products according to a total warehouse performance plan; s2, matching the states of temporary raising barrels in all areas in the store according to the number of the temporary raising barrels required to obtain selected distribution areas; s3, providing temporary rearing barrels in an idle state in a selected distribution area according to the number of the temporary rearing barrels required, and obtaining codes of the idle temporary rearing barrels; s4, according to the water parameters required by cultivation, matching the water supplementing branch pipes of the water parameters in the temporary cultivation barrel, obtaining codes corresponding to the water supplementing branch pipes, opening valves of the coded water supplementing branch pipes, and storing water in the temporary cultivation barrel; s5, water storage is completed, a temporary culture barrel with a required water body is obtained, and the temporary culture barrel is switched into an occupied state, so that the problems that a great deal of time is required for manually inspecting the temporary culture barrel and a water supplementing branch pipe is selected manually and a wrong water supplementing branch pipe is selected are avoided by adopting the technical scheme.

Description

An automatically controlled temporary care system

Technical field

The invention relates to the technical field of aquatic equipment control systems, and in particular to an automatically controlled temporary breeding system.

Background technique

In the new retail industry, the main warehouse delivers fresh aquatic products to each major store in a centralized manner according to the needs of each major store (divided into different regions). Each major store receives a large amount of fresh aquatic products delivered by the main warehouse, and then distributes the fresh aquatic products. Live aquatic products are cultured temporarily in temporary culture barrels in the aquaculture temporary culture system (temporary culture), and then the corresponding fresh aquatic products are delivered to the customer's designated location according to the corresponding customer's replenishment needs.

The purpose of temporary breeding in major stores is to reduce the activity of fresh aquatic products, adapt the fresh aquatic products to the high-density breeding environment, and prepare for subsequent distribution. Achieve high-density temporary cultivation within a certain water body space. After being raised for a long time, fresh aquatic products can eliminate feces and urine, strengthen muscles, and improve meat quality and physical fitness to adapt to high-density, long-distance, and long-term distribution environments, which is inevitable for the transportation and distribution of fresh aquatic products. stage. Therefore, temporary raising is an important link to improve the survival rate of distribution, improve the vitality of aquatic products, and maintain the delicious meat quality.

Different fresh aquatic products require different water environment temperatures depending on the water areas and water depths they live in. They can be divided into high-temperature culture (22°-25°), medium-temperature culture (19°-22°) and low-temperature culture. (14°-19°), etc. The specific temperature is adjusted according to actual needs. The existing distribution center only uses a unified temperature to control the water quality. Most fresh aquatic products cannot adapt to the living environment of a unified temperature control, and it is easy to cause damage to fresh aquatic products. death; in addition, fresh aquatic products have different salinity levels in the water environment depending on the water area and water depth in which they live, such as sea water, semi-sea water, fresh water, etc. Therefore, it is necessary to supply different fresh aquatic products according to different temperatures and different water qualities. Currently, major stores mainly use manual inspection to determine whether the temporary storage bucket is free, which takes a lot of time; and by manually selecting the water replenishment branch pipe, and then opening the selected water replenishment branch pipe valve to store water in the temporary storage bucket, a choice will appear The phenomenon of incorrect water replenishment branch pipes makes the fresh aquatic products unable to adapt to the water body, resulting in the death of fresh aquatic products; in addition, the valve of the water replenishment branch pipes cannot be manually opened to control the amount of water stored in the temporary culture barrel.

Contents of the invention

For this reason, it is necessary to provide an automatically controlled temporary culture system to solve the problem that it takes a lot of time to patrol the temporary culture barrels and manually select the wrong water supply branch pipe.

In order to achieve the above object, the present invention provides an automatically controlled temporary maintenance system, which includes the following steps:

S1. Obtain the number of temporary breeding barrels required for breeding fresh aquatic products and the water parameters required for breeding according to the main warehouse's contract performance plan;

S2. Match the temporary storage bucket status of each area in the store according to the number of required temporary storage buckets, and obtain the selected distribution area;

S3. Provide idle temporary storage buckets in the selected distribution area according to the number of required temporary storage buckets, and obtain the code of the idle temporary storage bucket;

S4. Match the water replenishment branch pipes of each water body parameter in the temporary breeding bucket according to the water body parameters required for breeding, obtain the code of the corresponding water replenishment branch pipe, open the valve of the water replenishment branch pipe with the code, and store water in the temporary breeding bucket;

S5. Complete the water storage, obtain the temporary storage bucket with the required water body, and switch the temporary storage bucket to the occupied state.

