CN211317692U - Wind tunnel heat exchange system - Google Patents

Abstract

The utility model provides a wind-tunnel heat transfer system, including heating system, refrigerating system, working shaft and wind tunnel heat exchanger, be equipped with first motorised valve and second motorised valve on heating system's hot feed liquid pipeline and the hot liquid pipeline that returns respectively, be equipped with third motorised valve and fourth motorised valve on refrigerating system's cold feed liquid pipeline and the cold liquid pipeline that returns respectively, form the feed liquid pipeline after hot feed liquid pipeline and the cold feed liquid pipeline cross and be connected with wind tunnel heat exchanger's inlet, it is connected with wind tunnel heat exchanger's delivery port to form the liquid pipeline that returns after crossing with the cold liquid pipeline that returns to the hot liquid pipeline, the feed liquid pipeline is connected through electric three-way valve with the liquid pipeline that returns, the working shaft sets up on returning the liquid pipeline, be equipped with water-water heat exchanger between cold feed liquid pipeline and the liquid pipeline that returns. The utility model has the advantages that: PID adjustment can be carried out on the temperature detected by the sensor, and the liquid supply temperature and precision of the heat exchanger in the test hall meet target requirements.

Description

Wind tunnel heat exchange system

Technical Field

The utility model relates to a wind-tunnel heat transfer system field, more specifically say and relate to a wind-tunnel heat transfer system.

Background

The connected transonic wind tunnel needs to be cooled or heated to maintain the total temperature stability of the test airflow, and the external cooling water flows through a heat exchanger arranged on a heat exchange section of the wind tunnel to exchange heat with the wind tunnel airflow. Traditionally, the change of the total heat transfer coefficient is small by changing the flow of cooling water through a variable frequency water pump, the change of the heat transfer temperature difference is limited, and as a result, the total temperature regulation range of the air flow in the wind tunnel test is narrow, and the control precision is poor.

Disclosure of Invention

The utility model overcomes not enough among the prior art provides a wind-tunnel heat transfer system.

The purpose of the utility model is realized by the following technical scheme.

The wind tunnel heat exchange system comprises a heating system, a refrigerating system, a water supply pump and a wind tunnel heat exchanger, wherein a first electric valve and a second electric valve are respectively arranged on a hot liquid supply pipeline and a hot liquid return pipeline of the heating system, a third electric valve and a fourth electric valve are respectively arranged on a cold liquid supply pipeline and a cold liquid return pipeline of the refrigerating system, the hot liquid supply pipeline and the cold liquid supply pipeline are intersected to form a liquid supply pipeline and are connected with a liquid inlet of the wind tunnel heat exchanger, the hot liquid return pipeline and the cold liquid return pipeline are intersected to form a liquid return pipeline which is connected with a water outlet of the wind tunnel heat exchanger, the liquid supply pipeline is connected with the liquid return pipeline through an electric three-way valve, the water supply pump is arranged on the liquid return pipeline, a water-water heat exchanger is arranged between the cold liquid supply pipeline and the liquid return pipeline, and a normal pressure storage tank is arranged on the liquid return pipeline.

Further, the heating system comprises a main heater, a water outlet of the main heater is connected with the hot liquid supply pipe, a water inlet of the main heater is connected with the hot liquid return pipe, and a pressure storage tank is arranged on a channel between the second electric valve and the main heater.

Furthermore, the refrigerating system comprises a refrigerating unit, a chilled water pump and a system constant pressure device, wherein the refrigerating unit, the chilled water pump and the system constant pressure device are sequentially connected.

Further, the chilled water pumps are in three groups.

Further, there are two electric three-way valves, one of which is disposed between the atmospheric storage tank and the water pump, and the other of which is disposed between the water-water heat exchanger and the chilled water pump.

Further, the water supply pumps are four groups.

Further, the system also comprises a PID controller, and the PID controller accurately controls the reflux quantity of the first electric valve, the second electric valve, the third electric valve, the fourth electric valve and the electric three-way valve.

Furthermore, a temperature sensor is arranged at the air inlet and the air outlet of the wind tunnel heat exchanger and is connected with the PID controller.

The utility model has the advantages that:

a normal pressure storage tank is arranged to store the cooled liquid, so that the amount of low-temperature water is ensured;

the liquid supply and the return liquid of the wind tunnel heat exchanger are mixed in proportion through an electric three-way valve in a cooling or heating state, so that the liquid supply temperature and the precision of the heat exchanger meet target requirements;

the system can reach the low temperature of-15 ℃, the air inlet and outlet of the heat exchanger are widened to form distributed temperature sensors, PID adjustment is carried out on the temperature sensors according to the temperature detected by the sensors, and the liquid supply temperature and precision of the heat exchanger in a test hall meet target requirements.

