CN112243932A - Intelligent temperature control culture pond - Google Patents

Abstract

The invention discloses an intelligent temperature control culture pond, which comprises a culture pond body, a first temperature sensor arranged in the culture pond body and used for detecting water temperature, and a heat exchange pipe set arranged in the culture pond body, wherein a water inlet of the heat exchange pipe set is connected with a hot water pipe, a water outlet of the heat exchange pipe set is connected with a cold water pipe, the hot water pipe is provided with a first water conveying device for conveying hot water into the heat exchange pipe set when the first temperature sensor detects that the water temperature is lower than a first preset temperature, and the cold water pipe is provided with a second water conveying device for conveying cold water into the heat exchange pipe set when the first temperature sensor detects that the water temperature is higher than a second preset temperature. The intelligent temperature-control culture pond provided by the invention not only ensures that the temperature of the culture pond body is maintained within a preset range, but also avoids the phenomenon of electric leakage in the culture pond.

Description

Intelligent temperature control culture pond

Technical Field

The invention relates to the technical field of aquaculture, in particular to an intelligent temperature-control culture pond.

Background

The aquaculture industry is going towards the trend of refinement at present, and different fishes have the best water temperature for life, and the temperature required for tropical fish culture is different from that required for tropical fish culture. Some fishes have high requirements on water temperature, particularly in the seedling stage, once the culture water temperature is not in the living range, a large amount of fishes may die, but the external temperature is unstable, even the change is large, the water temperature of the fish pond is greatly changed along with the change of the external temperature, so the development of the aquaculture industry is restricted, at present, common methods for maintaining the water temperature mainly comprise adding a heating rod and the like into a water body, the range of the water body acted by the heating rod is small, the method is not suitable for large-scale water body culture, the water temperature near the heating rod is high due to the fact that the water temperature is directly placed into the water, the water temperature is low due to the fact that the water is far away from accessories of the heating rod, the water temperature is not uniformly distributed, and the fish herds are easily.

Therefore, how to maintain the temperature of the water body in the culture pond and meet the requirements of different fishes on the temperature of the water body becomes a technical problem to be solved by the technical personnel in the field.

Disclosure of Invention

The invention aims to provide an intelligent temperature-control culture pond, which can ensure that the temperature of a culture pond body is maintained within a preset range and simultaneously avoid the electric leakage phenomenon of the culture pond.

In order to achieve the purpose, the invention provides an intelligent temperature control culture pond, which comprises a culture pond body, a first temperature sensor and a heat exchange pipe set, wherein the first temperature sensor is arranged in the culture pond body and used for detecting water temperature, the heat exchange pipe set is arranged in the culture pond body, a water inlet of the heat exchange pipe set is connected with a hot water pipe, a water outlet of the heat exchange pipe set is connected with a cold water pipe, the hot water pipe is provided with a first water conveying device which conveys hot water into the heat exchange pipe set when the first temperature sensor detects that the water temperature is lower than a first preset temperature, and the cold water pipe is provided with a second water conveying device which conveys cold water into the heat exchange pipe set when the first temperature sensor detects that the water temperature is higher than a second preset.

Optionally, the hot water pipe comprises a hot water inlet pipe and a hot water return pipe which are communicated with each other, the first water delivery device is arranged on the hot water inlet pipe, and a water inlet of the heat exchange pipe set is connected to the hot water inlet pipe;

the cold water pipe comprises a cold water inlet pipe and a cold water return pipe which are mutually communicated, the second water delivery device is arranged on the cold water inlet pipe, and the water outlet of the heat exchange pipe set is connected to the cold water inlet pipe.

Optionally, the system further comprises a hot water pond and a cold water pond which are arranged adjacent to the culture pond body;

the hot water tank is provided with a heating device, and the pipe orifices of the hot water inlet pipe and the hot water return pipe are both arranged in the hot water tank;

the cold water pool is provided with a refrigerator, and the orifices of the cold water inlet pipe and the cold water return pipe are arranged in the cold water pool.

Optionally, the hot water pool is provided with a second temperature sensor, and the heating device starts heating when the second temperature sensor detects that the temperature of the hot water pool is lower than a third preset temperature;

and the cold water pool is provided with a third temperature sensor, and when the third temperature sensor detects that the temperature of the cold water pool is higher than a fourth preset temperature, the refrigerator starts to refrigerate.

Optionally, the hot water return pipe is provided with a first electromagnetic valve, and the cold water return pipe is provided with a second electromagnetic valve; when the first water delivery device is started, the first electromagnetic valve is closed, and the second electromagnetic valve is opened; when the second water delivery device is started, the first electromagnetic valve is opened, and the second electromagnetic valve is closed.

Optionally, the refrigerator further comprises a solar power supply module, and the solar power supply module is connected with the heating device and the refrigerator.

