CN220250720U - Temperature control system capable of saving energy consumption - Google Patents

Abstract

The utility model discloses a temperature control system capable of saving energy consumption, which comprises a water tank, a first driving piece, a second driving piece, a heat exchanger, a cooling tower and a demisting tank, wherein the water tank is provided with a water inlet and a reflux port; the defogging jar is provided with the updraft ventilator, and the defogging jar is connected with the cooling tower through the updraft ventilator, and the defogging jar is provided with the air inlet, and the one end and the air inlet of updraft ventilator are connected, and the other end and the cooling tower of updraft ventilator are connected, and the inside of defogging jar is equipped with the whirl defogging piece, and the whirl defogging piece is connected with the air inlet, and the water storage storehouse sets up in the inside of defogging jar, and the water storage storehouse is connected with the backward flow mouth through the second driving piece. The beneficial effects are that: the design achieves the purpose of water circulation, improves the utilization rate of water resources and greatly reduces the cost.

Description

Temperature control system capable of saving energy consumption

Technical Field

The utility model relates to the technical field of cooling towers, in particular to a temperature control system capable of saving energy consumption.

Background

The cooling tower is a device which uses water as a circulating coolant, absorbs heat from a system and discharges the heat to the atmosphere so as to reduce the water temperature; the cooling is an evaporation heat-dissipating device which utilizes the principles of evaporation heat dissipation, convection heat transfer, radiation heat transfer and the like to dissipate waste heat generated in industry or refrigeration air conditioner to reduce water temperature by utilizing the heat generated by the evaporation heat-dissipating device to ensure the normal operation of a system, and the device is generally barrel-shaped, so the device is named as a cooling tower;

in the prior art, when the temperature of high-temperature hot water is reduced, the fan arranged on the cooling tower is used for heat exchange treatment, a large amount of electricity is consumed during operation of the fan, the mode is adopted for reducing the temperature of the high-temperature hot water for a long time, so that the cost is greatly increased, in addition, after the high-temperature hot water is sent into the cooling tower, a large amount of water vapor exists, the water vapor is directly discharged to the outside, the environment is affected to a certain extent, and in the discharging process, the water vapor can carry a large amount of water, so that the water loss is caused, and the utilization rate of water resources is reduced.

Disclosure of Invention

Aiming at the defects, the utility model aims to provide an energy-saving temperature control system which reduces energy consumption, improves the utilization rate of water resources and avoids influencing the environment.

To achieve the purpose, the utility model adopts the following technical scheme:

the temperature control system capable of saving energy comprises a water tank, a first driving piece, a second driving piece, a heat exchanger, a cooling tower and a demisting tank, wherein the water tank is provided with a water inlet and a reflux port, one end of the first driving piece is connected with the water inlet, the other end of the first driving piece is connected with a receiving end of the heat exchanger, an exhaust end of the heat exchanger is connected with the cooling tower, and the cooling tower is provided with an energy-saving fan for cooling high-temperature hot water; the utility model discloses a defogging jar, including cooling tower, defogging jar, cooling tower, air inlet, defogging jar, the defogging jar is provided with the updraft ventilator, the one end of updraft ventilator with the air inlet is connected, the other end of updraft ventilator with the cooling tower is connected, the inside of defogging jar is provided with whirl defogging piece, whirl defogging piece with the air inlet is connected, the below of whirl defogging piece is provided with the water storage bin, the second driving piece with the backward flow mouth is connected, the other end of second driving piece passes the defogging jar with the water storage bin is connected.

Preferably, the above temperature control system for saving energy consumption, wherein the cyclone demisting member comprises a spiral pipe, a drain pipe and a plurality of demisting plates, the spiral pipe is arranged inside the demisting tank, one end of the spiral pipe is connected with the air inlet, the other end of the spiral pipe is connected with the drain pipe, the water outlet of the drain pipe is positioned above the water storage bin, and the plurality of demisting plates are sequentially arranged inside the spiral pipe.

Preferably, in the energy-saving temperature control system, the demisting plate is in a W-zigzag shape.

Preferably, in the above temperature control system for saving energy, the drain pipe is funnel-shaped. And one end of the drain pipe with a long diameter is connected with the spiral pipe.

