RU2156923C1 - Self-contained air-conditioner with water condenser - Google Patents

Abstract

FIELD: transport facilities; closed hermetic reservoirs. SUBSTANCE: self-contained air-conditioner is provided with two- position flow regulator equipped with drive, heating heat exchanger, maximum and minimum air temperature setters, two comparison circuits, two control command formers for closing and opening the flow regulator respectively; temperature sensor is connected to one input of above- mentioned comparison circuits; second input of these circuits is connected to outputs of maximum and minimum air temperature setters respectively; outputs of comparison circuits are connected with respective inputs of control command formers for closing and opening the flow regulators, their outputs being connected with two-position regulator drive. EFFECT: possibility of continuous accumulation of moisture without additional consumption of power. 1 dwg

Description

 Stand-alone air conditioning is designed primarily for use in confined spaces of inhabited compartments of spacecraft, submarines and ground vehicles with a sealed volume for the crew, where it is necessary to collect the moisture released by the crew and at the same time control the air temperature in the sealed volume.

 There are various types of control systems for the temperature and humidity regime of closed volumes, one of which is autonomous air conditioners. Their principle of operation is almost the same, they differ in control systems and the temperature level of the refrigerant in the evaporator. Such systems are given in the book of V. Maake, G.Yu. Eckert, and J.L. Koshpen. "POLMANN - A Textbook on Refrigeration Engineering, ed. Moscow State University, 1998, p. 326, in the book of authors M.R. Barsky et al." Electrical Equipment and Air Conditioning for Passenger Cars, "Transzheleznodorozhdat, 1963, p. 165, and A number of other publications: The temperature in the chamber is controlled by changing the flow rate of the refrigerant through the evaporator-air cooler, which ensures a constant set temperature of evaporation in the tubes of this heat exchanger. As a rule, such systems are similar to control systems for the refrigeration circuit of household lodilnikov cause frequent cycles of turning on and off of the compressor.

 In this case, the compressor is selected based on the maximum possible load on the camera, thereby its energy consumption is also quite large. In order to thaw moisture frozen out on the surface of the air cooler, the compressor is forcedly turned off, which is one of the drawbacks of such a system. Please note that during the defrost period, the humidity in the chamber rises. A typical temperature-humidity control system, which uses an air temperature sensor in the chamber to control the temperature and humidity conditions, is presented in the aforementioned book of authors V. Maake, G.Yu. Ekkert, Zh.L. Koshpen "POLMANN - Textbook on refrigeration engineering" ; ed. Moscow State University, 1998, on page 217. In this system, the air temperature is regulated by turning the compressor on and off according to the signal from this sensor. The disadvantage of this type of system is the impossibility of collecting moisture, and periods of compressor shutdown, as well as an increase in air humidity during the defrost period.

 One of the analogues of the proposed air conditioner is the BK-1500 air conditioner, the device and the principle of operation of which are described on pages 254-255 in the book by O. Ya. Kokorin "Air conditioning units", Moscow, ed. Mechanical engineering, 1978. The operation of the refrigeration compressor is carried out by a sensor team that monitors the temperature of the air in the served room. When the internal temperature decreases from the controlled value, the sensor acts on the compressor drive and stops it. When the internal air temperature rises, the compressor motor is switched off by a command from the specified sensor.

 The prototype of the claimed air conditioner is a stand-alone air conditioner KV1-17 with a water condenser, described in the book by O. Ya. Kokorin "Air conditioning units", Moscow, ed. Engineering, 1978, pp. 247-249. The specified air conditioner includes a compressor, a water condenser, a thermostatic valve, an evaporator with a fan, a two-cavity heat exchanger, and an air temperature sensor installed at the entrance to the evaporator. The temperature sensor monitors the temperature of the air in the refrigerated volume, and when the temperature drops, the sensor gives a command to turn off the compressor, and when the temperature rises, to turn it on.

