CN220250736U - Cross-flow type high-temperature cooling tower - Google Patents

Abstract

The utility model discloses a cross-flow high-temperature cooling tower, which comprises a cooling installation shell, wherein a circulating cooling assembly is arranged in the cooling installation shell, a ventilation assembly is arranged at the periphery of the cooling installation shell, and a photovoltaic power supply assembly is arranged at one side of the circulating cooling assembly; the utility model improves the prior art, not only reduces resistance and saves energy by optimizing the ventilation system and improves the operation efficiency, but also effectively solves the problems that the operation efficiency is limited by only optimizing the ventilation system in the prior art in actual use and is lower in high temperature in summer and greatly improves the cooling effect in summer by the circulating cooling assembly.

Description

Cross-flow type high-temperature cooling tower

Technical Field

The utility model relates to the field of cross-flow high-temperature cooling, in particular to a cross-flow high-temperature cooling tower.

Background

In the high-temperature season in summer, the existing cross-flow cooling tower has the defects that the cooling effect of the cooling tower is obviously reduced due to the high temperature and humidity of the ambient air, the temperature of cooling water cannot be reduced to the required temperature, and the machine of a workshop user fails; the condensed water of the air conditioning unit is directly discharged in summer, and a large amount of cold energy is not fully utilized due to the low temperature of the condensed water of the air conditioner, so that energy waste is caused.

The prior publication No. CN103759548A discloses a cross flow cooling tower, which comprises a cooling tower body, wherein air inlets are arranged on the left end face and the right end face of the cooling tower body, two filler devices are arranged at the left air inlet and the right air inlet, and the two filler devices are positioned in the cooling tower body; two water distribution tanks are arranged on the upper sides of the two filling devices, and are positioned on the upper end face of the cooling tower body and are arranged corresponding to the filling devices; the upper end face of the cooling tower body is provided with an air duct, a fan is arranged at the air duct opening, and the fan can drive air in the cooling tower body to circulate; a central cylinder is arranged on the lower end surface of the cooling tower body and is connected with the water outlet; the air duct and the central cylinder are positioned between the two filling devices.

The device reduces resistance and saves energy through optimizing the ventilation system, improves the operation efficiency, but the operation efficiency which is only improved by optimizing the ventilation system is limited, and the operation efficiency is lower when the temperature is high in summer.

Disclosure of Invention

In order to solve the problems in the background art, the utility model adopts the following specific technical scheme:

a cross-flow type high-temperature cooling tower comprises a cooling installation shell, wherein a circulating cooling assembly is arranged in the cooling installation shell, a ventilation assembly is arranged on the periphery of the cooling installation shell, and a photovoltaic power supply assembly is arranged on one side of the circulating cooling assembly;

in order to achieve the purpose of circulation cooling, the circulation cooling assembly comprises a flow pipe, the flow pipe is sequentially arranged inside a cooling installation shell, a heat dissipation shell is arranged on the periphery of the flow pipe, a shunt pipe is arranged above and below the heat dissipation shell, the shunt pipe above the heat dissipation shell is connected with a circulation pump, the input end of the circulation pump is connected with a cooling box, a semiconductor refrigerating sheet is embedded inside the cooling box, and the cooling box is connected with the shunt pipe below the heat dissipation shell.

Further, a PLC controller is installed on one side of the cooling installation shell, the PLC controller is electrically connected with a temperature sensor, and the temperature sensor and the semiconductor refrigerating sheet are electrically connected with the PLC controller.

Further, in order to achieve the purpose of cooling and ventilating, the ventilating assembly comprises side air inlets which are symmetrically arranged on two sides of the cooling installation shell, the cooling installation shell is provided with installation grooves, an induced air motor is arranged in the installation grooves, and exhaust grooves are symmetrically arranged on two sides of the cooling installation shell.

Further, the induced air motor is electrically connected with the PLC.

Further, in order to achieve the purpose of photovoltaic power supply, the photovoltaic power supply assembly comprises a photovoltaic power generation plate, the photovoltaic power generation plate is electrically connected with a solar controller, one side of the solar controller is electrically connected with a storage battery, and one side of the storage battery is electrically connected with an inverter.

Further, the inverter is electrically connected with the PLC.

Further, the cooling installation casing one side is equipped with the protective housing, and PLC controller, solar controller, battery and dc-to-ac converter all are located the protective housing inside.

Compared with the prior art, the utility model provides a cross-flow type high-temperature cooling tower, which comprises the following components

The beneficial effects are that:

(1) The utility model improves the prior art, not only reduces resistance and saves energy by optimizing the ventilation system and improves the operation efficiency, but also effectively solves the problems that the operation efficiency is limited by only optimizing the ventilation system in the prior art in actual use and is lower in high temperature in summer and greatly improves the cooling effect in summer by the circulating cooling assembly.