Preferably, the energy-saving temperature control system comprises a fan body, a solar electric heating plate and a power supply controller, wherein the fan body is arranged inside the cooling tower, the solar electric heating plate and the power supply controller are both arranged on the outer wall of the cooling tower, the solar electric heating plate is electrically connected with the power supply controller, and the power supply controller is provided with an energizing line for being electrically connected with the fan body.

Preferably, in the above temperature control system for saving energy consumption, the air suction member includes an air suction pump and an air duct channel, the air duct channel is communicated with the air suction pump, one end of the air duct channel is connected with the air inlet, and the other end of the air duct channel is connected with the cooling tower.

Preferably, in the temperature control system for saving energy, the first driving member includes a first water pump and a water inlet pipe, the water inlet pipe is communicated with the first water pump, one end of the water inlet pipe is connected with the water inlet, and the other end of the water inlet pipe is connected with the receiving end of the heat exchanger.

Preferably, the above temperature control system capable of saving energy consumption, wherein the second driving member includes a second water pump, a filter and a return water circulation pipe, the return water circulation pipe is sequentially communicated with the second water pump and the filter, one end of the return water circulation pipe is connected with the return port, and the other end of the return water circulation pipe passes through the demisting tank and is connected with the water storage bin.

The utility model has the beneficial effects that:

the water tank is filled with water through the first driving piece into the heat exchanger, heat exchange is carried out on indoor heat absorbed by the condenser, high-temperature hot water is generated in the heat exchange process, the generated high-temperature hot water is sent into the cooling tower, the cooling tower is provided with an energy-saving fan for cooling the high-temperature hot water, a large amount of high-temperature steam is generated in the cooling process, the high-temperature steam is prevented from being directly discharged into the air in the cooling tower, the high-temperature steam in the cooling tower is sent into the demisting tank through the air suction piece, the high-temperature steam is separated through the rotational flow demisting piece provided with the demisting tank, and finally the separated water is conveyed into the water tank again through the second driving piece.

Drawings

FIG. 1 is a flow chart illustrating the operation of one embodiment of the present utility model;

FIG. 2 is a control flow diagram of an energy-efficient blower;

FIG. 3 is a schematic view of a cooling tower;

FIG. 4 is a schematic diagram of a demister tank;

FIG. 5 is a schematic view of a construction of a cyclone mist eliminator;

FIG. 6 is a schematic view of a demister plate according to one embodiment of the present utility model.

Wherein: the solar energy water heater comprises a water tank 11, a first driving piece 12, a second driving piece 13, a heat exchanger 14, a cooling tower 15, a demisting tank 16, an energy-saving fan 17, an air draft piece 18, a rotational flow demisting piece 19, a water storage bin 20, a spiral pipe 21, a water drain pipe 22, a demisting plate 23, a fan body 24, a solar electric heating plate 25, a power supply controller 26, a power-on line 27, an air draft pump 28, an air pipe channel 29, a first water pump 30, a water inlet pipe 31, a second water pump 32, a filter 33 and a return water circulating pipe 34.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the terms "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

As shown in fig. 1 to 6, a temperature control system capable of saving energy comprises a water tank 11, a first driving piece 12, a second driving piece 13, a heat exchanger 14, a cooling tower 15 and a demisting tank 16, wherein the water tank 11 is provided with a water inlet and a reflux port, one end of the first driving piece 12 is connected with the water inlet, the other end of the first driving piece 12 is connected with a receiving end of the heat exchanger 14, an exhaust end of the heat exchanger 14 is connected with the cooling tower 15, and the cooling tower 15 is provided with an energy-saving fan 17 for cooling high-temperature hot water; the demisting tank 16 is provided with an air suction member 18, the demisting tank 16 is connected with the cooling tower 15 through the air suction member 18, the demisting tank 16 is provided with an air inlet, one end of the air suction member 18 is connected with the air inlet, the other end of the air suction member 18 is connected with the cooling tower 15, a rotational flow demisting member 19 is arranged in the demisting tank 16, the rotational flow demisting member 19 is connected with the air inlet, a water storage bin 20 is arranged below the rotational flow demisting member 19, the second driving member 13 is connected with a backflow port, and the other end of the second driving member 13 penetrates through the demisting tank 16 to be connected with the water storage bin 20; firstly, the water of the water tank 11 is sent into the heat exchanger 14 through the first driving piece 12, then the indoor heat is absorbed by the condenser for heat exchange, high-temperature hot water is generated in the heat exchange process, the generated high-temperature hot water is sent into the cooling tower 15, the cooling treatment is carried out on the high-temperature hot water through the energy-saving fan 17 arranged on the cooling tower 15, a large amount of high-temperature steam is generated in the cooling treatment process, in order to avoid directly discharging the high-temperature steam into the air, the high-temperature steam in the cooling tower 15 is conveyed into the demisting tank 16 through the air suction piece 18, the high-temperature steam is separated through the rotational flow demisting piece 19 arranged on the demisting tank 16, so that water carried by the high-temperature steam can flow into the water storage bin 20, and finally the separated water is conveyed into the water tank 11 again through the second driving piece 13, the purpose of water circulation is achieved, the water resource utilization rate is improved, and the cost is greatly reduced.

