CN213074081U - Aquaculture heating device - Google Patents

Abstract

The application discloses aquaculture rising temperature device includes: the industrial hot water outlet pipe, the heat circulating pump, the filter, the flap valve, the first water inlet pipe, the second water inlet pipe, the controller and the culture pond, wherein the culture pond comprises a third water inlet pipe, a first water outlet pipe, a temperature sensor, a water quality detector and a coiled pipe heat exchanger; the industrial hot water outlet pipe is connected with a heat circulating pump, the heat circulating pump is connected with a first water inlet pipe, the filter is connected with a second water inlet pipe, the second water inlet pipe is connected with a flap valve, and the flap valve is connected with a third water inlet pipe; the industrial hot water outlet pipe is connected with a return pipe. The device has solved the electric heating mode, not only the resource-wasting makes the fish species take place to die moreover easily, increases enterprise manufacturing cost's problem.

Description

Aquaculture heating device

Technical Field

The application relates to the technical field of aquaculture, especially, relate to an aquaculture rising temperature device.

Background

The aquaculture can not only meet the needs of consumers, but also bring rich benefits to the culturists. The water temperature not only directly influences the survival and growth of the fishes, but also indirectly acts on the fishes through the change of the water temperature to the water body environment condition. Almost all environmental factors are limited by water temperature. Due to changes in metabolic intensity and body temperature of fish. Directly affects the feeding and growth of the fish. Various fishes have the temperature range suitable for the fishes, and as the temperature rises, the metabolism of the fishes is correspondingly enhanced, the food intake is increased, and the growth is accelerated. The temperature and the temperature of the water vary seasonally and day and night. In summer, the temperature rises gradually, the water temperature also rises along with the temperature rise, and if corresponding measures are not taken, the aquatic animals are easy to suffer from heatstroke. In late autumn and early winter, the growth speed of aquatic animals is reduced, the aquatic animals enter a fattening period, the metabolism function is reduced, the respiration is slowed, and the demand for dissolved oxygen in water is reduced, so that winter protection and heat preservation become the key management points in winter.

At present, most aquaculture plants adopt an electric heating mode to heat up a water pool, the mode not only wastes resources, but also easily causes fish seeds to be inappropriately dead if the local heating is too fast, thereby causing economic loss to enterprises and increasing the production cost of the enterprises. Therefore, the aquaculture warming device is provided to solve the problems.

SUMMERY OF THE UTILITY MODEL

The application provides an aquaculture rising temperature device has solved and has adopted the electric heating mode to heat up the pond, and this kind of mode is the resource-wasting not only, if local intensification makes the fish species unsuitable emergence death too fast moreover easily, causes economic loss for the enterprise, increases enterprise manufacturing cost's problem.

In order to solve the technical problem, the application provides an aquaculture rising temperature device, includes: the system comprises an industrial hot water outlet pipe, a heat circulating pump, a filter, a flap valve, a first water inlet pipe, a second water inlet pipe, a controller and a culture pond, wherein the culture pond comprises a third water inlet pipe, a first water outlet pipe, a temperature sensor, a water quality detector and a coiled pipe heat exchanger; the industrial hot water outlet pipe is connected with a water inlet of the heat circulating pump, a water outlet of the heat circulating pump is connected with one end of the first water inlet pipe, the other end of the first water inlet pipe is connected with a water inlet of the filter, a water outlet of the filter is connected with one end of the second water inlet pipe, the other end of the second water inlet pipe is connected with a water inlet of the flap valve, and a water outlet of the flap valve is connected with the third water inlet pipe;

the industrial hot water outlet pipe is also connected with a water return pipe, the water return pipe is positioned on one side of the water inlet of the heat circulating pump, and a valve is arranged on the water return pipe.

Furthermore, a plurality of heat conduction pipes are communicated with the coiled pipe heat exchanger and are positioned at the upper end of the coiled pipe heat exchanger.

Further, a plurality of the heat conduction pipes are distributed at equal intervals.

Furthermore, a sunshade net is arranged on the culture pond.

Furthermore, the shape of the culture pond is rectangular, and the depth of the culture pond is 2-5 m.

Compare in prior art, when using the aquaculture rising temperature device that this application provided, detect the temperature in the breed pond by temperature sensor to with the information transmission to the controller that needs the intensification, the controller can control opening or closing of heat-cycle pump. The hot water that produces can insert by industry hot water outlet pipe in industrial production, and hot water gets into the coiled pipe heat exchanger by the third inlet tube behind first inlet tube, filter, second inlet tube, the flap valve in proper order, and the coiled pipe heat exchanger is with heat transmission to breeding in the pond, heaies up breeding the pond, and the water through the circulation flows out by first outlet pipe, and when closing the heat-circulating pump, hot water is returned by the wet return. Therefore, the aquaculture warming device utilizes industrial hot water to warm, saves resources, heats water in the culture pond by using the coiled pipe heat exchanger at the bottom of the culture pond, cannot cause fish death due to local warming, and saves the production cost of enterprises.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments are briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without making any inventive changes.