Optionally, the first temperature sensor, the second temperature sensor, and the third temperature sensor are all connected to a data transmission module, and the data transmission module is configured to transmit the temperatures detected by the first temperature sensor, the second temperature sensor, and the third temperature sensor to a display terminal.

Optionally, an insulating layer is attached to the wall of the hot water tank and/or the cold water tank.

Compared with the prior art, the intelligent temperature control culture pond provided by the invention comprises a culture pond body and a heat exchange tube group arranged in the culture pond body, the temperature of water is detected by a temperature sensor arranged in the culture pond body, and when the temperature of the water is lower than a first preset temperature, hot water is introduced into the heat exchange tube group through a first water delivery device and a hot water tube to exchange heat with culture water, so that the temperature of the culture water is raised; when the temperature is higher than a second preset temperature, cold water is conveyed into the heat exchange tube group through the second water conveying device and the cold water pipe, and exchanges heat with culture water, so that the temperature of the culture water is reduced. Therefore, the water temperature in the culture pond body is maintained within a preset range, namely is higher than the first preset temperature and is lower than the second preset temperature, the risk of electric leakage caused by direct heating of a heating rod and the like is avoided, and the constant water temperature of the culture pond body is favorably maintained.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic view of an intelligent temperature-controlled culture pond provided by an embodiment of the invention.

Wherein:

the system comprises a solar cell panel 1, a storage battery 2, a standby battery 3, a heating device 4, a hot water tank 5, a hot water inlet pipe 51, a hot water return pipe 52, a first electromagnetic valve 53, a first water delivery device 54, a refrigerating machine 6, a cold water tank 7, a cold water inlet pipe 71, a cold water return pipe 72, a cold water return pipe 73, a second electromagnetic valve 74, a second water delivery device 8, a heat exchange pipe group 9, a culture tank body 10, a first temperature sensor 11, a second temperature sensor 11 and a third temperature sensor 12.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order that those skilled in the art will better understand the disclosure, the invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1, fig. 1 is a schematic view of an intelligent temperature-controlled culture pond according to an embodiment of the present invention.

In a specific embodiment provided by the invention, the intelligent temperature control culture pond comprises a culture pond body 9, and a first temperature sensor 10 and a heat exchange tube group 8 which are arranged in the culture pond body 9. The water inlet and the water outlet of the heat exchange tube group 8 are respectively connected with a hot water pipe and a cold water pipe. If the optimum culture temperature range of a certain fish is between a first preset temperature and a second preset temperature, wherein the first preset temperature is lower than the second preset temperature, when the first temperature sensor 10 detects that the temperature of water in the culture pond body 9 is lower than the first preset temperature, the first water delivery device 54 is controlled to deliver hot water into the heat exchange tube group 8, the hot water is output from the cold water pipe after being subjected to heat exchange with the water in the culture pond body 9, and when the first temperature sensor 10 detects that the temperature of the water in the culture pond body 9 rises to exceed the first preset temperature, the first water delivery device 54 is controlled to stop delivering water; similarly, when the first temperature sensor 10 detects that the temperature of the water in the culture pond body 9 is higher than the second preset temperature, the second water delivery device 74 is controlled to deliver cold water into the heat exchange tube group 8, the cold water and the water in the culture pond body 9 are subjected to heat exchange and then discharged from the hot water tube, and when the temperature of the water in the culture pond body 9 is reduced to the second preset temperature or lower, the second water delivery device 74 stops running.

In order to improve the reliability of the temperature detected by the first temperature sensors 10, the first temperature sensors 10 may be arranged in multiple groups, the multiple groups of first temperature sensors 10 are respectively arranged at the center of the culture pond body 9 and near the pond wall, all the first temperature sensors 10 are connected to an operation processing module (such as a computer, a single chip microcomputer, etc.), and the operation processing module is used for calculating the average value of the detected temperatures of all the first temperature sensors 10, so as to control the first water delivery device 54 and the second water delivery device 74 to operate.

In addition, the first temperature sensors 10 and the heat exchange tube sets 8 can be arranged in a one-to-one correspondence manner, and when the first temperature sensors 10 arranged in a certain area of the culture pond body 9 detect that the water temperature in the area exceeds a preset range, the first water delivery device 54 and the second water delivery device 74 deliver water to the heat exchange tube sets 8 in the area. The heat exchange tube group 8 can be a semi-elliptical tube group as shown in the figure, and can also be a serpentine tube group, so that the water inlet and the water outlet of the heat exchange tube group are respectively connected with a hot water pipe and a cold water pipe.

