CN209945060U - Multi-working-condition energy-saving cross-flow cooling tower - Google Patents

Abstract

The utility model discloses a multi-working condition energy-saving cross flow type cooling tower, which comprises a tower body; a power plant integrated within the tower; a heat dissipation device is arranged at the air inlet end of the tower body; the upper part of the heat dissipation device is provided with a water distribution device; the heat dissipation device comprises two heat dissipation components, namely a first heat dissipation component and a second heat dissipation component; the water distribution device comprises two water distribution components, namely a first water distribution component and a second water distribution component; the first radiating assembly and the first water distribution assembly form a first processing unit, and the second radiating assembly and the second water distribution assembly form a second processing unit. The utility model discloses a cooling tower internal design has two sets of processing unit, can switch or adjust every processing unit's handling capacity and opening state according to different work condition, and two processing unit independent control respectively have reduced the technological requirement to power component, reduce the treatment cost.

Description

Multi-working-condition energy-saving cross-flow cooling tower

Technical Field

The utility model relates to a cooling arrangement technical field especially relates to an energy-conserving crossflow cooling tower of multiplex condition.

Background

A cross flow cooling tower (cross flow cooling tower) is a device that cools water. The water flow falls vertically from the upper part of the tower, the air flows horizontally through the water spraying packing, and the air flow is orthogonal to the water flow in the cooling tower. The water quality of cooling water is divided into: open columns and closed columns. The method is divided into the following steps according to noise levels: normal type (P), low noise type (D), ultra low noise type (C), industrial type (G).

Most of cross-flow cooling towers in the prior art are powered by an internal power assembly (exhaust fan), then external air enters through an air inlet on the side surface of the cooling tower, and under the driving of the power assembly, the air enters a processing unit to be processed by a process and finally is discharged through an air outlet at the power assembly.

However, most of the cross-flow cooling towers in the prior art are in a single treatment mode, that is, only one set of treatment unit is provided, so that once the air volume/treatment volume needs to be adjusted, the process requirement on an internal power assembly is high, and the use cost and the treatment cost are increased.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a practice thrift cost, energy-conserving crossflow cooling tower of handling capacity adjustable multiplex condition.

In order to achieve the above object, the present invention provides the following technical solutions:

the utility model discloses an energy-conserving crossflow cooling tower of multiplex condition, include:

a tower body;

a power plant integrated within the tower;

a heat dissipation device is arranged at the air inlet end of the tower body;

the upper part of the heat dissipation device is provided with a water distribution device;

the tower body is also internally provided with a control assembly;

the working states of the power device and the water distribution device are controlled by the control component;

the control assembly is provided with a monitoring host and a temperature and humidity sensor electrically connected with the monitoring host;

the temperature and humidity sensor is used for monitoring ambient temperature and humidity;

the data detected by the temperature and humidity sensor is communicated with the monitoring host, and the monitoring host controls the power device and the water distribution device to work by receiving the data of the temperature and humidity sensor;

the heat dissipation device comprises two heat dissipation components, namely a first heat dissipation component and a second heat dissipation component;

the water distribution device comprises two water distribution components, namely a first water distribution component and a second water distribution component;

the first radiating assembly and the first water distribution assembly form a first processing unit, and the second radiating assembly and the second water distribution assembly form a second processing unit.

Further, the inside filler that all fills of first radiator unit and second radiator unit, power device includes two power components, is first power component and second power component respectively, first power component and second power component all have and are controlled by control assembly's air exhauster, the air exhauster is taken out the outside air in the tower body and is passed through the filler in first radiator unit and the second radiator unit respectively.

Furthermore, the first water distribution assembly and the second water distribution assembly are provided with spray heads communicated with external water supply equipment, the spray heads of the first water distribution assembly face the first heat dissipation assembly, and the spray heads of the second water distribution assembly face the second heat dissipation assembly.

Furthermore, two air inlets which are arranged towards the horizontal direction are symmetrically arranged on the side surface of the tower body, and the two air inlets are respectively a first air inlet and a second air inlet;

the first heat dissipation assembly is arranged at the first air inlet and is obliquely arranged towards the inside of the tower body;

the second heat dissipation assembly is arranged at the outlet of the second air inlet and is obliquely arranged towards the inside of the tower body;

the first heat dissipation assembly and the second heat dissipation assembly are arranged in a mirror image mode.

In the technical scheme, the utility model provides an energy-conserving crossflow cooling tower of multiplex condition, it has following beneficial effect:

the utility model discloses a cooling tower internal design has two sets of processing unit, can switch or adjust every processing unit's handling capacity and opening state according to different work condition, and two processing unit independent control respectively have reduced the technological requirement to power component, reduce the treatment cost.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

Fig. 1 is a schematic structural diagram of a multi-operating-condition energy-saving cross-flow cooling tower provided by an embodiment of the present invention.

Description of reference numerals:

1. a tower body; 2. a control component;

301. a first heat dissipation assembly; 302. a second heat dissipation assembly;

401. a first power assembly;

501. a first water distribution assembly; 502. a second water distribution component;

601. a first air inlet; 602. a second air inlet.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1;

the utility model discloses an energy-conserving crossflow cooling tower of multiplex condition, include:

a tower body 1;

a power plant integrated in the tower body 1;

the air inlet end of the tower body 1 is provided with a heat dissipation device;

the upper part of the heat dissipation device is provided with a water distribution device;

the tower body 1 is also internally provided with a control assembly 2;

the working states of the power device and the water distribution device are controlled by the control component 2;

the control component 2 is provided with a monitoring host and a temperature and humidity sensor electrically connected with the monitoring host;

the temperature and humidity sensor is used for monitoring ambient temperature and humidity;

the data detected by the temperature and humidity sensor is communicated with the monitoring host, and the monitoring host controls the power device and the water distribution device to work by receiving the data of the temperature and humidity sensor;

the heat dissipation device comprises two heat dissipation components, namely a first heat dissipation component 301 and a second heat dissipation component 302;

the water distribution device comprises two water distribution components, namely a first water distribution component 501 and a second water distribution component 502;

the first heat dissipation assembly 301 and the first water distribution assembly 501 form a first processing unit, and the second heat dissipation assembly 302 and the second water distribution assembly 502 form a second processing unit.