Drawings

FIG. 1 is a schematic diagram of the system of the present invention;

in the figure:

1. a heating system; 2. a refrigeration system; 3. a water supply pump; 4. a wind tunnel heat exchanger;

5. a first electrically operated valve; 6. a second electrically operated valve; 7. a third electrically operated valve; 8. a fourth electrically operated valve;

9. a hot liquid supply conduit; 10. a hot return line; 11. a cold liquid supply conduit; 12. a cold return liquid pipe;

13. a liquid supply conduit; 14. a liquid return pipeline; 15. a main heater; 16. an electric three-way valve;

17. a pressure storage tank; 18. a refrigeration unit; 19. a chilled water pump; 20. a system constant pressure device;

21. a water-to-water heat exchanger; 22. a normal pressure storage tank; 23. a temperature sensor; 24. an electric three-way valve.

Detailed Description

The technical solution of the present invention is further explained by the following specific examples.

Example 1

As shown in fig. 1, the wind tunnel heat exchange system comprises a heating system 1, a refrigerating system 2, a water supply pump 3 and a wind tunnel heat exchanger 4, a first electric valve 5 and a second electric valve 6 are respectively arranged on a hot liquid supply pipeline 9 and a hot liquid return pipeline 10 of the heating system 1, a third electric valve 7 and a fourth electric valve 8 are respectively arranged on a cold liquid supply pipeline 11 and a cold liquid return pipeline 12 of the refrigerating system 2, the hot liquid supply pipeline 9 and the cold liquid supply pipeline 11 are intersected to form a liquid supply pipeline 13 and are connected with a liquid inlet of the wind tunnel heat exchanger 4, the hot liquid return pipeline 10 and the cold liquid return pipeline 12 are intersected to form a liquid return pipeline 14 and are connected with a water outlet of the wind tunnel heat exchanger 4, the liquid supply pipeline 13 and the liquid return pipeline 14 are connected through an electric three-way valve 16, the water supply pump 3 is arranged on the liquid return pipeline 12, a water-water heat exchanger 21 is, the liquid return pipeline 14 is provided with a normal pressure storage tank 22.

Example 2

As shown in fig. 1, the wind tunnel heat exchange system comprises a heating system 1, a refrigerating system 2, a water supply pump 3 and a wind tunnel heat exchanger 4, a first electric valve 5 and a second electric valve 6 are respectively arranged on a hot liquid supply pipeline 9 and a hot liquid return pipeline 10 of the heating system 1, a third electric valve 7 and a fourth electric valve 8 are respectively arranged on a cold liquid supply pipeline 11 and a cold liquid return pipeline 12 of the refrigerating system 2, the hot liquid supply pipeline 9 and the cold liquid supply pipeline 11 are intersected to form a liquid supply pipeline 13 and are connected with a liquid inlet of the wind tunnel heat exchanger 4, the hot liquid return pipeline 10 and the cold liquid return pipeline 12 are intersected to form a liquid return pipeline 14 and are connected with a water outlet of the wind tunnel heat exchanger 4, the liquid supply pipeline 13 and the liquid return pipeline 14 are connected through an electric three-way valve 16, the water supply pump 3 is arranged on the liquid return pipeline 12, a water-water heat exchanger 21 is, the liquid return pipeline 14 is provided with a normal pressure storage tank 22;

the heating system 1 comprises a main heater 15, the water outlet of the main heater 15 is connected with a hot liquid supply pipe 9, the water inlet of the main heater 15 is connected with a hot liquid return pipe 10, a pressure storage tank 17 is arranged on a passage between the second electric valve 6 and the main heater 15, and the power of the main heater 15 is 0-1200 kW;

the refrigerating system 2 comprises a refrigerating unit 18, a chilled water pump 19 and a system constant pressure device 20, wherein the refrigerating unit 18, the chilled water pump 19 and the system constant pressure device 20 are sequentially connected;

the three groups of the freezing water pumps 19 are used, when the refrigerator is used in daily life, two freezing water pumps 19 work, and one additional freezing water pump 19 is used for standby;

the water supply pumps 3 are four groups, when the water supply device is used daily, the three groups of water supply pumps 3 work, and an additional water supply pump 3 is reserved for standby.

There are two electric three-way valves 16, one electric three-way valve 16 being provided between the atmospheric storage tank 22 and the water supply pump 3, and the other electric three-way valve 24 being provided between the water-water heat exchanger 21 and the chilled water pump 19.