(2) In actual use, the purpose of photovoltaic power generation is achieved by arranging the photovoltaic power generation plate, and electric energy generated by the photovoltaic power generation plate is input into the storage battery through the solar controller and is supplied to the PLC through the inverter, so that the energy-saving function is achieved.

Drawings

FIG. 1 is a schematic diagram of a main structure of a cross-flow type high temperature cooling tower according to an embodiment of the present utility model;

FIG. 2 is a perspective view of a cross-flow type high temperature cooling tower according to an embodiment of the present utility model;

FIG. 3 is a schematic view of a circulating cooling assembly in a cross-flow type high temperature cooling tower according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a photovoltaic power module in a cross-flow type high-temperature cooling tower according to an embodiment of the present utility model.

In the figure:

1. cooling the mounting shell; 2. a recirculating cooling assembly; 201. a flow tube; 202. a heat dissipation housing; 203. a shunt; 204. a circulation pump; 205. a cooling box; 206. a semiconductor refrigeration sheet; 3. a ventilation assembly; 301. a side air inlet; 302. a mounting groove; 303. an induced air motor; 304. an exhaust groove; 4. a photovoltaic power supply assembly; 401. a photovoltaic power generation panel; 402. a solar controller; 403. a storage battery; 404. an inverter; 5. a PLC controller; 6. a temperature sensor.

Detailed Description

For the purpose of further illustrating the concepts of the present application, there is provided in the drawings, which are a part of the present disclosure and are primarily intended to illustrate examples and, together with the description, serve to explain the principles of the examples, with reference to the same, wherein elements are not drawn to scale and like reference numerals are generally used to designate like elements.

The utility model is further described with reference to the accompanying drawings and the specific embodiments, as shown in fig. 1-4, a cross-flow type high-temperature cooling tower according to an embodiment of the utility model comprises a cooling installation shell 1, a circulating cooling component 2 is arranged in the cooling installation shell 1, a ventilation component 3 is arranged at the periphery of the cooling installation shell 1, and a photovoltaic power supply component 4 is arranged at one side of the circulating cooling component 2.

As shown in fig. 1-4, the circulation cooling assembly 2 comprises a flow tube 201, the flow tube 201 is sequentially installed inside a cooling installation shell 1, a heat dissipation shell 202 is arranged on the periphery of the flow tube 201, shunt tubes 203 are arranged above and below the heat dissipation shell 202, a circulation pump 204 is connected with the shunt tubes 203 above the heat dissipation shell 202, an input end of the circulation pump 204 is connected with a cooling box 205, semiconductor refrigerating sheets 206 are embedded inside the cooling box 205, the cooling box 205 is connected with the shunt tubes 203 below the heat dissipation shell 202, a PLC controller 5 is installed on one side of the cooling installation shell 1, a temperature sensor 6 is electrically connected with the PLC controller 5, and the temperature sensor 6 and the semiconductor refrigerating sheets 206 are electrically connected with the PLC controller 5.

Through the above technical scheme, through setting up flow tube 201 to reach the purpose that the thermal medium flows, through setting up circulating pump 204, thereby make the coolant liquid in the cooler bin 205 get into in the shunt tubes 203 of radiator housing 202 top through circulating pump 204, after getting into cooler bin 205, can carry out cold and heat exchange to flow tube 201, later in getting into cooler bin 205 through the shunt tubes 203 of radiator housing 202 top and recycling, the temperature that the PLC controller 5 detected through temperature sensor 6, the start-up of control semiconductor refrigeration piece 206, close when the low temperature in the cooler bin 205, open when the high temperature.

As shown in fig. 1-4, the ventilation assembly 3 includes a side air inlet 301, the side air inlet 301 is symmetrically arranged at two sides of the cooling installation housing 1, the cooling installation housing 1 is provided with an installation groove 302, an induced air motor 303 is installed inside the installation groove 302, two sides of the cooling installation housing 1 are symmetrically provided with an air exhaust groove 304, and the induced air motor 303 is electrically connected with the PLC controller 5.

Through the technical scheme, the purpose of natural wind inlet is achieved by arranging the side air inlet 301, meanwhile, the induced air motor 303 in the mounting groove 302 accelerates the natural wind to flow, and the cooling efficiency is improved through the exhaust groove 304.

As shown in fig. 1-4, the photovoltaic power supply assembly 4 includes a photovoltaic power generation plate 401, the photovoltaic power generation plate 401 is electrically connected with a solar controller 402, one side of the solar controller 402 is electrically connected with a storage battery 403, one side of the storage battery 403 is electrically connected with an inverter 404, the inverter 404 is electrically connected with a PLC controller 5, a protection casing is arranged on one side of the cooling installation casing 1, and the PLC controller 5, the solar controller 402, the storage battery 403 and the inverter 404 are all located inside the protection casing.