Optionally, the intelligent temperature-controlled culture pond provided by the invention further comprises a hot water pond 5 and a cold water pond 7 which are arranged adjacent to the culture pond body 9, the hot water pond 5 supplies hot water into the heat exchange tube group 8 through a first water conveying device 54, and the cold water pond 7 supplies cold water into the heat exchange tube group 8 through a second water conveying device 74. The arrangement of the hot water pipe and the cold water pipe can refer to fig. 1, the hot water pipe comprises a hot water inlet pipe 51 and a hot water return pipe 52 which are communicated with each other, two ends of the hot water pipe, namely pipe orifices of the hot water inlet pipe 51 and the hot water return pipe 52, are both placed in the hot water pool 5, the first water delivery device 54 is connected to the hot water inlet pipe 51, and water inlets of all the heat exchange pipe groups 8 are also connected to the hot water inlet pipe 51; the cold water pipe comprises a cold water inlet pipe 71 and a cold water return pipe 72 which are connected with each other, the two ends of the cold water pipe, namely the pipe orifices of the cold water inlet pipe 71 and the cold water return pipe 72, are all placed in cold water, the second water conveying device 74 is connected with the cold water inlet pipe 71, and the water outlets of all the heat exchange pipe groups 8 are all connected with the cold water inlet pipe 71. The first water delivery device 54 and the second water delivery device 74 may specifically employ electric water pumps.

When the first water delivery device 54 delivers water to the heat exchange tube set 8 to heat water in the culture pond 9, most of the hot water enters the heat exchange tube set 8 through the hot water inlet tube 51, and is discharged to the cold water pond 7 from the cold water return tube 72 after heat exchange and temperature reduction, and part of the hot water directly flows back to the hot water pond 5 through the hot water return tube 52 without passing through the heat exchange tube set 8. When the second water conveying device 74 conveys water to the heat exchange tube group 8 to cool the water in the culture pond body 9, most of cold water enters the heat exchange tube group 8 through the cold water inlet tube 71, is discharged to the hot water pond 5 from the hot water return tube 52 after heat exchange and temperature rise, and part of cold water directly flows back to the cold water pond 7 through the cold water return tube 72 without passing through the heat exchange tube group 8. A connecting pipe is also arranged between the hot water tank 5 and the cold water tank 7, and the connecting pipe is used for supplementing water to the side with reduced water quantity.

In order to optimize the above embodiments, in the preferred embodiment of the present invention, a first electromagnetic valve 53 is further disposed on the hot water return pipe 52, a second electromagnetic valve 73 is disposed on the cold water return pipe 72, the first electromagnetic valve 53 and the second electromagnetic valve 73 are connected and controlled by a control mechanism, and the control mechanism may adopt a single chip microcomputer or the like. The control mechanism is used for controlling the first electromagnetic valve 53 to be closed when the first water delivery device 54 is started, and simultaneously controlling the second electromagnetic valve 73 to be opened, so that all hot water flows to the heat exchange tube group 8 and flows to the cold water pool 7 from the cold water return pipe 72; when the second water delivery device 74 is started, the control mechanism also controls the second electromagnetic valve 73 to be closed, and the first electromagnetic valve 53 is opened, so that the cold water flows to the heat exchange tube group 8 from the cold water inlet pipe 71 and flows to the heating pool through the hot water return pipe 52.

Set up heating device 4 in the hot-water tank 5, heating device 4 specifically adopts electrical heating ring or electrical heating rod, and cold water tank 7 sets up refrigerator 6, and refrigerator 6 can adopt the compressor refrigeration to cool the water in the cold water tank 7. In order to maintain the temperature of the hot water tank 5 and the cold water tank 7, a second temperature sensor 11 is further provided in the hot water tank 5, and a third temperature sensor 12 is provided in the cold water tank 7. When the second temperature sensor 11 detects that the water temperature of the hot water pool 5 is reduced below a third preset temperature, the heating device 4 is controlled to start heating; when the third temperature sensor 12 detects that the temperature of the cold water pool 7 rises above a fourth preset temperature, the refrigerator 6 is controlled to start running. Generally speaking, the third preset temperature is greater than the second preset temperature, and the fourth preset temperature is less than the first preset temperature, so as to ensure the heat exchange effect between the hot water delivered by the hot water tank 5 and the water in the culture tank 9, and the heat exchange effect between the cold water delivered by the cold water tank 7 and the water in the culture tank 9, so as to maintain the water temperature of the culture tank 9 between the first preset temperature and the second preset temperature. The bottom and the wall of the cold water tank 7 and the hot water tank 5 are usually provided with an insulating layer, and the insulating layer can be a foam layer. In addition, the pipe walls of the hot water pipe, the cold water pipe and other pipelines are also coated or attached with the heat-insulating layer, so that less hot water or cold water exchanges heat with the outside air in the conveying process.

Still including the display terminal who is used for monitoring breed cell body 9, hot- water tank 5 and 7 temperature in cold water pond, display terminal can be cell-phone, panel or computer equipment, and output transmission module is connected to first temperature sensor 10, second temperature sensor 11 and third temperature sensor 12, sends the temperature parameter who detects for display terminal through data transmission module to the implementation detects the temperature of breeding cell body 9, hot-water tank 5 and cold water pond 7.