Preferably, in this embodiment, the first heat dissipation assembly 301 and the second heat dissipation assembly 302 are both filled with filler, the power device includes two power assemblies, which are the first power assembly 401 and the second power assembly, respectively, each of the first power assembly 401 and the second power assembly has an exhaust fan controlled by the control assembly 2, and the exhaust fan draws outside air into the tower body 1 and passes through the filler in the first heat dissipation assembly 301 and the second heat dissipation assembly 302, respectively.

The first water distribution component 501 and the second water distribution component 502 both have nozzles communicated with external water supply equipment, the nozzle of the first water distribution component 501 faces the first heat dissipation component 301, and the nozzle of the second water distribution component 502 faces the second heat dissipation component 302.

The side surface of the tower body 1 is symmetrically provided with two air inlets which are arranged towards the horizontal direction, and the two air inlets are a first air inlet 601 and a second air inlet 602 respectively;

the first heat dissipation assembly 301 is installed at the first air inlet 601, and the first heat dissipation assembly 301 is obliquely arranged towards the inside of the tower body 1;

the second heat dissipation assembly 302 is installed at the second air inlet 602, and the second heat dissipation assembly 302 is obliquely arranged towards the inside of the tower body 1;

the first heat dissipation assembly 301 and the second heat dissipation assembly 302 are arranged in mirror image with each other.

The functional components inside the tower body 1 of the embodiment are controlled by the control assembly 2, the control assembly 2 adopts a conventional programmable controller, a control program can be set in advance according to actual engineering requirements, for example, a Mitsubishi MELSEC-F FX series programmable controller, the program is set in advance according to required process conditions, then the control communication is carried out between the control assembly and the temperature and humidity sensor integrated on the tower body 1, the temperature and humidity sensor is used for monitoring the temperature and humidity conditions inside the tower body 1 and outside the tower body 1, collected temperature and humidity signals are sent to the controller, the controller drives any power assembly to work, and finally independent control and work of each processing unit are achieved.

In the technical scheme, the utility model provides an energy-conserving crossflow cooling tower of multiplex condition, it has following beneficial effect:

the utility model discloses a cooling tower internal design has two sets of processing unit, can switch or adjust every processing unit's handling capacity and opening state according to different work condition, and two processing unit independent control respectively have reduced the technological requirement to power component, reduce the treatment cost.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (4)

1. Energy-conserving crossflow cooling tower of multiplex condition, its characterized in that includes:

a tower body (1);

a power plant integrated in the tower (1);

a heat dissipation device is arranged at the air inlet end of the tower body (1);

the upper part of the heat dissipation device is provided with a water distribution device;

the tower body (1) is also internally provided with a control assembly (2);

the working states of the power device and the water distribution device are controlled by the control component (2);

the control assembly (2) is provided with a monitoring host and a temperature and humidity sensor electrically connected with the monitoring host;

the temperature and humidity sensor is used for monitoring ambient temperature and humidity;

the data detected by the temperature and humidity sensor is communicated with the monitoring host, and the monitoring host controls the power device and the water distribution device to work by receiving the data of the temperature and humidity sensor;

the heat dissipation device comprises two heat dissipation components, namely a first heat dissipation component (301) and a second heat dissipation component (302);

the water distribution device comprises two water distribution components, namely a first water distribution component (501) and a second water distribution component (502);

the first heat dissipation assembly (301) and the first water distribution assembly (501) form a first processing unit, and the second heat dissipation assembly (302) and the second water distribution assembly (502) form a second processing unit.

2. The multi-operating-condition energy-saving cross-flow cooling tower of claim 1, wherein the first heat dissipation assembly (301) and the second heat dissipation assembly (302) are filled with filler, the power device comprises two power assemblies, namely a first power assembly (401) and a second power assembly, the first power assembly (401) and the second power assembly are provided with exhaust fans controlled by the control assembly (2), and the exhaust fans draw outside air into the tower body (1) and pass through the filler in the first heat dissipation assembly (301) and the filler in the second heat dissipation assembly (302), respectively.

3. The multi-operating-condition energy-saving cross-flow cooling tower of claim 2, wherein the first water distribution assembly (501) and the second water distribution assembly (502) are provided with spray heads communicated with external water supply equipment, the spray heads of the first water distribution assembly (501) face the first heat dissipation assembly (301), and the spray heads of the second water distribution assembly (502) face the second heat dissipation assembly (302).

4. The multi-working-condition energy-saving cross-flow cooling tower of claim 1, wherein two air inlets which are opened towards the horizontal direction are symmetrically arranged on the side surface of the tower body (1), and the two air inlets are respectively a first air inlet (601) and a second air inlet (602);

the first heat dissipation assembly (301) is installed at the first air inlet (601), and the first heat dissipation assembly (301) is obliquely arranged towards the inner side of the tower body (1);

the second heat dissipation assembly (302) is installed at the second air inlet (602), and the second heat dissipation assembly (302) is obliquely arranged towards the inside of the tower body (1);

the first heat dissipation assembly (301) and the second heat dissipation assembly (302) are arranged in a mirror image mode.

Images