Through above-mentioned technical scheme, through setting up photovoltaic power generation board 401 to reach photovoltaic power generation's purpose, the electric energy that photovoltaic power generation board 401 produced is in the battery 403 through solar controller 402 input, is supplying power for PLC controller 5 through inverter 404, thereby reaches PLC controller 5, solar controller 402, battery 403 and inverter 404 protection's purpose through setting up the protective housing.

In order to facilitate understanding of the above technical solutions of the present utility model, the following describes in detail the working principle or operation manner of the present utility model in the actual process.

Working principle: the purpose of heat medium flow is achieved by arranging the flow tube 201, the circulating pump 204 is arranged, so that cooling liquid in the cooling box 205 can enter the shunt tube 203 above the heat dissipation shell 202 through the circulating pump 204, cold and heat exchange can be carried out on the flow tube 201 after the cooling liquid enters the cooling box 205, and then the cooling liquid enters the cooling box 205 through the shunt tube 203 above the heat dissipation shell 202 for recycling, and the temperature detected by the temperature sensor 6 by the PLC 5 controls the starting of the semiconductor refrigerating sheet 206, and the cooling box 205 is closed at low temperature and opened at high temperature;

the side air inlet 301 is arranged, so that the purpose of natural wind inlet is achieved, meanwhile, the induced air motor 303 in the mounting groove 302 accelerates the natural wind to flow, and the cooling efficiency is improved through the exhaust groove 304;

through setting up photovoltaic power generation board 401 to reach photovoltaic power generation's purpose, the electric energy that photovoltaic power generation board 401 produced is in the battery 403 through solar controller 402 input, is supplying power for PLC controller 5 through inverter 404, through setting up the protective housing, thereby reaches PLC controller 5, solar controller 402, battery 403 and inverter 404 protection's purpose.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "configured," "connected," "secured," "screwed," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intermediaries, or in communication with each other or in interaction with each other, unless explicitly defined otherwise, the meaning of the terms described above in this application will be understood by those of ordinary skill in the art in view of the specific circumstances.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. The transverse flow type high-temperature cooling tower is characterized by comprising a cooling installation shell (1), wherein a circulating cooling assembly (2) is arranged inside the cooling installation shell (1), a ventilation assembly (3) is arranged on the periphery of the cooling installation shell (1), and a photovoltaic power supply assembly (4) is arranged on one side of the circulating cooling assembly (2);

the circulating cooling assembly (2) comprises a flow pipe (201), the flow pipe (201) is sequentially installed inside a cooling installation shell (1), a heat dissipation shell (202) is arranged on the periphery of the flow pipe (201), shunt pipes (203) are arranged above and below the heat dissipation shell (202), the shunt pipes (203) above the heat dissipation shell (202) are connected with a circulating pump (204), the input end of the circulating pump (204) is connected with a cooling box (205), semiconductor refrigerating sheets (206) are embedded inside the cooling box (205), and the cooling box (205) is connected with the shunt pipes (203) below the heat dissipation shell (202).

2. A crossflow type high-temperature cooling tower according to claim 1, wherein a PLC controller (5) is mounted on one side of the cooling mounting housing (1), the PLC controller (5) is electrically connected with a temperature sensor (6), and the temperature sensor (6) and the semiconductor refrigerating sheet (206) are electrically connected with the PLC controller (5).

3. The cross-flow high-temperature cooling tower according to claim 2, wherein the ventilation assembly (3) comprises side air inlets (301), the side air inlets (301) are symmetrically arranged on two sides of the cooling installation shell (1), the cooling installation shell (1) is provided with an installation groove (302), the installation groove (302) is internally provided with an induced air motor (303), and two sides of the cooling installation shell (1) are symmetrically provided with exhaust grooves (304).

4. A crossflow type high temperature cooling tower according to claim 3, wherein the induced draft motor (303) is electrically connected to the PLC controller (5).

5. The cross-flow high-temperature cooling tower according to claim 4, wherein the photovoltaic power supply assembly (4) comprises a photovoltaic power generation plate (401), the photovoltaic power generation plate (401) is electrically connected with a solar controller (402), one side of the solar controller (402) is electrically connected with a storage battery (403), and one side of the storage battery (403) is electrically connected with an inverter (404).

6. The cross-flow type high-temperature cooling tower according to claim 5, wherein the inverter (404) is electrically connected to the PLC controller (5).

7. A crossflow high temperature cooling tower as claimed in claim 6, wherein the cooling installation housing (1) is provided with a protective housing on one side, and the PLC controller (5), solar controller (402), battery (403) and inverter (404) are all located inside the protective housing.