Example 3

As shown in fig. 1, the wind tunnel heat exchange system comprises a heating system 1, a refrigerating system 2, a water supply pump 3 and a wind tunnel heat exchanger 4, a first electric valve 5 and a second electric valve 6 are respectively arranged on a hot liquid supply pipeline 9 and a hot liquid return pipeline 10 of the heating system 1, a third electric valve 7 and a fourth electric valve 8 are respectively arranged on a cold liquid supply pipeline 11 and a cold liquid return pipeline 12 of the refrigerating system 2, the hot liquid supply pipeline 9 and the cold liquid supply pipeline 11 are intersected to form a liquid supply pipeline 13 and are connected with a liquid inlet of the wind tunnel heat exchanger 4, the hot liquid return pipeline 10 and the cold liquid return pipeline 12 are intersected to form a liquid return pipeline 14 and are connected with a water outlet of the wind tunnel heat exchanger 4, the liquid supply pipeline 13 and the liquid return pipeline 14 are connected through an electric three-way valve 16, the water supply pump 3 is arranged on the liquid return pipeline 12, a water-water heat exchanger 21 is, the liquid return pipeline 14 is provided with a normal pressure storage tank 22;

the heating system 1 comprises a main heater 15, the water outlet of the main heater 15 is connected with a hot liquid supply pipe 9, the water inlet of the main heater 15 is connected with a hot liquid return pipe 10, a pressure storage tank 17 is arranged on a passage between the second electric valve 6 and the main heater 15, and the power of the main heater 15 is 0-1200 kW;

the refrigerating system 2 comprises a refrigerating unit 18, a chilled water pump 19 and a system constant pressure device 20, wherein the refrigerating unit 18, the chilled water pump 19 and the system constant pressure device 20 are sequentially connected;

the three groups of the freezing water pumps 19 are used, when the refrigerator is used in daily life, two freezing water pumps 19 work, and one additional freezing water pump 19 is used for standby;

the water supply pumps 3 are four groups, when the water supply device is used daily, the three groups of water supply pumps 3 work, and an additional water supply pump 3 is reserved for standby.

There are two electric three-way valves 16, one electric three-way valve 16 being provided between the atmospheric storage tank 22 and the water supply pump 3, and the other electric three-way valve 16 being provided between the water-water heat exchanger 24 and the chilled water pump 19.

The system further comprises a PID controller, the PID controller accurately controls the return flow of the first electric valve 5, the second electric valve 6, the third electric valve 7, the fourth electric valve 8 and the electric three-way valve 16, a temperature sensor 23 is arranged at an air inlet and an air outlet of the wind tunnel heat exchanger 4, and the temperature sensor 23 is connected with the PID controller.

The working principle of the wind tunnel heat exchanger loop is as follows:

the system is divided into 4 limit working conditions for operation, the air outlet temperature requirement after the heat exchanger is constant when each working condition operates, and the heat generated by the whole system is constant at the moment; that is, when operating in this operating mode, the cooling capacity of the refrigeration unit (or the heating capacity of the main heater) should be substantially constant, regardless of temperature fluctuations caused by load changes in the operating mode.

In the actual test, whether the system is in a cooling working condition or a heating working condition is manually selected on the operation screen in the test;

the working principle of the cooling working condition of the heat exchanger loop is as follows: the working principle diagram of the cooling working condition is shown in the figure 1, and the working principle is as follows: the first electric valve 5 and the second electric valve 6 close the main heater and close the inlet and the outlet of the main heater; providing 50% concentration ice river solution at-22 deg.c to-15 deg.c (precision of +/-0.5 deg.c) by refrigerating unit in refrigerating machine room, providing energy with water pump, heat exchanging with ice river in wind tunnel system via plate exchanger in storage tank to cool the ice river solution in wind tunnel system to-17 deg.c to 60 deg.c, regulating with electric three-way valve 16 in unit side according to actual temperature requirement, and storing to 10m³The storage tank 22 is used for carrying out PID adjustment on the electric three-way valve 17 according to the signal of the temperature sensor 23 behind the heat exchanger 4, so that the liquid supply temperature can be accurately adjusted; the liquid supply and the return liquid of the wind tunnel heat exchanger are mixed in proportion through an electric three-way valve 16 (PID adjustment is carried out on the liquid supply temperature sensor 23 in front of the heat exchanger 4), so that the liquid supply temperature and the precision of the heat exchanger in a test hall can meet target requirements;

the relation between the liquid supply temperature of the wind tunnel heat exchanger and the air outlet temperature of the wind tunnel heat exchanger is found and set in field debugging; under the working condition that the wind tunnel load is unchanged during the test, the air outlet temperature can be kept constant without changing the air quantity after the liquid supply temperature is constant.