Further, it also includes step S6, which step S6 includes opening the valve of the coded water replenishment branch pipe and the return water branch pipe corresponding to the water replenishment branch pipe after temporarily cultivating the fresh aquatic products in the temporary cultivation barrel. The flow rate of the valve of the water supply branch pipe is the same as the flow rate of the valve of the return water branch pipe.

Further, it also includes step S7. The step S7 includes draining the water body in the temporary breeding bucket after taking out all the fresh aquatic products, and switching the temporary breeding bucket to an idle state.

Further, the step S1 also includes obtaining the stores distributed by the general warehouse according to the general warehouse fulfillment plan.

Further, the step S2 includes:

S21. Obtain the total number of free temporary storage buckets in each area of the store;

S22. Determine one by one whether the number of required temporary culture buckets is less than or equal to the total number of idle temporary culture buckets in each area; if the number of required temporary culture buckets is less than or equal to the total number of idle temporary culture buckets in a certain area, then the area is Deliverable area, obtain the total deliverable area of the store;

S23. Select a delivery area from the total deliverable areas of the store to obtain the selected delivery area.

Further, the step S4 includes:

S41. Obtain the water body parameters of each water supply tributary pipe in the temporary breeding barrel in the store;

S42. Compare whether the water body parameters required for breeding are the same as the water body parameters of each water supply branch pipe; if they are the same, stop the comparison and output the code of the water supply branch pipe; otherwise, continue the comparison;

S43. Open the valve of the water supply branch pipe of the code and store water in the temporary breeding barrel.

Further, the step S4 also includes obtaining the water volume required for breeding according to the master warehouse's contract performance plan, and controlling the water storage volume in the temporary breeding barrel according to the water volume required for breeding.

Further, controlling the amount of water stored in the holding tank in step S4 includes setting the valve flow rate of the coded water replenishment branch pipe and the valve opening time;

That is, water volume = valve flow rate * time.

Further, the water parameters required for breeding include water temperature and water type.

Further, the water temperature includes low temperature, medium temperature and high temperature; the water type includes sea water, semi-sea water and fresh water.

Different from the existing technology, the above technical solution automatically obtains the status of the temporary breeding barrels in each area and selects the distribution area; then provides the temporary breeding barrels in the idle state in the selected distribution area, and then automatically matches them according to the water parameters required for breeding. Open the valve of the water replenishing branch pipe and store water in the temporary breeding bucket to avoid the problem of manually inspecting the temporary breeding bucket, which takes a lot of time, and manually selecting the wrong water replenishing branch pipe.

Description of the drawings

Figure 1 is a flow chart of an automatically controlled temporary care system of the present invention;

Figure 2 is a schematic plan view of a water supply system suitable for a temporary cultivation system of different aquatic products according to the specific embodiment;

Figure 3 is an enlarged schematic diagram of position C in Figure 2;

Figure 4 is a schematic plan view of the backwater system of a temporary cultivation system suitable for different aquatic products according to the specific embodiment;

Figure 5 is an enlarged schematic diagram of D in Figure 4;

Figure 6 is a schematic diagram of the water inlet and outlet structure of a temporary breeding barrel suitable for a temporary breeding system for different aquatic products according to the specific embodiment.

