KR20010061869A - air-conditioner expansion valve with of automatically adjustable spring tension - Google Patents

Abstract

PURPOSE: An automatic tension adjustable air conditioner expansion valve is provided to allow the cooling capacity to be adjusted in accordance with conditions and achieve a stable cooling performance by varying the tension of coil spring of pressure control unit in accordance with the temperature of refrigerant flowing at the outlet port of evaporator. CONSTITUTION: A tension adjusting device(50) for adjusting tension of a coil spring(24), comprises a temperature sensor(51) for sensing the temperature of an outlet port(16) of an evaporator; an actuator(53) for moving, in accordance with the input control signal, an adjusting screw(26) which supports the coil spring; and a control unit(57) for controlling operation of the actuator in accordance with the signal input from the temperature sensor. The control unit includes a database of tension value of the coil spring corresponding to the temperature of the outlet port of the evaporator, and controls tension of the coil spring through the actuator which is constituted by a driving motor(54) for rotating the adjusting screw through a rotation driving shaft(55).

Description

Air-conditioner expansion valve with of automatically adjustable spring tension

The present invention relates to an air conditioner expansion valve, and more particularly, by varying the coil spring tension of the pressure control unit for adjusting the pressure of the refrigerant flowing into the evaporator according to the refrigerant temperature at the evaporator outlet. It relates to an air conditioner expansion valve to more precisely control the outlet pressure of the refrigerant in accordance with the effect.

In general, an air conditioner (air conditioner) refers to a device that keeps the room in a comfortable state by automatically adjusting the air temperature and humidity of the room by a mechanical device, such as an evaporator, a compressor, a condenser, and an expansion valve. It constitutes a refrigeration cycle made.

Figure 1 shows a refrigeration cycle of the air conditioner, the refrigerant gas evaporated by the endothermic action in the evaporator 105 is sent to the compressor 102, the compressor 102 receives work from the outside in a high temperature and high pressure gas state It is compressed and sent to condenser 103. When the high-temperature, high-pressure refrigerant gas is forcedly cooled by air in the condenser 103, a phase change occurs to be a high-pressure liquid refrigerant and is sent to the storage container 104. The expansion valve 101 is to spray the refrigerant by dropping the pressure while throttling the high-pressure refrigerant in the storage container 104 to easily evaporate. This sprayed refrigerant is sent back to the evaporator 105 to obtain a freezing effect by the endothermic action.

Here, the expansion valve 101 is divided into an internal equalization type and an external equalization type, and an external equalization type is absolutely used. However, instead of external equalizers that require a thermostat to detect the evaporator outlet temperature and an equalizer port to detect the pressure at the evaporator outlet, block-type expansion valves that do not require them are designed to gradually block The trend is to turn to.

The air conditioner expansion valve for automobiles is divided into an internal equalization type and an external equalization type, and an external equalization type is absolutely used. However, instead of external equalizers that require a thermostat to detect the evaporator outlet temperature and an equalizer port to detect the pressure at the evaporator outlet, block-type expansion valves that do not require them are designed to gradually block The trend is to turn to.

The block expansion valve 101 has an inlet 112 formed at a lower side of the main body 110 to introduce a high pressure refrigerant in the storage container 104 and a high pressure refrigerant from the inlet 112 to the evaporator 105. Evaporator inlet 114 formed on the other side of the upper body 110 adjacent to the inlet 112 so that the inlet 112, and the refrigerant gas evaporated by the endothermic action in the evaporator 105 to the compressor (102). The evaporator outlet 116 formed through the upper portion of the 110, the diaphragm mounting portion 118 formed on the upper portion of the main body 110, and the orifice portion 119 communicating between the inlet 112 and the evaporator inlet 114. And a pressure control part 120 formed at the lower part to selectively open and close the orifice part 119 to control the outflow pressure to the evaporator outlet 116.

The diaphragm 130 is mounted on the diaphragm mounting portion 118 of the main body 110, and a predetermined set pressure is sealed thereon. In addition, the rod member 140 is built in the longitudinal direction from the center of the main body 110, the guider 142 attached to the upper end in accordance with the outflow pressure of the evaporator outlet 116 slides in the diaphragm 130, The lower end of the lower rod 144 is configured to slide the orifice portion 119 between the inlet 112 and the evaporator inlet 114. An O-ring 146 is attached to the middle of the rod member 140. In addition, the guider 142 is formed with a temperature sensitive port 128 in communication with the evaporator outlet 116.