 The disadvantage of the prototype is that during periods of shutdown of the compressor, which at low heat load can reach almost 50-60% of the daily time, moisture released into the air of a closed volume is not collected on the surface of the evaporator, which reduces the comfort of a person in this volume. When using this type of air conditioner on board the Mir orbital space station, extremely undesirable consequences of this drawback appeared. Wet air, falling on the cold structural elements of the station, began to condense, after which moisture particles in the conditions of zero gravity moved droplet in the air flows created by the fan. Periodically, there was a danger of drip moisture entering the electronic devices blown by the fans and breaking them down due to a short circuit. During continuous operation of the air conditioner (forced operation with the control channel turned off), the moisture released in the pressurized compartment constantly condensed in the evaporator-air cooler, therefore the above danger was eliminated, however, the air temperature in the inhabited volume of the thermal compartment decreased below the permissible value. The crew members were particularly uncomfortable with a cold air stream leaving the air conditioner evaporator evaporator. To heat the air during the operation of the air conditioner, the crew was forced to turn on electric heating devices to dry the air, which imposed restrictions on energy-intensive work on board the station during this period of time.

 The objective of the invention was the creation of an autonomous air conditioner that allows you to adjust the temperature of the cooling and air drying out of the heat exchanger during the continuous process of air drying in a closed volume due to the use of heat of compressed refrigerant, i.e. without the cost of additional electricity.

 The solution to this problem is achieved by the fact that the air conditioner contains a compressor, a water condenser, a thermostatic valve, an evaporator, a two-cavity heat exchanger, one cavity of which is connected to the outlet of the water condenser and the inlet of the thermostatic valve, and the other cavity is connected to the evaporator output and the compressor inlet, and air temperature sensor, a two-position flow controller with a drive, installed at the outlet of the compressor, a heating heat exchanger, with one output of the controller with it is single with the input of the heating heat exchanger, the other output of the controller is connected to the output of the heating heat exchanger and the input of the condenser, the heating heat exchanger is installed in the air channel at the outlet of the evaporator, the air temperature sensor is installed through the air channel at the outlet of the heating heat exchanger, and the maximum and minimum allowable values are entered air temperatures, two comparison schemes, two shapers of control commands for closing and opening the controller, respectively Of course, the temperature sensor is connected to one input of the mentioned comparison circuits, and the outputs of the sensors of the maximum allowable and minimum allowable air temperatures are connected to the second input of these circuits, respectively, the outputs of the comparison circuits are connected to the corresponding inputs of the shapers of the control commands for closing and opening the controllers, and their outputs are driven by a two-position controller.

In Fig 1 shows the proposed autonomous air conditioning, where
1 - compressor
2 - water condenser,
3 - thermostatic valve
4 - evaporator with fan,
5 - two-cavity heat exchanger,
6 - on-off controller
7 - heating heat exchanger,
8 - setpoint minimum permissible air temperature,
9 - setpoint maximum permissible air temperature,
10 is a comparison diagram,
11 is a comparison diagram,
12 - shaper control team to open the regulator,
13 - shaper control team to close the regulator,
14 - regulator drive,
15 - air temperature sensor.

 The stand-alone air conditioner includes a compressor 1, the output of which is equipped with a two-position controller 6 with drive 14, while one output of the controller 6 is connected to the input of the heating heat exchanger 7, the other output of the controller 6 is connected to the output of this heat exchanger 7 and the input of the water condenser 2. Output of the water condenser 2 connected through one of the cavities of the heat exchanger 5 with the input of the thermostatic valve 3, and the output of the thermostatic valve 3 is connected to the input of the evaporator 4 with a fan, and the output of the evaporator 4 through another the cavity of the heat exchanger 5 is hydraulically connected to the inlet of the compressor 1. Through the air channel, the heating heat exchanger 7 is installed at the outlet of the evaporator 4 with a fan, and the air temperature sensor 15 is installed at the air outlet of the heating heat exchanger 4.

 The air temperature sensor 15 is electrically connected to one of the two inputs of the comparison circuits 10 and 11, while the output of the set point of the minimum allowable air temperature 8 is electrically connected to the second input of the comparison circuit 10, and the output of the set point of the maximum allowable air temperature is connected to the second input of the comparison circuit 11. The output of the comparison circuit 10 is electrically connected to the input of the shaper of the control command 13 to close the controller 6, and the output of the comparison circuit 11 is connected to the shaper of the control command 12 to open the controller 6, while the outputs of these shapers are connected to the drive 14 of the on-off controller.