Explanation of reference symbols:

101. High temperature reservoir;

102. Medium temperature reservoir;

103. Low temperature reservoir;

104. High-temperature semi-seawater pool;

105. Medium temperature semi-seawater pool;

106. Low-temperature semi-seawater pool;

107. High temperature fresh water pool;

108. Medium temperature fresh water pool;

109. Low-temperature freshwater pool;

20. Filter tank;

30. Temporary storage bucket;

301. Temporary support;

401. Main circulation water pump;

402. Water supply pump;

403. One-way valve;

404. Water supply supervisor;

405. Water supply branch pipe;

406. Water supply tributary pipe;

50. Evaporator;

601. Filter;

602. Protein water supply pump;

603. Protein skimmer;

604. Germicidal lamp;

701. Water supply pipe;

702. Automatic water replenishment valve;

801. Return water supervisor;

802. Return water branch pipe;

803. Backwater tributary pipe;

804. Overflow;

805. Water tank.

Detailed ways

In order to explain in detail the technical content, structural features, achieved objectives and effects of the technical solution, the following will be described in detail with reference to specific embodiments and accompanying drawings.

Reference herein to "an embodiment" means that a particular feature, structure or characteristic described in connection with the embodiment can be included in at least one embodiment of the present application. The word "embodiment" appearing in various places in the specification does not necessarily refer to the same embodiment, nor does it specifically limit its independence or correlation with other embodiments. In principle, in this application, as long as there is no technical contradiction or conflict, the technical features mentioned in each embodiment can be combined in any way to form a corresponding implementable technical solution.

Unless otherwise defined, the technical terms used in this article have the same meanings as commonly understood by those skilled in the technical field to which this application belongs; the use of relevant terms in this article is only to describe specific embodiments and is not intended to limit this application. .

In the description of this application, the term "and/or" is an expression used to describe the logical relationship between objects, indicating that there can be three relationships, such as A and/or B, indicating: A exists, B exists, and both exist at the same time. There are three situations A and B. In addition, the character "/" in this article generally indicates that the related objects are a type of "or" logical relationship.

In this application, terms such as "first" and "second" are only used to distinguish one entity or operation from another entity or operation and do not necessarily require or imply that there exists a relationship between these entities or operations. Any actual quantity, priority or sequence relationship.

Without further limitation, in this application, the terms “includes,” “includes,” “has,” or other similar expressions used in the statements are intended to cover non-exclusive inclusion, and these expressions do not exclude Additional elements may also be present in a process, method, or product that includes stated elements, such that a process, method, or product that includes a list of elements may include not only those defined elements, but also other elements not expressly listed. , or also includes elements inherent to the process, method or product.

The same understanding as in the "Examination Guidelines", in this application, expressions such as "greater than", "less than" and "exceeding" are understood to exclude the number; expressions such as "above", "below" and "within" are understood to include Original number. In addition, in the description of the embodiments of this application, the meaning of "multiple" is two or more (including two), and similar expressions related to "multiple" are also understood in this way, such as "multiple groups", "multiple groups" "Multiple times" etc., unless otherwise expressly and specifically limited.

In the description of the embodiments of this application, space-related expressions are used, such as "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", "back" "Left", "right", "vertical", "horizontal", "vertical", "top", "bottom", "inside", "outside", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc., so The indicated orientation or positional relationship is based on the specific embodiment or the orientation or positional relationship shown in the drawings. It is only to facilitate the description of the specific embodiment of the present application or to facilitate the reader's understanding. It does not indicate or imply that the device or component indicated must be Having a specific location, a specific orientation, or being constructed or operated in a specific orientation should not be construed as limiting the embodiments of the present application.

Unless otherwise explicitly stipulated or limited, in the description of the embodiments of this application, terms such as "installation," "connection," "connection," "fixing," and "setting" should be understood in a broad sense. For example, the "connection" can be a fixed connection, a detachable connection, or an integrated connection; it can be a mechanical connection, an electrical connection, or a communication connection; it can be a direct connection, or it can be a communication connection. Indirect connection through an intermediary; it can be an internal connection between two elements or an interactive relationship between two elements. For those skilled in the technical field to which this application belongs, the specific meanings of the above terms in the embodiments of this application can be understood according to specific circumstances.