The pressure control part 120 of the main body 110 is provided with the ball 122 adjacent to the orifice part 119, and the coil spring 124 is elastically supported by this ball 122, and the coil spring 124 is carried out. The adjusting screw 126 is installed to adjust the elasticity of the evaporator outlet 116 to control the pressure.

Three forces act on the expansion valve 101 configured as described above. That is, the force Fset by the sealed set pressure on the diaphragm 130, the force Fsp by the coil spring 124, and the force Feva by the outflow pressure of the evaporator outlet act. The relationship of these forces is as follows.

Fset = Feva + Fsp

Thus, if the outlet pressure of the evaporator outlet 16 is high,

Fset <Feva + Fsp

The sum of the forces acting on the lower portion of the diaphragm 130 becomes greater than the force acting on the upper portion of the diaphragm 130 so that the diaphragm 130 moves upward, and the ball 122 rises to the evaporator inlet. The pressure of the refrigerant entering the 114 is reduced, which in turn results in a decrease in the pressure of the evaporator outlet 116,

Fset> Feva + Fsp

In this equation, the relationship of the force acts to increase the outlet pressure of the evaporator outlet 116 by moving the diaphragm 130 downward again. Therefore, this operation is repeated until the force acting on the expansion valve is in equilibrium.

However, the above-described conventional expansion valve 101 adjusts the opening degree of the orifice portion 119 only by expansion and contraction action through the set pressure and the temperature sensitive port 128 of the diaphragm, so that the refrigerant pressure is not precisely controlled and the refrigerant pressure is reduced. Since the range of adjustment is limited, it is difficult to properly adjust the cooling power according to the situation, and there is a problem in that stable cooling performance cannot be expected.

Accordingly, the present invention has been made in view of the above problems, by varying the coil spring tension of the pressure control unit for adjusting the pressure of the refrigerant flowing into the evaporator in accordance with the refrigerant temperature of the evaporator outlet side pressure change and temperature of the evaporator outlet. It is an object of the present invention to provide an air-conditioning expansion valve to more precisely control the outlet pressure of the refrigerant in accordance with the load.

1 is a cross-sectional view showing a conventional air conditioning expansion valve.

Figure 2 is a cross-sectional view showing an air conditioning expansion valve according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: expansion valve 14: evaporator inlet

16: evaporator outlet 19: orifice

22: ball 24: coil spring

26: adjusting nut 30: diaphragm

50: tension control device 51: temperature sensor

53: Actuator 54: Drive Motor

57: control unit

According to a feature of the present invention for achieving the above object, the opening degree of the orifice portion communicating the inlet and the evaporator inlet communicating with the condenser is adjusted by the vertical movement of the ball supported by the coil spring, the vertical movement of the ball is coiled An air conditioner expansion valve configured to be controlled by expansion means which is moved up and down according to a temperature and pressure change of an evaporator outlet in a direction opposite to a spring, comprising: a temperature sensor for sensing the temperature of the evaporator outlet and a coil spring according to an input control signal It provides an expansion valve including an actuator for moving the adjustment screw to support the control unit for controlling the operation of the actuator in accordance with a signal input from the temperature sensor.

Hereinafter, an embodiment of the present invention will be described in more detail based on the accompanying drawings.

Figure 2 shows an air conditioner expansion valve (1) capable of automatic tension adjustment according to an embodiment of the present invention, the expansion valve 1 is the lower portion of the main body 10 to introduce a high-pressure refrigerant in the storage container (4) An inlet 12 formed at one side and an evaporator inlet 14 formed at the other side of the upper portion of the main body 10 adjacent to the inlet 12 so that the high pressure refrigerant from the inlet 12 is introduced into the evaporator 5; An evaporator outlet 16 formed through the upper portion of the main body 10 so that the refrigerant gas evaporated by the endothermic action in the evaporator 5 to the compressor 2, and a diaphragm mounting portion formed on the upper portion of the main body 10 18, an orifice portion 19 communicating between the inlet 12 and the evaporator inlet 14, and the orifice portion 19 to selectively open and close to control the outflow pressure to the evaporator outlet 16 to the lower portion. Basic configuration of the pressure control unit 20 is formed as in the prior art.