 Air conditioning works as follows.

 To maintain a predetermined humidity regime with constant moisture release, the compressor 1 operates continuously throughout the entire period of active moisture release, for example, throughout the crew’s working day. The refrigerant vapor compressed in compressor 1, for example R218, is fed to the input of the on-off controller 6, after which, depending on the air temperature at the outlet of the air conditioner, measured by temperature sensor 15, they either go directly to the water condenser 2 (the position of the controller is “closed”), or first they pass through the heating heat exchanger 7 (the position of the regulator is “open”) and only then they enter the water condenser 2. In the condenser 2, the refrigerant vapor is condensed by cooling it, for example, the coolant pa thermostating envelope pressurized compartment system. From the condenser 2, the liquid refrigerant through one of the cavities of the recuperative heat exchanger 5 enters the thermostatic valve 3, where it is throttled with decreasing temperature, after which it enters the evaporator 4 with a fan. In this heat exchanger, the refrigerant cools and drains the air passing through it, while the refrigerant itself evaporates and its vapor passes through another cavity of the heat exchanger 5, cooling the liquid entering the inlet of the thermostatic valve 3. In this case, the refrigerant vapor is heated. From the heat exchanger 5, the heated vapors are sucked in by the compressor 1. The air flow created by the fan through the heat exchange surface of the evaporator 4, which has a temperature below the dew point, is cooled, while moisture from it condenses on the surface of the heat exchanger and is removed by the condensate collection system.

 The dried and cooled air then enters the heating heat exchanger 7, where at its low temperature it is heated to the required comfortable value.

The air temperature sensor 15 measures the temperature of the air leaving the heating heat exchanger 7, and if the intentional value of the air temperature falls outside the minimum acceptable range set by the set point of the minimum allowable air temperature 8, for example, 15 ^o C, this value through the comparison circuit 11 and the generator 12 gives a control action to the actuator 14, regulator 6 whereupon the controller opens and heated to 50 - 60 ^o C refrigerant vapor fed to the heating heat exchanger which, in turn, n It heats up the dried air. When the air temperature rises above the maximum allowable value, for example 25 ^o C, the signal from the sensor 5 falls into the comparison circuit 10, where it is compared with the value of the maximum allowable temperature issued by the setter 9, after which the former 13 will issue a control command to the controller drive 14 to close it and air heating does not occur.

 The proposed air conditioner allows you to fully complete the task, namely to ensure continuous collection of moisture from the atmosphere of the compartment and maintaining the temperature of the air leaving the evaporator in the range of comfortable values. In this case, no additional electricity is required, since the system uses the heat generated in the refrigeration cycle.

 This autonomous air conditioner was fully implemented in the design and manufacture of the temperature control system of the service module of the new international orbital station, while all components of domestic production were used.

Claims (1)

 A stand-alone water-cooled air conditioner comprising a compressor, a water condenser, a thermostatic valve, an evaporator with a fan, a two-cavity heat exchanger, one cavity of which is connected to the output of the water condenser and the input of the thermostatic valve, and the other cavity is connected to the evaporator output and the compressor input, an air temperature sensor, characterized in that a two-position flow regulator with a drive installed at the outlet of the compressor, a heating heat exchanger, and one the regulator output is connected to the input of the heating heat exchanger, the other output of the controller is connected to the output of the heating heat exchanger and the input of the water condenser, the heating heat exchanger is installed in the air channel at the outlet of the evaporator, the air temperature sensor is installed through the air channel at the outlet of the heating heat exchanger, the maximum permissible and the minimum permissible values of air temperatures, two comparison schemes, two shapers of control commands for closing and opening the controller, respectively, while the temperature sensor is connected to one input of the mentioned comparison circuits, and the outputs of the controllers of the maximum allowable and minimum allowable air temperatures are connected to the second input of these circuits, respectively, the outputs of the comparison circuits are connected to the corresponding inputs of the shapers of control commands for closing and opening the controllers , and their outputs are driven by a two-position controller.