Fig. 1 is a schematic structural view of an aquaculture warming device provided by an embodiment of the present invention;

fig. 2 is the embodiment of the present invention, in which the heat pipe is installed on the coiled pipe heat exchanger.

In the figure, 1-an industrial hot water outlet pipe, 2-a heat circulating pump, 3-a filter, 4-a flap valve, 11-a first water inlet pipe, 12-a second water inlet pipe, 5-a culture pond, 13-a third water inlet pipe, 14-a first water outlet pipe, 6-a temperature sensor, 7-a water quality detector, 8-a coil heat exchanger, 9-a water return pipe, 91-a valve and 111-a heat conducting pipe.

Detailed Description

In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments.

The core of this application is to provide an aquaculture rising temperature device, can solve and adopt the electric heating mode to heat up the pond, and this kind of mode is the resource-wasting not only, if local intensification makes the fish species unsuitable emergence death too fast in addition, causes economic loss for the enterprise, increases enterprise manufacturing cost's problem.

Fig. 1 is a schematic structural view of an aquaculture warming device provided by an embodiment of the present invention; fig. 2 is the embodiment of the present invention, in which the heat pipe is installed on the coiled pipe heat exchanger. As shown in fig. 1, includes: the system comprises an industrial hot water outlet pipe 1, a heat circulating pump 2, a filter 3, a flap valve 4, a first water inlet pipe 11, a second water inlet pipe 12, a controller and a culture pond 5, wherein the culture pond 5 comprises a third water inlet pipe 13, a first water outlet pipe 14, a temperature sensor 6, a water quality detector 7 and a coiled pipe heat exchanger 8, the temperature sensor 6 and the water quality detector 7 are all arranged at the bottom of the culture pond 5, the heat circulating pump 2, the temperature sensor 6 and the water quality detector 7 are all electrically connected with the controller, a water inlet of the coiled pipe heat exchanger 8 is in flange connection with the third water inlet pipe 13, and a water outlet of the coiled pipe heat exchanger 8 is in flange connection with the; the industrial hot water outlet pipe 1 is connected with a water inlet of the heat circulating pump 2, a water outlet of the heat circulating pump 2 is connected with one end of a first water inlet pipe 11, the other end of the first water inlet pipe 11 is connected with a water inlet of a filter 3, a water outlet of the filter 3 is connected with one end of a second water inlet pipe 12, the other end of the second water inlet pipe 12 is connected with a water inlet of a flap valve 4, and a water outlet of the flap valve 4 is connected with a third water inlet pipe 13;

wherein, still be connected with wet return 9 on industry hot water outlet pipe 1, wet return 9 is located the one side of heat circulating pump 2 water inlet, is provided with valve 91 on wet return 9.

In particular, hot water in industrial production is often directly discharged, which not only wastes resources but also easily causes environmental pollution, so that the hot water produced in industrial production is used as a hot water source for raising the temperature in the culture pond. The industrial hot water outlet pipe 1 is connected with a water inlet of the heat circulating pump 2, the heat circulating pump 2 is connected with the controller, and the controller enables the heat circulating pump 2 to automatically stop or start. One end of the first water inlet pipe 11 is connected with the water outlet of the heat circulating pump 2, and the other end of the first water inlet pipe 11 is connected with the water inlet of the filter 3. The filter 3 can filter impurities such as silt and waste in the hot water, and the structure of the filter 3 is not limited to the structure shown in the drawing. The water outlet of the filter 3 is connected with one end of a second water inlet pipe 12, and the other end of the second water inlet pipe 12 is connected with the water inlet of the flap valve 4. The flap valve 4 can play a good role in cutting off and throttling water entering the culture pond 5. The water outlet of the flap valve 4 is connected with a third water inlet pipe 13, and hot water enters the culture pond 5 through the third water inlet pipe 13.