Referring to Figure 1, the present invention provides an automatically controlled temporary maintenance system. By automatically obtaining the status of the temporary maintenance buckets 30 in each area, a distribution area is selected; and then the temporary maintenance buckets in an idle state are provided in the selected distribution area. 30. Then automatically match the water replenishment branch pipe 406 according to the water body parameters required for breeding, open the valve of the water replenishment branch pipe 406, and store water in the temporary breeding bucket 30, so as to avoid the manual inspection of the temporary breeding bucket 30, which requires a lot of time and manual selection of water replenishment. The branch pipe 406 may cause the problem of selecting the wrong water replenishing branch pipe 406 .

The implementation of the present invention includes the following steps:

S1. Obtain the number of 30 temporary breeding barrels required for breeding fresh aquatic products and the water parameters required for breeding according to the main warehouse's contract performance plan;

S2. Match the status of the temporary storage buckets 30 in each area of the store according to the required number of temporary storage buckets 30, and obtain the selected distribution area;

S3. Provide idle temporary cultivation buckets 30 in the selected distribution area according to the number of required temporary cultivation buckets 30, and obtain the code of the idle temporary cultivation bucket 30;

S4. Match the water replenishment branch pipe 406 (belonging to the water supply system) of each water body parameter in the temporary breeding bucket 30 according to the water body parameters required for breeding, obtain the code of the corresponding water replenishment branch pipe 406, open the valve of the water replenishment branch pipe 406 of the code, and go to Water is stored in the temporary breeding barrel for 30 seconds;

S5. Complete water storage, obtain the temporary storage bucket 30 with the required water body, and switch the temporary storage bucket 30 to the occupied state.

The above-mentioned stores are the stores distributed by the general warehouse in the general warehouse fulfillment plan; the above-mentioned water parameters required for breeding can include but are not limited to water temperature and water type. The water temperature may include low temperature, medium temperature and high temperature (high temperature means the water quality temperature is controlled at 22°-25°, medium temperature means the water quality temperature is controlled at 19°-22°, and low temperature means the water quality temperature is controlled at 14°-19°); so The above-mentioned water body types are also divided into various types due to different proportions of salt components, including but not limited to sea water, semi-sea water, fresh water, etc. In this embodiment, sea water, semi-sea water, and fresh water are used as examples to further elaborate on this embodiment, which is helpful to To further understand the present invention, the water body parameters may include high-temperature seawater, medium-temperature seawater, low-temperature seawater, high-temperature semi-seawater, medium-temperature semi-seawater, low-temperature semi-seawater, high-temperature fresh water, medium-temperature fresh water, and low-temperature fresh water. The water supply branch pipes 406 are numbered one by one according to the above-mentioned outflow water parameters.

The above embodiment may also include step S6. The step S6 includes temporarily raising the fresh aquatic products in the temporary breeding barrel 30, and then opening the valve of the coded water replenishment branch pipe 406 (belonging to the water supply system) and the water replenishment branch pipe. 406 (belonging to the return water system) corresponds to the valve of the return water branch pipe 803. The flow rate of the valve of the water supplement branch pipe 406 is the same as the flow rate of the valve of the return water branch pipe 803. The water supply system will separately flow the water in each reservoir into the temporary breeding barrel 30 through the water replenishment branch pipe 406. The water return system will recycle the overflow water from the temporary cultivation barrel 30 to the corresponding filter tank through the water replenishment branch pipe 406, and then recycle the water in the filter tank. The main circulation water pump returns to the corresponding reservoir to form an aquaculture temporary cultivation circulating water system.

The above embodiment may also include step S7, which includes draining the water body in the temporary breeding barrel 30 after all the fresh aquatic products are taken out, and switching the temporary breeding barrel 30 to an idle state. The temporary cultivation bucket 30 completes water storage and switches to the occupied state. The water body of the temporary cultivation bucket 30 is drained and switches to the idle state. The status switching of the temporary cultivation bucket 30 is realized, which provides a prerequisite for automatically obtaining the status of the temporary cultivation bucket 30 in each area.

The specific implementation of step S2 includes:

S21. Obtain the total number of 30 free temporary storage buckets in each area of the store;

S22. Determine one by one whether the number of required temporary cultivation buckets 30 is less than or equal to the total number of 30 idle temporary cultivation buckets in each region; if the number of required temporary cultivation buckets 30 is less than or equal to the total number of 30 idle temporary cultivation buckets in a certain region, Then this area is the deliverable area, and the total deliverable area of the store is obtained;

S23. Select a delivery area from the total deliverable areas of the store to obtain the selected delivery area.