In the temperature control system capable of saving energy consumption in this embodiment, the rotational flow demister 19 includes a spiral pipe 21, a drain pipe 22 and a plurality of demisting plates 23, the spiral pipe 21 is disposed inside the demisting tank 16, one end of the spiral pipe 21 is connected with the air inlet, the other end of the spiral pipe 21 is connected with the drain pipe 22, the water outlet of the drain pipe 22 is located above the water storage bin 20, and the plurality of demisting plates 23 are sequentially disposed inside the spiral pipe 21; the whirl defogging piece 19 comprises spiral pipe 21, drain pipe 22 and a plurality of defogging board 23, and defogging board 23 sets gradually in the inside of spiral pipe 21, and such design makes after spiral pipe 21 received high temperature steam, through the defogging board 23 that spiral pipe 21 inside was equipped with, after steam and defogging board 23 contact, can produce the drop of water, and the drop of water of production can follow drain pipe 22 and flow into water storage bin 20 downwards, and such design can avoid the moisture loss that the steam carried, greatly reduced the cost.

Wherein the demister plate 23 is in a W zigzag shape, and the design can better separate high-temperature steam.

The energy-saving temperature control system in some embodiments, wherein the drain pipe 22 is funnel-shaped. And one end of the drain pipe 22 with a long diameter is connected with the spiral pipe 21; because the diameter of one end that drain pipe 22 and spiral pipe 21 are connected is wide, and the other end is narrow to form the funnel form, this kind of design is convenient for more accept the water that spiral pipe 21 separated, and the narrow one end of drain pipe 22 is then in order to send the water more accurate to the inside of water storage bin 20.

It should be noted that, the energy-saving fan 17 includes a fan body 24, a solar electric heating plate 25 and a power controller 26, the fan body 24 is disposed in the cooling tower 15, the solar electric heating plate 25 and the power controller 26 are both disposed on the outer wall of the cooling tower 15, the solar electric heating plate 25 is electrically connected with the power controller 26, and the power controller 26 is provided with an energizing line 27 for electrically connecting with the fan body 24; because energy-conserving fan 17 comprises fan body 24, solar electric plate 25 and power controller 26, in the use, solar electric plate 25 is after converting the heat energy that receives into electric energy, carries power controller 26, through the circular telegram line 27 that power controller 26 was equipped with fan body 24 electric connection to reach the purpose that drive fan body 24 rotated the cooling, thereby the cost of the power consumption can be reduced to such design.

In the temperature control system capable of saving energy consumption in this embodiment, the air suction member 18 includes an air suction pump 28 and an air duct channel 29, the air duct channel 29 is communicated with the air suction pump 28, one end of the air duct channel 29 is connected with an air inlet, and the other end of the air duct channel 29 is connected with the cooling tower 15; the design achieves the purpose of conveying high-temperature steam, and is more reliable in the conveying process.

In the temperature control system for saving energy consumption in this embodiment, the first driving member 12 includes a first water pump 30 and a water inlet pipe 31, the water inlet pipe 31 is communicated with the first water pump 30, one end of the water inlet pipe 31 is connected with the water inlet, and the other end of the water inlet pipe 31 is connected with the receiving end of the heat exchanger 14; this design thus achieves the purpose of feeding the water inside the tank 11 into the interior of the heat exchanger 14.

