RU2692123C2 - Device for cooling and thermostating of radioelectronic equipment elements of radar stations using melting heat accumulators with additional air-liquid heat sink - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to systems for cooling and thermostating devices and units of radioelectronic equipment of radar stations installed on military caterpillar vehicles. Disclosed is a device for cooling and thermostating radioelectronic equipment elements of radar stations using melting heat accumulators with additional air-liquid heat sink, comprising a liquid cooling system comprising electric-centrifugal pumps, filter, pressure indicator, check valve, temperature controllers, air-liquid heat exchangers, ventilation devices; liquid thermal control system comprising an electric-centrifugal pump, filter, pressure indicator, heater, temperature controllers, air-liquid heat exchanger, ventilation device, thermostat; air cooling system including air-to-air heat exchangers, centrifugal fans and axial exhaust fan. Additionally, a module with radioelectronic equipment of radar stations is equipped with a heat exchanger with melting heat accumulators with air-liquid heat sink, which includes an air-liquid heat exchanger, a centrifugal fan, an electric centrifugal pump, a filter, sensor for measuring density of coolant, which is represented by nickel nitrate, pipelines, wherein heat exchanger with melting heat accumulators with air-liquid heat sink uses cooling liquid antifreeze.EFFECT: technical result is providing continuous serviceability of radar emitter in special conditions by developing a device for cooling and thermostating elements of radioelectronic equipment of radar stations using melted heat accumulators with additional air-liquid heat sink.1 cl, 1 dwg

Description

The invention relates to cooling systems and temperature control devices and electronic equipment (REA) units of radar stations (RLS) installed on military tracked vehicles (VGM).

Electronic equipment (REA) of radar stations (RLS) installed on military tracked vehicles (VGM) is operated in various conditions of climate and terrain, which have a significant impact on its performance and reliability.

The optimal values of external influencing factors (temperature, humidity, pressure, etc.) on the operation of electronic equipment installed on military tracked vehicles (VGM) are supported by cooling systems and temperature control.

Known analogues of cooling systems and temperature control devices and electronic equipment units (REA) radar stations installed on military tracked vehicles (VGM), designed for cooling and temperature control of vacuum devices and radio electronic equipment stations.

From the studied analogues, cooling systems (liquid and air) and temperature control of instruments and electronic equipment (REA) radar stations (radar) were taken as a prototype (see Article 9C32. Technical description. Part 1. General information. - 9C32.0000 TO 1982 , pp. 132-139), containing a liquid cooling system (electric centrifugal pumps, filter, pressure alarm, check valve, temperature controllers, air-to-liquid heat exchangers, ventilation devices); liquid thermostatic system (electric centrifugal pump, filter, pressure alarm, heater, thermostats, air-to-liquid heat exchanger, ventilation unit, thermostat), air-cooling system (air-to-air heat exchangers, centrifugal fans and axial exhaust fan),

The liquid cooling system (LSS) maintains the temperature of the liquid at the entrance to the vacuum devices not higher than 85 ° C. Power consumption 9.3 kW.

The system of liquid thermostating (SLT) maintains the temperature of the liquid at the entrance to the electrovacuum devices and assemblies within plus 70 ± 15 ° C. The power consumed during forced heating is 53 kW, in the operating mode - 5.3 ÷ 12 kW.

The coolant antifreeze-65 (antifreeze) is applied in the LSS and SLT. For LSS and SLT, the accumulator is common.

NWO maintains the air temperature in the central compartment with the installed CEA no higher than 85 ° C.

The data of the cooling system (liquid and air) and temperature control devices and electronic equipment (REA) radar stations (RLS) do not provide optimal conditions for the operation of radio-electronic radar in special operating conditions (high ambient temperature with simultaneous high relative humidity, low ambient temperature ).

High ambient air temperature with simultaneous high relative humidity reduces the dielectric strength of waveguides, high-voltage connections, leads to insulation breakdown and REA failure.

Low ambient temperature contributes to the change of parameters of electronic components (capacitors, inductors, resistors, etc.). It is allowed to turn on high-voltage equipment from the "cold" state (the temperature of the liquid in the life span t≥0 ° C). In this case, the output power of the transmitting system is reduced to 50% and the noise parameters of the receiving system deteriorate.

In addition, these systems have a significant power consumption, especially when forced heating (53 kW). At the same time, the overall execution time of the assigned task increases, which is a significant drawback in the system of basic measures for ensuring the preparedness of units.