The specific implementation of step S4 includes:

S41. Obtain the water body parameters of each water supply branch pipe 406 in the temporary breeding barrel 30 in the store;

S42. Compare whether the water body parameters required for breeding are the same as the water body parameters of each water supply branch pipe 406; if they are the same, stop the comparison and output the code of the water supply branch pipe 406; otherwise, continue the comparison;

S43. Open the valve of the water supply branch pipe 406 of the code and store water in the temporary breeding barrel 30.

The above-mentioned step S4 also includes obtaining the water volume required for breeding according to the contract performance plan of the main warehouse, and controlling the water storage volume in the temporary breeding barrel 30 according to the water volume required for breeding. The specific implementation includes setting the valve flow rate and valve opening time of the coded water supply branch pipe 406;

That is, the amount of water stored in the temporary breeding barrel 30 = the amount of water in the water body = the flow rate of the valve * time.

In order to further elaborate on the present invention, a temporary cultivation system suitable for different aquatic products is provided by applying the above-mentioned automatic controlled temporary cultivation system.

Referring to Figures 2 to 6, this embodiment provides a temporary culture system suitable for different aquatic products, which includes several rows of temporary culture barrels, a return water system, a water supply system, several reservoirs and corresponding to each reservoir. A filter tank 20 is provided; several reservoirs include reservoirs with different water qualities and different temperatures corresponding to each water quality; each reservoir provides a temperature-adapted water environment for different fresh aquatic products, and the filter pond The water in 20 is passed into the corresponding reservoirs through the main circulation water pump; each row of temporary cultivation barrels has several temporary cultivation barrels 30; the water supply system will separately pass the water in each reservoir into the temporary cultivation barrels 30, and return them to the temporary cultivation barrels 30. The water system recycles the water overflowing from the temporary cultivation barrel 30 to the corresponding filter tank 20, and then flows back into the corresponding reservoir through the main circulation water pump 401 to form an aquatic product temporary cultivation circulating water system; in which the water supply system passes through the water supply pump 402 Pump the water from each reservoir 101, 102, 103, 104, 105, 106, 107, 108, 109 to the water supply main pipe 404, and then flow through the water supply branch pipe 405 to the water supply branch pipe 406 of each temporary breeding barrel 30 , water of different temperatures can be replaced by switching the valve of the water replenishing branch pipe 406; an overflow port 804 is set at a high position of the temporary maintenance barrel 30, and the water is recovered to the return water branch pipe 803 through the water receiving tank 805, and is formed by the pressure difference The natural backflow causes the water in the temporary breeding barrel 30 to flow back into the corresponding filter tank 20, thereby solving the problem that the existing aquatic product temporary breeding circulating water system uniformly temperature-controls the water environment of fresh aquatic products and easily causes the death of fresh aquatic products. , to meet the temperature requirements of different water environments for a variety of fresh aquatic products. The above-mentioned water receiving tank 805 is preferably funnel-shaped to facilitate the flow of water into the return water branch pipe 803.

In the specific implementation of this embodiment, several reservoirs include reservoirs with different water qualities and different temperatures corresponding to each water quality, that is, each water quality has reservoirs with multiple temperatures, such as high temperature, medium temperature and low temperature. (High temperature means the water quality temperature is controlled at 22°-25°, medium temperature means the water quality temperature is controlled at 19°-22°, and low temperature means the water quality temperature is controlled at 14°-19°). Water quality is also divided into multiple categories due to the different proportions of salt components. species, including but not limited to seawater, semi-seawater, fresh water, etc. In this embodiment, seawater, semi-seawater, and freshwater are used as examples to further illustrate this embodiment. The plurality of reservoirs include high-temperature seawater pool 101, medium-temperature seawater pool 102, low-temperature seawater pool 102, and low-temperature seawater pool 102. Seawater pool 103, high temperature semi-seawater pool 104, medium temperature half seawater pool 105, low temperature half seawater pool 106, high temperature freshwater pool 107, medium temperature freshwater pool 108, low temperature freshwater pool 109, each of which has a heater and a temperature The control unit and the heater heat the water in the reservoir, and the temperature control unit controls the temperature of the water in the reservoir to maintain a constant required temperature (this is existing technology and will not be described in detail here). The water in the filter pool 20 is passed into each corresponding reservoir 101, 102, 103, 104, 105, 106, 107, 108, 109 through the main circulation water pump 401; in this embodiment, the main circulation water pump 401 has Two, their model number is PA-25000.