In the temperature control system capable of saving energy consumption in this embodiment, the second driving piece 13 includes a second water pump 32, a filter 33 and a return water circulation pipe 34, the return water circulation pipe 34 sequentially communicates the second water pump 32 and the filter 33, one end of the return water circulation pipe 34 is connected with a return port, and the other end of the return water circulation pipe 34 passes through the demisting tank 16 to be connected with the water storage bin 20; the water in the water storage bin 20 can be returned to the water tank 11 through the second water pump 32 to achieve the water circulation purpose, and stains in the water can be filtered through the filter 33, so that the purity of a water source is ensured.

The technical principle of the present utility model is described above in connection with the specific embodiments. The description is made for the purpose of illustrating the general principles of the utility model and should not be taken in any way as limiting the scope of the utility model. Other embodiments of the utility model will be apparent to those skilled in the art from consideration of this specification without undue burden.

Claims (8)

1. The utility model provides a temperature control system of energy saving which characterized in that: the device comprises a water tank, a first driving piece, a second driving piece, a heat exchanger, a cooling tower and a demisting tank, wherein the water tank is provided with a water inlet and a backflow port, one end of the first driving piece is connected with the water inlet, the other end of the first driving piece is connected with a receiving end of the heat exchanger, an exhaust end of the heat exchanger is connected with the cooling tower, and the cooling tower is provided with an energy-saving fan for cooling high-temperature hot water;

the utility model discloses a defogging jar, including cooling tower, defogging jar, cooling tower, air inlet, defogging jar, the defogging jar is provided with the updraft ventilator, the one end of updraft ventilator with the air inlet is connected, the other end of updraft ventilator with the cooling tower is connected, the inside of defogging jar is provided with whirl defogging piece, whirl defogging piece with the air inlet is connected, the below of whirl defogging piece is provided with the water storage bin, the second driving piece with the backward flow mouth is connected, the other end of second driving piece passes the defogging jar with the water storage bin is connected.

2. The energy-saving temperature control system according to claim 1, characterized in that: the cyclone demisting piece comprises a spiral pipe, a drain pipe and a plurality of demisting plates, wherein the spiral pipe is arranged in the demisting tank, one end of the spiral pipe is connected with the air inlet, the other end of the spiral pipe is connected with the drain pipe, a water outlet of the drain pipe is positioned above the water storage bin, and the demisting plates are sequentially arranged in the spiral pipe.

3. The energy-saving temperature control system according to claim 2, characterized in that: the defogging board is W zigzag.

4. The energy-saving temperature control system according to claim 2, characterized in that: the drain pipe is funnel-shaped, and the long one end of drain pipe diameter with the spiral pipe is connected.

5. The energy-saving temperature control system according to claim 1, characterized in that: the energy-saving fan comprises a fan body, a solar electric heating plate and a power supply controller, wherein the fan body is arranged inside the cooling tower, the solar electric heating plate and the power supply controller are both arranged on the outer wall of the cooling tower, the solar electric heating plate is electrically connected with the power supply controller, and the power supply controller is provided with an energizing line for being electrically connected with the fan body.

6. The energy-saving temperature control system according to claim 1, characterized in that: the air suction piece comprises an air suction pump and an air duct channel, the air duct channel is communicated with the air suction pump, one end of the air duct channel is connected with the air inlet, and the other end of the air duct channel is connected with the cooling tower.

7. The energy-saving temperature control system according to claim 1, characterized in that: the first driving piece comprises a first water pump and a water inlet pipe, the water inlet pipe is communicated with the first water pump, one end of the water inlet pipe is connected with the water inlet, and the other end of the water inlet pipe is connected with the receiving end of the heat exchanger.

8. The energy-saving temperature control system according to claim 1, characterized in that: the second driving piece comprises a second water pump, a filter and a return water circulating pipe, the return water circulating pipe is used for sequentially communicating the second water pump with the filter, one end of the return water circulating pipe is connected with the backflow port, and the other end of the return water circulating pipe penetrates through the demisting tank to be connected with the water storage bin.