Currently, in the taken prototype, the LSS and SLF systems have structurally provided devices that provide automated protection of this system against adverse external environmental factors, but have significant drawbacks.

In this regard, there is a need to develop and use a device for cooling and thermostating the elements of X-ray radar with the use of melting heat accumulators (PTA) with an additional air-liquid heat sink.

To ensure the continued operability of radio-electronic radar installed on a military tracked vehicle, it is necessary to create and maintain an optimal thermal condition for operating electronic equipment when external temperature effects change within certain limits due to the introduction of a device for cooling and temperature-regulating radio electronic equipment elements into the system of liquid cooling. radar stations using meltable heat accumulators with additional air-liquid m heat sink.

The purpose of this technical solution is to ensure the continued operability of radio-electronic radars under special conditions by developing a device for cooling and thermostating the elements of radio-electronic radars using melting heat accumulators with an additional air-liquid heat sink.

To achieve this goal, a device is proposed for cooling and thermostating elements of radioelectronic equipment of radar stations using melting heat accumulators with an additional air-liquid heat sink containing a liquid cooling system that includes centrifugal pumps, a filter, a pressure alarm, a check valve, thermostats, air-liquid heat exchangers ; ventilation devices; liquid thermostatting system, including electric centrifugal pump, filter, pressure alarm, heater, thermostats, air-to-liquid heat exchanger, ventilation device, thermostat; an air cooling system including air-to-air heat exchangers, centrifugal fans and an axial exhaust fan, characterized in that, additionally, a heat exchanger with melting heat accumulators with an air-liquid heat sink, including an air-liquid heat exchanger, a centrifugal fan, is installed in the module with REA RLS, electric centrifugal pump, filter, sensor measuring the density of the coolant, represented by nickel nitrate, pipelines, while in the heat exchanger with melting those lovymi batteries with the air-liquid heat sink used antifreeze coolant.

The proposed device is presented in the figure, which consists of a module of radioelectronic equipment of a radar station (REA RLS) 15, an information processing unit and the generation of commands 1, a temperature sensor in the module of REA RLS 14,

When turning on the heat of vacuum electronic devices of radio electronic equipment, the following are turned on (figure):

in SZhO pump 35, in SZhT pump 2, heater 4, five centrifugal fans СВО 23, 24, 25, 26, 27 and axial fan 12.

SZhT works as follows: heater 4 has two tubular heaters - a 6 kW forced heater (6) and a 3 kW operating heater (8). When the fluid temperature is less than + 56 ° C, both heaters are turned on to quickly heat up to the operating temperature of the thermostatically controlled elements of REA RLS 15.

For a fast exit to the mode (achievement of the set temperature) the GTL path has two circuits: small and large. Along the small circuit, the liquid circulates as follows: pump 2, filter 3, heater 4, housing with thermostats 5, 7, thermostatic elements of REA RLS 15, thermostat 10.

When the temperature of the liquid plus 56 ° C is reached, the thermostat 5 is turned off by the signal of the thermostat 5. Further heating is performed by the working heater 8. When the temperature of the liquid plus 69 ° C is reached, the thermostat 10 starts to open and the liquid circulates along a small and large circuit. The large circuit differs from the small air-liquid heat exchanger 11.

When the temperature of the liquid reaches + 84 ° C, the thermostat 10 fully opens the large circuit and closes the small one.

At a temperature of plus 85 ° C, the working heater 8 is turned off. During further operation, the temperature of the liquid in front of the thermostatically controlled elements of radio electronics 15 is maintained within plus 70 ± 15 ° C by switching on and off according to a signal from the thermostat 7, 14 of the working heater 8, the ventilation unit 13 and the thermostat 10. In case of a liquid reaching a temperature of 95 ° C behind thermostatically controlled elements of REA RLS 15, or a pressure drop in the hydraulic path below 5.0 kgf / cm ² , it is turned off by signals from the thermostat 23 or the pressure indicator 37 the high voltage power supply of electrovacuum devices and on the front panel of the information processing unit and the generation of commands the GENERAL FAULT warning lamp lights up.

Liquid cooling systems SZhO-I and LSS-II produce cooling of electronic devices of radio-electronic radar 15. It works in conjunction with air cooling systems and liquid thermostating.