The water supply system includes a water supply pump 402, a water supply main pipe 404, a water supply branch pipe 405 and a water supply branch pipe 406 corresponding to each reservoir 101, 102, 103, 104, 105, 106, 107, 108, 109; The water supply main pipe 404 is connected to the corresponding reservoir through the water supply pump 402; the water supply branch pipes 405 are arranged in parallel above each row of temporary breeding barrels 30, and are connected to the water supply main pipe 404 of the corresponding filter tank 20; each water supply branch pipe 405 corresponds to Each temporary culture bucket 30 is connected to a corresponding water supply branch pipe 406 . The water supply branch pipe 406 is provided with a valve, and the bottom of the water supply branch pipe 406 extends into the bottom of the temporary culture bucket 30 . The above-mentioned water supply branch pipes 405 are preferably parallel to the length direction of the row of temporary cultivation barrels 30, so as to reduce the layout length of the water supply branch pipes 405, thereby reducing the layout cost of the water supply branch pipes 405. In order to further reduce the cost of laying out the water supply branch pipes 405, two adjacent rows of temporary cultivation barrels 30 in several rows of temporary cultivation barrels 30 can be arranged opposite each other. The water supply branch pipes 405 are arranged side by side above the two adjacent rows of temporary cultivation barrels 30 to provide water. The branch pipe 405 is connected to the water supply branch pipe 406 corresponding to each temporary cultivation bucket 30 of two adjacent rows of temporary cultivation buckets 30. That is, the two adjacent rows of temporary cultivation buckets 30 share a water supply branch pipe 405, which reduces the cost of pipe network layout. Of course, a one-way valve 403 can also be provided between the main water supply pipe 404 and the corresponding reservoir to prevent the water in the water supply pipe from flowing back into the reservoir. Each of the above-mentioned temporary cultivation barrels 30 can have two temporary cultivation compartments 301 , the water supply branch pipes 406 respectively extend into the two temporary cages and extend into the bottom of the temporary cage 301.

The return water system includes a return water main pipe 801, a return water branch pipe 802 and a return water branch pipe 803 corresponding to each filter tank 20; an overflow port 804 is provided outward on the side wall of the temporary storage barrel 30, so The water outlet of the overflow port 804 is provided with a water receiving tank 805, and the return water branch pipes 803 are respectively provided with valves, one end of which is connected to the bottom of the water tank; the other end is connected to the return water branch pipe 802 of the corresponding filter tank 20; each filter tank The return water branch pipes 802 are arranged in parallel on one side of each row of temporary cultivation barrels 30 and are connected to the corresponding return water main pipe 801; the return water main pipe 801 is connected to the corresponding filter tank 20. The above-mentioned return water branch pipe 802 is preferably parallel to the length direction of the row of temporary cultivation barrels 30, thereby reducing the layout length of the return water branch pipe 802, thereby reducing the layout cost of the return water branch pipe 802. Similarly, in order to further reduce the cost of laying out the return water branch pipes 802, two adjacent rows of temporary cultivation barrels 30 in several rows of temporary cultivation barrels 30 can be arranged opposite each other, and the return water branch pipes 802 are arranged side by side between the two adjacent rows of temporary cultivation barrels 30. In between, the overflow ports 804 of two adjacent rows of temporary raising barrels 30 are arranged correspondingly to each other. A water receiving tank 805 is provided between the adjacent temporary raising barrels 30. The overflow ports 804 of the adjacent temporary raising barrels 30 flow into the water receiving tank 805. The bottom of the water receiving tank 805 is connected to the return water branch pipe 803, that is, two adjacent rows of temporary cultivation barrels 30 share a water supply branch pipe 405, which reduces the cost of laying out the pipe network. Of course, the plurality of water receiving tanks 805 can be replaced by one water receiving tank 805 with a length. The length of the water receiving tank 805 specifically means that the width of the water receiving tank 805 is smaller than the distance between two adjacent rows of temporary maintenance barrels 30 , and the length of the water receiving tank 805 satisfies The water from the overflow port 804 of the first adjacent temporary cultivation barrel 30 and the last adjacent temporary cultivation barrel 30 can flow into the water receiving tank 805, which can reduce the number of return water branch pipes 803 arranged at the bottom of the water receiving tank 805 and reduce backwater. The cost of laying out the branch pipe 803.