Furthermore, in order to reduce energy consumption, the invention also provides a solar power supply module, the solar power supply module comprises a solar cell panel 1 and a storage battery 2 connected with the solar cell panel 1, electric energy in the cooling process and the heating process of the culture tank body 9 mainly comes from the solar cell panel 1, when the solar cell panel 1 irradiates the solar cell panel 1, the solar cell panel 1 converts solar energy into electric energy and stores the electric energy in the storage battery 2, and meanwhile, a standby battery 3 is arranged, the standby battery 3 can be charged through the solar cell panel 1 or connected into a power grid for standby charging, when the electric energy in the storage battery 2 is insufficient in long-time rainy days, the standby battery 3 replaces the storage battery 2 to supply power for the whole heating device 4, the refrigerator 6 and the like.

It is noted that, in this specification, relational terms such as first and second, and the like are used solely to distinguish one entity from another entity without necessarily requiring or implying any actual such relationship or order between such entities.

The intelligent temperature-control culture pond provided by the invention is described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the method and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (8)

1. The intelligent temperature control culture pond is characterized by comprising a culture pond body (9), a first temperature sensor (10) arranged in the culture pond body (9) and used for detecting water temperature, and a heat exchange pipe set (8) arranged in the culture pond body (9), wherein a water inlet of the heat exchange pipe set (8) is connected with a hot water pipe, a water outlet of the heat exchange pipe set (8) is connected with a cold water pipe, the hot water pipe is provided with a first water conveying device (54) which conveys hot water into the heat exchange pipe set (8) when the first temperature sensor (10) detects that the water temperature is lower than a first preset temperature, and the cold water pipe is provided with a second water conveying device (74) which conveys cold water into the heat exchange pipe set (8) when the first temperature sensor (10) detects that the water temperature is higher than a second preset temperature.

2. The intelligent temperature-controlled culture pond according to claim 1, wherein the hot water pipe comprises a hot water inlet pipe (51) and a hot water return pipe (52) which are communicated with each other, the first water delivery device (54) is arranged on the hot water inlet pipe (51), and the water inlet of the heat exchange pipe set (8) is connected to the hot water inlet pipe (51);

the cold water pipe comprises a cold water inlet pipe (71) and a cold water return pipe (72) which are communicated with each other, the second water conveying device (74) is arranged on the cold water inlet pipe (71), and a water outlet of the heat exchange pipe set (8) is connected to the cold water inlet pipe (71).

3. The intelligent temperature-controlled culture pond according to claim 2, further comprising a hot water pond (5) and a cold water pond (7) which are arranged adjacent to the culture pond body (9);

the hot water pool (5) is provided with a heating device (4), and the pipe orifices of the hot water inlet pipe (51) and the hot water return pipe (52) are arranged in the hot water pool (5);

the cold water tank (7) is provided with a refrigerator (6), and the orifices of the cold water inlet pipe (71) and the cold water return pipe (72) are arranged in the cold water tank (7).

4. The intelligent temperature-controlled culture pond according to claim 3, wherein the hot water pond (5) is provided with a second temperature sensor (11), and the heating device (4) starts heating when the second temperature sensor (11) detects that the temperature of the hot water pond (5) is lower than a third preset temperature;

the cold water pool (7) is provided with a third temperature sensor (12), the third temperature sensor (12) detects that when the temperature of the cold water pool (7) is higher than a fourth preset temperature, the refrigerator (6) starts to refrigerate.

5. The intelligent temperature-controlled culture pond according to claim 4, wherein the hot water return pipe (52) is provided with a first electromagnetic valve (53), and the cold water return pipe (72) is provided with a second electromagnetic valve (73); when the first water delivery device (54) is started, the first electromagnetic valve (53) is closed, and the second electromagnetic valve (73) is opened; when the second water delivery device (74) is started, the first electromagnetic valve (53) is opened, and the second electromagnetic valve (73) is closed.

6. The intelligent temperature-controlled culture pond according to any one of claims 3 to 5, further comprising a solar power supply module, wherein the solar power supply module is connected with the heating device (4) and the refrigerating machine (6).

7. The intelligent temperature-controlled culture pond according to claim 4, wherein the first temperature sensor (10), the second temperature sensor (11) and the third temperature sensor (12) are all connected with a data transmission module, and the data transmission module is used for transmitting the temperatures detected by the first temperature sensor (10), the second temperature sensor (11) and the third temperature sensor (12) to a display terminal.

8. The intelligent temperature-controlled culture pond according to claim 6, wherein the pond wall of the hot water pond (5) and/or the cold water pond (7) is attached with an insulating layer.

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