During LSS operation, the fluid circulates in a closed circuit: pumps 13, check valve 14, filter 15, pressure indicator 37, housing with thermostats 7, 14, 29, 30, 32, 33, 34, units and blocks of radio-electronic radar 15, heat exchangers 28, 31. The liquid, passing through the cooled elements, heats up, but until the temperature of the liquid reaches + 75 ° C, the ventilation devices 26, 27 do not work, which is necessary for the GTL to quickly heat the temperature-controlled elements to the operating temperature. When the temperature of the liquid reaches 75 ° C, the temperature of the thermostats 29 and 32 in the heat exchangers 28, 31 are switched on by one ventilation device 26, 27 (LSS-I, LSS-II). If the temperature continues to rise, then at a temperature of plus 84 ° C, according to a signal from the thermostat 34, three more ventilation devices 23, 24, 25 (LSS-II) are turned on.

Shutdown of the VZhO-I and LSS-II ventilation devices is performed when the temperature of the liquid drops to + 60 ° C according to the signal from the thermostat 30.

If the temperature of the liquid at the exit from the cooled units and blocks of radio-electronic equipment reaches plus 95 ° C by signals from temperature sensors 14, 22, 25, or pressure indicator 37, the anode power supply of vacuum devices switches off and the front panel of the information processing and command generation unit lights. PUMP "GENERAL FAILURE".

During the operation of SVO, centrifugal fans 23, 24, 25, 26, 27 create a circulation of air in a closed circuit: fans, units and blocks of radio-electronic radar, air-to-air heat exchangers 28, 31 (hot circuit).

To cool the most important radio-electronic equipment of the radar, an independent fan 13 (hot circuit) is used. Axial fan 12, taking in outside air, drives it through heat exchangers 11 and emits a cold circuit into the atmosphere, thereby ensuring that the air temperature in the compartments with radio-electronic control radars is no higher than 85 ° C. When fans fail or airlock on the panel of the information processing unit and the generation of commands, the “FAIL” warning lamp lights up. When the air temperature in the compartments with radio-electronic radar rises above 85 °, the high-voltage voltage is turned off by the signal of the thermal sensor and the TOTAL FAILURE warning light on the front panel of the information processing unit and the generation of commands.

In addition, the most important radio-electronic radar units are thermostatically controlled by melting heat accumulators (PTA).

It is proposed to use the principle of sharing of melting heat accumulators and liquid heat sink system from the PTA working area. PTA uses reversible endothermic melting processes of working substances (nickel nitrate), accompanied by additional heat absorption during phase transformations of these substances from solid to liquid after they reach the phase transition temperature (70 ± 15 ° C). The proposed device is a thin-walled metal container. To reduce the thermal resistance of the melting substance, the internal capacitance of the PTA is made in the form of a cellular panel. Capacity and honeycombs are made of metal body with high thermal conductivity. To prevent the melting substance from melting completely, the air blower 18 and the electrical centrifugal pump 17 are turned on by the signal of the density measurement sensor 19, which through the filter 16 and pipelines passing through the PTA drives the cooling liquid through the heat exchanger 21, carrying out a liquid heat sink from the working area of the PTA, while maintaining optimal temperature values in the module of radio-electronic radar 15.

As a result of using the device for cooling and temperature control of radio electronic equipment elements using melting heat accumulators (PTA) with an additional air-liquid heat sink, the radar can be maintained for a longer period of time at high ambient temperatures and reduce the radar output time low temperatures, as well as reduce the cost of electrical energy.

Thus, the use of this device will ensure the maintenance of the parameters and characteristics of REA radar within the limits specified in the technical specifications for it.

Claims (1)

A device for cooling and thermostating elements of radioelectronic equipment of radar stations using melting heat accumulators with an additional air-liquid heat sink containing a liquid cooling system that includes centrifugal pumps, a filter, a pressure alarm, a check valve, thermostats, air-liquid heat exchangers, ventilation devices; liquid thermostatting system, including electric centrifugal pump, filter, pressure alarm, heater, thermostats, air-to-liquid heat exchanger, ventilation device, thermostat; an air cooling system including air-to-air heat exchangers, centrifugal fans and an axial exhaust fan, characterized in that, additionally, a heat exchanger with melting heat accumulators with an air-liquid heat sink, including an air-liquid heat exchanger, a centrifugal fan, is installed in the module with REA RLS, electric centrifugal pump, filter, sensor measuring the density of the coolant, represented by nickel nitrate, pipelines, while in the heat exchanger with melting those lovymi batteries with the air-liquid heat sink used antifreeze coolant.

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