The air outlet temperature control logic: the wind tunnel heat exchange system adopts a control logic of constant water quantity and variable liquid supply temperature, and the relation between the liquid supply temperature and the air outlet temperature of the heat exchanger is found out for linear adjustment during system debugging; for the accurate adjustment of the actual liquid supply temperature, besides the accuracy of the liquid supply temperature of the refrigerating unit, electric three-way valves 16 and 17 configured by the system mix the liquid supply of the refrigerating unit and the liquid return of the heat exchanger so as to realize the accuracy of the total liquid supply temperature of the heat exchanger;

the working principle of the heating working condition of the heat exchanger loop is as follows:

the working principle diagram of the heating working condition is shown in the figure 1, and the working principle is as follows: the refrigerating unit is not opened, the third electric valve 7 and the fourth electric valve 8 after the storage tank of the refrigerating system is closed, the system liquid path is switched to the heating system to operate, the heating unit can carry out stepless regulation according to the target liquid outlet temperature, and the unit can adapt to flow change and automatically carry out liquid outlet temperature control and safety protection control.

The liquid supply and the return liquid of the wind tunnel heat exchanger are mixed in proportion through an electric three-way valve 16 (PID adjustment is carried out on the liquid supply and the return liquid according to a liquid supply temperature sensor 23 in front of the heat exchanger), so that the liquid supply temperature and the precision of the heat exchanger 4 reach the target requirements;

the air outlet temperature control logic: the wind tunnel heat exchange system adopts a control logic of constant water quantity and variable liquid supply temperature, and the relation between the liquid supply temperature and the air outlet temperature of the heat exchanger is found out for linear adjustment during system debugging; for the accurate adjustment of the actual liquid supply temperature, besides the liquid supply temperature accuracy of the main heater provided by the heating system, the electric three-way valves 16 and 17 configured by the system mix the liquid supply of the main heater and the liquid return of the heat exchanger so as to realize the accuracy of the total liquid supply temperature of the heat exchanger.

The above description has been made in detail for the three embodiments of the present invention, but the above description is only for the preferred embodiment of the present invention, and should not be construed as limiting the scope of the present invention. All the equivalent changes and improvements made according to the application scope of the present invention should still fall within the patent coverage of the present invention.

Claims (8)

1. Wind tunnel heat transfer system, its characterized in that: comprises a heating system, a refrigerating system, a water supply pump and an air hole heat exchanger, wherein a first electric valve and a second electric valve are respectively arranged on a hot liquid supply pipeline and a hot liquid return pipeline of the heating system, a third electric valve and a fourth electric valve are respectively arranged on a cold liquid supply pipeline and a cold liquid return pipeline of the refrigerating system, the hot liquid supply pipeline and the cold liquid supply pipeline are intersected to form a liquid supply pipeline and are connected with a liquid inlet of the wind tunnel heat exchanger, the hot liquid return pipeline and the cold liquid return pipeline are intersected to form a liquid return pipeline which is connected with a water outlet of the wind tunnel heat exchanger, the liquid supply pipeline is connected with the liquid return pipeline through an electric three-way valve, the water supply pump is arranged on the liquid return pipeline, and a water-water heat exchanger is arranged between the cold liquid supply pipeline and the liquid return pipeline, and a normal pressure storage tank and the water-water heat exchanger are sequentially arranged on the liquid return pipeline along the liquid return direction.

2. The wind tunnel heat exchange system of claim 1, wherein: the heating system comprises a main heater, a water outlet of the main heater is connected with the hot liquid supply pipe, a water inlet of the main heater is connected with the hot liquid return pipe, and a pressure storage tank is arranged on a channel between the second electric valve and the main heater.

3. The wind tunnel heat exchange system of claim 1, wherein: the refrigerating system comprises a refrigerating unit, a chilled water pump and a system constant pressure device, wherein the refrigerating unit, the chilled water pump and the system constant pressure device are sequentially connected.

4. The wind tunnel heat exchange system of claim 3, wherein: the chilled water pumps are divided into three groups.

5. The wind tunnel heat exchange system of claim 4, wherein: the number of the electric three-way valves is two, one electric three-way valve is arranged between the normal-pressure storage tank and the water pump, and the other electric three-way valve is arranged between the water-water heat exchanger and the chilled water pump.

6. The wind tunnel heat exchange system of claim 1, wherein: the water supply pumps are four groups.

7. The wind tunnel heat exchange system according to any one of claims 1 to 6, wherein: the system further comprises a PID controller, wherein the PID controller accurately controls the first electric valve, the second electric valve, the third electric valve, the fourth electric valve and the backflow amount of the electric three-way valve.

8. The wind tunnel heat exchange system of claim 7, wherein: and temperature sensors are arranged at the air inlet and the air outlet of the wind tunnel heat exchanger and are connected with the PID controller.

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