CN215062908U - Clean high-efficient thermal power is demineralized water tank for heat and electricity - Google Patents

Abstract

The utility model discloses a clean high-efficiency thermal electric desalting water tank, which comprises a salt water tank body, wherein a plurality of heat dissipation devices are arranged in the salt water tank body at intervals from top to bottom, each heat dissipation device comprises a plurality of heat dissipation pipes arranged at intervals, and the inner surfaces of the heat dissipation pipes are communicated with the outer side of the salt water tank body; the utility model discloses a natural wind flows into the cooling tube, flows into other one end from its one end and flows out, can take this internal heat of brine tank to reach the effect of natural cooling.

Description

Clean high-efficient thermal power is demineralized water tank for heat and electricity

Technical Field

The utility model relates to a firepower thermoelectric equipment technical field specifically is a demineralized water tank of clean high-efficient firepower thermoelectric usefulness.

Background

The existing demineralized water tank is made of a stainless steel plate, the stainless steel plate is exposed and exposed outside after being painted, the surface temperature is generally higher than 40 ℃ in summer, demineralized water in the demineralized water tank is indirectly heated, the operation of the desalting machine is not facilitated, and therefore the desalting water tank needs to be effectively cooled.

SUMMERY OF THE UTILITY MODEL

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a clean high-efficiency desalting water tank for thermal power comprises a salt water tank body, wherein a plurality of heat dissipation devices are arranged in the salt water tank body at intervals from top to bottom, and each heat dissipation device comprises a plurality of heat dissipation pipes arranged at intervals;

the inner surface of the radiating pipe is communicated with the outer side of the brine tank body, natural wind flows into the radiating pipe, flows into the other end from one end of the radiating pipe and flows out from the other end of the radiating pipe, and heat in the brine tank body can be taken to achieve the effect of natural cooling.

Furthermore, the connecting pipe that communicates with the cooling tube has been installed to the both sides of brine tank body, and the gas circulation pump with the connecting pipe intercommunication has still been installed at the top of brine tank body, replaces natural wind through gas circulation pump work, takes out the heat in the cooling tube to be suitable for windless environment.

Furthermore, the outer surface cladding of connecting pipe has the electrical heating area, and temperature sensor has been installed to the internal surface of brine tank body, and the controller has still been installed at the top of brine tank body, and the controller respectively with electrical heating area, gas circulation pump and temperature sensor electric connection, the controller can be according to the information of temperature sensor feedback, control electrical heating area work to be convenient for with the internal temperature control of brine tank between-degree.

Furthermore, the gas circulating pump is provided with two input ends and an output end, wherein one input end is communicated with the connecting pipe through a three-way joint, and the output end is communicated with the connecting pipe positioned on the left side of the brine tank body;

the inner surfaces of one end of the three-way joint connected with the gas circulating pump and one end communicated with the outside are provided with electromagnetic valves, and the electromagnetic valves are electrically connected with the controller;

the electromagnetic valves in one end of the three-way joint connected with the gas circulating pump and one end communicated with the outside are an electromagnetic valve a and an electromagnetic valve b in sequence, when the heating belt is not in operation, the controller controls the electromagnetic valve a to be closed, the electromagnetic valve b to be opened, cooling circulation is realized, when the heating belt is in operation, the electromagnetic valve b is closed, the electromagnetic valve a is opened, and heat circulation is realized.

Furthermore, a solar panel and a storage battery are arranged at the top of the brine tank body, and the controller is electrically connected with the solar panel and the storage battery respectively so as to supply power to the whole system by using solar energy.

The working principle and the beneficial effects are as follows: the natural wind flows into the radiating pipe and flows into the other end from one end of the radiating pipe to flow out, and the heat in the brine tank body can be taken, so that the effect of natural cooling is achieved.

Drawings

FIG. 1 is a schematic cross-sectional structure of the present invention;

fig. 2 is a schematic view of the structure of the three-way joint of the present invention.

In the figure: 1. a brine tank body; 2. a radiating pipe; 3. a connecting pipe; 4. a gas circulation pump; 5. an electrical heating belt; 6. a temperature sensor; 7. a controller; 8. a three-way joint; 9. a solar panel; 10. and (4) a storage battery.

Detailed Description

The invention will be better understood from the following examples.

The drawings in the specification show the structure, ratio, size, etc. only for the purpose of matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and not for the purpose of limiting the present invention, so the present invention does not have the essential meaning in the art, and any structure modification, ratio relationship change or size adjustment should still fall within the scope covered by the technical content disclosed in the present invention without affecting the function and achievable purpose of the present invention. Meanwhile, the terms "upper", "lower", "front", "rear", "middle", and the like used in the present specification are for the sake of clarity only, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof are also considered to be the scope of the present invention without substantial changes in the technical content.