In order to purify the recycled water of the return water system, a filter screen 601 can be provided in the above-mentioned filter pool 20. The filter screen 601 divides the filter pool 20 into filter pool A area and filter pool B area; the return water main pipe 801 is connected In the corresponding filter pool A area; the water in the filter pool area B is passed into each corresponding reservoir 101, 102, 103, 104, 105, 106, 107, 108, 109 through the main circulation water pump 401. The recycled water flowing in from the backwater main pipe 801 of the return water system flows into the filter tank A area. The filter screen 601 filters out the larger impurities (such as scales, fresh aquatic product excrement, etc.) in the recycled water, that is, they are retained in the filter tank. In the pool A area, the recycled water that has been filtered out larger impurities through the filter screen 601 enters the filter pool area B.

In order to further purify the recycled water, a purification system can also be set up in area B of the filter pool. The purification system includes a protein water supply pump 602, a protein separator 603 and a sterilization lamp 604. The protein water supply pump 602 separates the water in area B of the filter pool. The water is pumped into the protein separator 603, and then flows back to area B of the filter pool after passing through the sterilizing lamp 604. The protein water supply pump 602 pumps the water in the filter pool B area into the protein separator 603. The protein separator 603 uses the principle that the bubble surface in the water can adsorb various granular dirt and soluble organic matter mixed in the water. Use oxygenating equipment or a vortex pump to generate a large number of bubbles. These bubbles are all concentrated on the water surface to form foam. The foam that has absorbed dirt is collected in a container on the water surface. It will turn into turbid liquid and be eliminated. The turbid liquid will be removed. The discharged water is sterilized by the germicidal lamp 604 and then returned to area B of the filter pool. In this embodiment, the above-mentioned protein separator 603 is PSK-800 egg skimmer, with a processing capacity of 30T/H; the protein water supply pump 602 has two, and the model is PA-60000; the model of the sterilization lamp 604 is RSUV-D300W, The processing capacity is 30T/H.

The specific implementation of this implementation can also add a refrigeration system. The refrigeration system includes an evaporator 50. The evaporator 50 is preferably a pure titanium evaporator 50. The main circulation water pump 401 extracts the water in the filter pool B area and evaporates it. The device 50 is then connected to each corresponding reservoir 101, 102, 103, 104, 105, 106, 107, 108, 109. The evaporator 50 cools the water in area B of the filter pool and then flows it into the corresponding reservoir. The evaporator 50 and the heater work together to control the temperature of the reservoir to maintain the required temperature. constant temperature. Of course, the heat-exchanged gas in the evaporator 50 can also be used as a heating source in the water reservoir.

The bottom of each of the above-mentioned reservoirs 101, 102, 103, 104, 105, 106, 107, 108, 109 is respectively provided with a water replenishment pipe 701 connected to the filter tank A area, and the water replenishment pipe 701 is provided with an automatic water replenishment valve 702 . The main circulation water pump 401 pumps water from the filter pool 20 and flows into the reservoir after being cooled by the refrigeration system. The water in the reservoir flows out in two ways, and flows all the way to the temporary cultivation barrel 30 to replenish the temporary cultivation barrel 30, and then returns to the filter. Pool 20. On the other hand, when the water in the filter tank 20 is replenished to the temporary storage tank 30, the automatic water replenishment valve 702 will start to replenish the water in the filter tank 20.