Specifically, the culture pond 5 further comprises a first water outlet pipe 14, a temperature sensor 6, a water quality detector 7 and a coiled pipe heat exchanger 8. The coiled pipe heat exchanger 8, the temperature sensor 6 and the water quality detector 7 are all arranged at the bottom of the culture pond 5, the temperature sensor 6 and the water quality detector 7 are electrically connected with the controller, the temperature sensor 6 can measure the water temperature in the culture pond 5, the water quality detector 7 can measure the water quality in the culture pond 5, and the water temperature and the water quality can be displayed on a display of the controller. The structure of the controller is not shown in the figures, which is incorporated in the prior art. The controller automatically controls the heat circulating pump 2 to make the hot water flow in from the industrial hot water outlet pipe 1. The coiled heat exchanger 8 transfers heat to water in the culture pond 5, and in order to further improve the heat dissipation efficiency, a plurality of heat conduction pipes 111 are communicated with the coiled heat exchanger 8, and the heat conduction pipes 111 are located at the upper end of the coiled heat exchanger 8. As shown in fig. 2, the heat transfer pipe 111 is laid over the coil heat exchanger 8, and the inlet of the heat transfer pipe 111 communicates with the side wall of the coil heat exchanger 8. The heat conduction pipe 111 not only can dissipate heat, but also increases the area of hot water circulation in the culture pond 5, so that the temperature rise of water is more uniform. Further, the plurality of heat transfer pipes 111 are distributed at equal intervals. The number of the heat conductive pipes 111 can be designed according to actual needs. The water inlet of the coiled pipe heat exchanger 8 is connected with a third water inlet pipe 13 through a flange, and the water after heat exchange flows out of the third water inlet pipe 13. In order to prevent the direct light above the culture pond 5 from influencing the fingerlings, a sunshade net is further arranged on the culture pond 5. The structure of sunshade net combines prior art, and it is not repeated to be repeated. In order to facilitate heat dissipation, the culture pond 5 is rectangular, and the depth of the culture pond 5 is 2-5 m. Wherein, still be connected with wet return 9 on industry hot water outlet pipe 1, wet return 9 is located the one side of heat circulating pump water inlet, is provided with valve 91 on wet return 9. When the temperature of the culture pond 5 does not need to be raised, hot water flows back through the water return pipe 9.

Compare in prior art, when using the aquaculture rising temperature device that this application provided, detect the temperature in the breed pond by temperature sensor to with the information transmission to the controller that needs the intensification, the controller can control opening or closing of heat-cycle pump. The hot water that produces can insert by industry hot water outlet pipe in industrial production, and hot water gets into the coiled pipe heat exchanger by the third inlet tube behind first inlet tube, filter, second inlet tube, the flap valve in proper order, and the coiled pipe heat exchanger is with heat transmission to breeding in the pond, heaies up breeding the pond, and the water through the circulation flows out by first outlet pipe, and when closing the heat-circulating pump, hot water is returned by the wet return. Therefore, the aquaculture warming device utilizes industrial hot water to warm, saves resources, heats water in the culture pond by using the coiled pipe heat exchanger at the bottom of the culture pond, cannot cause fish death due to local warming, and saves the production cost of enterprises.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the application disclosed herein. This application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice in the art to which the invention pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims.

It will be understood that the present application is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The above-described embodiments of the present application do not limit the scope of the present application.

Claims (5)

1. An aquaculture warming apparatus, comprising: the system comprises an industrial hot water outlet pipe, a heat circulating pump, a filter, a flap valve, a first water inlet pipe, a second water inlet pipe, a controller and a culture pond, wherein the culture pond comprises a third water inlet pipe, a first water outlet pipe, a temperature sensor, a water quality detector and a coiled pipe heat exchanger; the industrial hot water outlet pipe is connected with a water inlet of the heat circulating pump, a water outlet of the heat circulating pump is connected with one end of the first water inlet pipe, the other end of the first water inlet pipe is connected with a water inlet of the filter, a water outlet of the filter is connected with one end of the second water inlet pipe, the other end of the second water inlet pipe is connected with a water inlet of the flap valve, and a water outlet of the flap valve is connected with the third water inlet pipe;

the industrial hot water outlet pipe is also connected with a water return pipe, the water return pipe is positioned on one side of the water inlet of the heat circulating pump, and a valve is arranged on the water return pipe.

2. An aquaculture warming device according to claim 1, wherein said coiled heat exchanger is provided with a plurality of heat conducting pipes, said heat conducting pipes being located at an upper end of said coiled heat exchanger.

3. An aquaculture warming apparatus according to claim 2 wherein said plurality of heat conducting pipes are equally spaced.

4. An aquaculture warming device according to claim 1, wherein a sunshade net is arranged on said culture pond.

5. An aquaculture warming device according to claim 1 wherein said aquaculture pond is rectangular in shape and has a depth of 2-5 m.

Images