The diaphragm 30 is mounted on the diaphragm mounting portion 18 of the main body 10 and a predetermined set pressure is sealed in the upper portion thereof. In addition, the rod member 40 is embedded in the longitudinal direction at the center of the main body 10 so that the guider 42 attached to the upper end in accordance with the outflow pressure of the evaporator outlet 16 slides in the diaphragm 30, The lower end of the lower rod 44 is adapted to slide the orifice portion 19 between the inlet 12 and the evaporator inlet 14. An O-ring 46 is attached to the middle of the rod member 40. In addition, the guider 42 is formed with a temperature sensitive port 28 in communication with the evaporator outlet 16.

The pressure control unit 20 is provided with a ball 22 adjacent to the orifice unit 19, and the coil spring 24 is elastically supported on the ball 22 to adjust the elasticity of the coil spring 24. Screws 26 are installed to control the pressure of the evaporator outlet 16.

Here, according to a feature of the present invention, the tension adjusting device 50 for adjusting the tension of the coil spring 24 is provided, the tension adjusting device 50 is a temperature for sensing the temperature of the evaporator outlet 16 According to the sensor 51, the actuator 53 for moving the adjustment screw 26 supporting the coil spring 24 in accordance with the input control signal, and the actuator 53 in accordance with the signal input from the temperature sensor 51 It is comprised of the control part 57 which controls an operation | movement.

The control unit 57 is configured with a database of the tension value of the coil spring 24 according to the temperature of the evaporator outlet 16, and the tension of the coil spring 24 is adjusted through the actuator 53.

At this time, the actuator 53 is composed of a drive motor 54 for forward and reverse rotation of the adjustment screw 26 through the rotation drive shaft (55).

In the drawings, reference numeral 2 is a compressor, 3 is a condenser, and 5 is an evaporator.

Looking at the operation of the air conditioner expansion valve 1 according to an embodiment of the present invention configured as described above are as follows.

In the course of operating the refrigeration cycle of the air conditioner, basically the force (Fset) by the set pressure enclosed on the diaphragm 30, the force (Fsp) by the coil spring 24, and the evaporator outlet 16 The opening degree of the orifice 19, that is, the refrigerant pressure passing through the expansion valve, is determined by the force Feva due to the outflow pressure.

In this process, the control unit 57 of the tension control device 50 detects the refrigerant temperature of the evaporator outlet 16 through the temperature sensor 51, and then adjusts the tension of the coil spring 24 according to the refrigerant temperature value. Calculate. Then, the calculated tension value is adjusted through the actuator 53. That is, the drive motor 54 of the actuator 53 rotates the adjustment screw 26 supporting the coil spring 24 at a predetermined angle while being rotated forward and backward according to a control signal input from the controller 57. The adjusting screw 26 is elevated to adjust the tension of the coil spring 24.

Thus, the refrigerant pressure flowing into the evaporator is precisely controlled by the tension control of the coil spring 24 based on the refrigerant temperature detected from the temperature sensor 51 as well as widening the adjustment range, the experimental table 1 described below As described above, it is possible to secure stable cooling performance.

Coil spring tension Room temperature change Remarks 1.5kgf 22.5 ℃ 30 minutes at 48km / h 1.75kgf 20.5 ℃

As can be seen in Table 1, when the tension of the coil spring 24 is changed from 1.5kgf to 1.75kgf it is possible to secure the cooling performance of 22.5 ℃ to 20.5 ℃.

As described above, the present invention by varying the coil spring tension of the pressure control unit for adjusting the pressure of the refrigerant flowing into the evaporator according to the refrigerant temperature of the evaporator outlet side of the refrigerant according to the pressure change of the evaporator outlet and the influence of the temperature load By being able to adjust the outflow pressure more precisely, it is possible to appropriately adjust the cooling power in accordance with the situation, it is possible to expect a stable cooling performance.

While the invention has been shown and described with respect to particular embodiments, those skilled in the art will recognize that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended claims. Anyone can easily know.

Claims (2)

The opening degree of the orifice portion communicating the inlet and the evaporator inlet on the condenser side is controlled by the vertical movement of the ball supported by the coil spring, and the vertical movement of the ball is dependent on the temperature and pressure change of the evaporator outlet in the direction opposite to the coil spring. In the air conditioning expansion valve configured to be adjusted by the expansion means which is moved up and down along, A temperature sensor for sensing the temperature of the evaporator outlet, an actuator for moving the adjusting screw of the coil spring according to the input control signal, and a controller for controlling the operation of the actuator according to the signal input from the temperature sensor. Expansion valve comprising a. According to claim 1, The actuator is an expansion valve, characterized in that consisting of a drive motor for forward and reverse rotation of the adjustment screw.