As shown in fig. 1-2, a clean and efficient desalting water tank for thermal power heating comprises a brine tank body 1, wherein a plurality of heat dissipation devices are arranged in the brine tank body 1 at intervals from top to bottom, and each heat dissipation device comprises a plurality of heat dissipation pipes 2 arranged at intervals;

the inner surface of the radiating pipe 2 is communicated with the outer side of the brine tank body 1, flows into the radiating pipe through natural wind, flows into the other end from one end of the radiating pipe and flows out from the other end of the radiating pipe, and can take heat in the brine tank body to achieve the effect of natural cooling.

Wherein, connecting pipe 3 with cooling tube 2 intercommunication is installed to the both sides of brine tank body 1, and gas circulation pump 4 with connecting pipe 3 intercommunication is still installed at the top of brine tank body 1, replaces natural wind through gas circulation pump work, takes the heat in the cooling tube out to be suitable for the environment of no wind.

Wherein, the surface cladding of connecting pipe 3 has electric heating belt 5, and temperature sensor 6 has been installed to the internal surface of brine tank body 1, and controller 7 has still been installed at the top of brine tank body 1, and controller 7 respectively with electric heating belt 5, gas circulation pump 4 and temperature sensor 6 electric connection, the controller can be according to the information of temperature sensor feedback, control electric heating belt work to be convenient for with the temperature control in the brine tank body between 25-35 degrees.

The gas circulating pump 4 is provided with two input ends and one output end, wherein one input end is communicated with the connecting pipe 3 through the three-way joint 8, and the output end is communicated with the connecting pipe 3 positioned on the left side of the brine tank body 1;

the inner surfaces of one end of the three-way joint 8 connected with the gas circulating pump 4 and one end communicated with the outside are provided with electromagnetic valves, and the electromagnetic valves are electrically connected with the controller 7;

wherein the solenoid valve in the one end that three way connection 8 and gas circulation pump 4 are connected, and the one end that communicates with the external world is solenoid valve a and solenoid valve b in proper order, and when the heating zone did not work, controller control solenoid valve a closed, and solenoid valve b opens, realizes cooling circulation, and when the heating zone worked, solenoid valve b closed, and solenoid valve a opened, realized the thermal cycle.

Wherein, the top of the brine tank body 1 is also provided with a solar panel 9 and a storage battery 10, and the controller 7 is respectively electrically connected with the solar panel 9 and the storage battery 10 so as to supply power to the whole system by using solar energy.

Claims (5)

1. The utility model provides a clean high-efficient firepower is demineralized water tank of thermoelectric usefulness, includes brine tank body (1), its characterized in that: a plurality of heat dissipation devices are arranged in the brine tank body (1) at intervals from top to bottom, and each heat dissipation device comprises a plurality of heat dissipation pipes (2) arranged at intervals;

the inner surface of the radiating pipe (2) is communicated with the outer side of the brine tank body (1).

2. The clean, high efficiency, fire-powered electric desalination tank of claim 1, wherein: connecting pipes (3) communicated with the radiating pipes (2) are arranged on two sides of the brine tank body (1), and a gas circulating pump (4) communicated with the connecting pipes (3) is further arranged on the top of the brine tank body (1).

3. A clean high efficiency fire electric demineralization tank of claim 2, wherein: the surface cladding of connecting pipe (3) has electrical heating area (5), and temperature sensor (6) have been installed to the internal surface of brine tank body (1), and controller (7) have still been installed at the top of brine tank body (1), and controller (7) respectively with electrical heating area (5), gas circulation pump (4) and temperature sensor (6) electric connection.

4. A clean high efficiency fire electric demineralization tank of claim 3, wherein: the gas circulating pump (4) is provided with two input ends and one output end, wherein one input end is communicated with the connecting pipe (3) through a three-way joint (8), and the output end is communicated with the connecting pipe (3) positioned on the left side of the brine tank body (1);

the inner surfaces of one end of the three-way joint (8) connected with the gas circulating pump (4) and one end communicated with the outside are respectively provided with an electromagnetic valve, and the electromagnetic valves are electrically connected with the controller (7).

5. The clean, high efficiency, fire-powered electric desalination tank of claim 4, wherein: the top of the brine tank body (1) is also provided with a solar panel (9) and a storage battery (10), and the controller (7) is respectively and electrically connected with the solar panel (9) and the storage battery (10).

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