It should be noted that although the above-mentioned embodiments have been described herein, this does not limit the scope of patent protection of the present invention. Therefore, based on the innovative concept of the present invention, changes and modifications to the embodiments described herein, or equivalent structures or equivalent process transformations using the contents of the description and drawings of the present invention, directly or indirectly apply the above technical solutions Other related technical fields are included in the protection scope of the patent of the present invention.

Claims (10)

1. An automatically controlled temporary breeding system, characterized by: including the following steps: S1. Obtain the number of temporary breeding barrels required for breeding fresh aquatic products and the water parameters required for breeding according to the main warehouse's contract performance plan; S2. Match the temporary storage bucket status of each area in the store according to the number of required temporary storage buckets, and obtain the selected distribution area; S3. Provide idle temporary storage buckets in the selected distribution area according to the number of required temporary storage buckets, and obtain the code of the idle temporary storage bucket; S4. Match the water replenishment branch pipes of each water body parameter in the temporary breeding bucket according to the water body parameters required for breeding, obtain the code of the corresponding water replenishment branch pipe, open the valve of the water replenishment branch pipe with the code, and store water in the temporary breeding bucket; S5. Complete the water storage, obtain the temporary storage bucket with the required water body, and switch the temporary storage bucket to the occupied state. 2. An automatically controlled temporary breeding system according to claim 1, characterized in that: it also includes step S6, and said step S6 includes temporarily raising the fresh aquatic products in the temporary breeding barrel, opening the The valve of the coded water supply branch pipe and the valve of the return water branch pipe corresponding to the water supply branch pipe, the flow rate of the valve of the water supply branch pipe is the same as the flow rate of the valve of the return water branch pipe. 3. An automatically controlled temporary breeding system according to claim 2, characterized in that: it also includes step S7, which includes draining the water body in the temporary breeding barrel after taking out all the fresh aquatic products. When the storage is exhausted, the temporary storage bucket switches to idle state. 4. An automatically controlled temporary storage system according to claim 1, characterized in that step S1 further includes obtaining the stores distributed by the general warehouse according to the general warehouse fulfillment plan. 5. An automatically controlled temporary care system according to claim 1, characterized in that: the step S2 includes: S21. Obtain the total number of free temporary storage buckets in each area of the store; S22. Determine one by one whether the number of required temporary culture buckets is less than or equal to the total number of idle temporary culture buckets in each area; if the number of required temporary culture buckets is less than or equal to the total number of idle temporary culture buckets in a certain area, then the area is Deliverable area, obtain the total deliverable area of the store; S23. Select a delivery area from the total deliverable areas of the store to obtain the selected delivery area. 6. An automatically controlled temporary care system according to claim 1, characterized in that: the step S4 includes: S41. Obtain the water body parameters of each water supply tributary pipe in the temporary breeding barrel in the store; S42. Compare whether the water body parameters required for breeding are the same as the water body parameters of each water supply branch pipe; if they are the same, stop the comparison and output the code of the water supply branch pipe; otherwise, continue the comparison; S43. Open the valve of the water supply branch pipe of the code and store water in the temporary breeding barrel. 7. An automatically controlled temporary breeding system according to claim 6, characterized in that: the step S4 also includes obtaining the water volume required for breeding according to the contract fulfillment plan of the main warehouse, and controlling the temporary breeding system according to the water volume required for breeding. The amount of water stored in the breeding barrel. 8. An automatically controlled temporary cultivation system according to claim 7, characterized in that: controlling the water storage volume in the temporary maintenance barrel in step S4 includes setting the valve flow rate of the coded water supply branch pipe and the valve opening value. time; That is, water volume = valve flow rate * time. 9. An automatically controlled temporary culture system according to claim 1, characterized in that: the water parameters required for culture include water body temperature and water body type. 10. An automatically controlled temporary cultivation system according to claim 7, characterized in that: the water temperature includes low temperature, medium temperature and high temperature; the water type includes seawater, semi-seawater and fresh water.