KR100382813B1 - Refrigeration cycle - Google Patents

Abstract

In the refrigeration cycle (air conditioner) using the mixed refrigerant, the mixing ratio of the refrigerant in the refrigerant circuit is measured by the mixing ratio detector, and the controller receives a detection signal to control the valve when the mixing ratio of the high boiling point refrigerant component is low. By opening the high boiling point refrigerant stored in the liquid reservoir is returned to the refrigerant circuit. The high boiling point refrigerant supplied from the liquid storage tank through the opening operation of the control valve is supplied from the low pressure side of the compressor into the refrigerant circuit so that the mixing ratio of the refrigerant circulating in the refrigerant circuit is maintained at a predetermined value, so that the refrigerant pressure due to the change of the mixing ratio Abnormal increase of is prevented.

Description

Refrigeration cycle

Background of the Invention

Field of invention

The present invention relates to a refrigeration cycle using a mixed refrigerant obtained by mixing a plurality of refrigerants having different characteristics.

Description of related technology

In general, the refrigerant circuit of a conventional air conditioner is composed of a plurality of components such as a compressor, a condenser, a pressure reducing device (expansion device), an evaporator, and the like, and these components are connected to each other through a refrigerant tube in a loop form. The gaseous refrigerant in the air conditioner is compressed by the compressor and circulated through the refrigerant circuit.

Such gaseous refrigerant circulated through the refrigerant circuit is maintained within a predetermined pressure range.

When the gaseous refrigerant is excessively compressed so that the pressure exceeds the predetermined pressure range, the compressor is overloaded, or the refrigerant circuit is damaged or leaks of the refrigerant surrounding the joint part of the refrigerant circuit are allowed.

In order to avoid these failures, various attempts have been made so far to prevent the refrigerant from being excessively compressed in the refrigerant circuit.

In the conventional refrigerant circuit, the generation of excessive pressure of the refrigerant is mostly due to the rapid change of the load, and since the flon refrigerant is used in the prior art and is sensitive to these factors, that is to say, factors that induce excessive pressure of the refrigerant, the external air temperature Is usually based on exogenous factors.

Recently, in order to prevent the destruction of the so-called ozone layer, as disclosed, for example, in Japanese Patent Application Laid-Open No. 54-2561, at least one that is free from troublesome refrigerants and that is free of chlorides and mixed with each other to provide a predetermined refrigerant property. Air conditioners using mixed refrigerants made from two refrigerant components are known. In this mixed refrigerant, these refrigerant components have different physical properties such as different boiling points or condensation pressures.

In an air conditioner using such a mixed refrigerant, the condensation pressure of the refrigerant in the refrigerant circuit changes due to a change in the mixing ratio of the refrigerant components of the mixed refrigerant.

Therefore, in order to maintain the air conditioner in a stable state, it is necessary to maintain the mixing ratio of the mixed refrigerant at a fixed value.

Summary of the Invention

An object of the present invention is to provide a refrigeration cycle using a mixed refrigerant formed of at least two refrigerant components having different characteristics, wherein the mixed refrigerant is prevented from being abnormally compressed when circulated through the refrigerant circuit of the refrigeration cycle. Can be.

In order to achieve the above object, according to the first aspect of the present invention, a mixed refrigerant composed of a plurality of refrigerants having different characteristics is circulated through the operation of a compressor, and at least a refrigerant circuit including a compressor, a condenser, a pressure reducing device, and an evaporator is provided. The refrigeration cycle includes: detection means for detecting the physical state of the mixed refrigerant circulating in the refrigerant circuit, storage means for storing the liquefied refrigerant in the refrigerant circuit, pressure of the mixed refrigerant circulating in the refrigerant circuit The refrigerant supply means for supplying the liquefied refrigerant stored in the storage means to the predetermined position of the reduced refrigerant circuit, the flow rate adjusting means for adjusting the amount of the liquefied refrigerant passing through the refrigerant supply means, and the detection means detected by the detection means. Control means for controlling the flow rate adjusting means based on the physical state of the mixed refrigerant Here, the flow rate of the liquefied refrigerant passing through the refrigerant supply means is controlled based on the physical state detected by the detection means so that the physical state of the mixed refrigerant circulating in the refrigerant circuit converges to a predetermined range.

According to the refrigeration cycle of the first aspect of the present invention, some of the plurality of refrigerants having different characteristics are mainly liquefied and stored in the storage means according to the physical state of the mixed refrigerant. Therefore, the liquefied refrigerant stored in the storage means is returned to the low pressure portion of the refrigerant circuit in accordance with the physical state of the refrigerant detected by the detection means.

When the liquefied refrigerant is returned as described above, the detection means detects the physical state of the mixed refrigerant in the refrigerant circuit and controls the flow rate adjusting means based on the detected physical state.

In this operating state, the mixed refrigerant circulating in the refrigerant circuit can converge to a predetermined range, so that the mixed refrigerant circulating in the refrigerant circuit can be prevented from maintaining at an abnormal high pressure.

When the mixed refrigerant is formed of at least R-32 (difluoromethane) and R-125 (pentafluoroethane), the pressure of the refrigerant circuit may be excessively high, so that the present invention is more effectively applicable.

When the expansion means is used for the flow rate adjusting means, the liquefied refrigerant is returned to the refrigerant circuit in a state where the refrigerant is likely to vaporize.

If the condensation temperature is detected as the physical quantity of the mixed refrigerant, the structure can be further simplified since a temperature detector may be used as the detection means.

If the gas-liquid separation means is arranged on the suction side of the compressor to perform gas-liquid separation of the liquefied refrigerant supplied from the storage means, liquid compression by the compressor can be prevented.

Moreover, if the air flow rate of the fan of the condenser is increased based on the condensation temperature and the control by the fan is performed, the physical change of the refrigerant state can be quickly and surely converged to a predetermined range under the operation of the refrigeration cycle (air conditioner). have.

If the physical quantity of the mixed refrigerant detected by the detecting means is the temperature of the mixed refrigerant existing in the low pressure state, the physical state of the refrigerant circuit can be most effectively grasped.

If the amount of the liquefied refrigerant flowing in the refrigerant supply means is increased when the temperature on the low pressure side of the refrigerant circuit is lower than the predetermined temperature, the abnormal increase in pressure can be suppressed by simple temperature measurement.

The refrigerant leaks from the refrigerant circuit when the gradient of the flow rate of the mixed refrigerant flowing in the refrigerant supply means continues to exceed the predetermined value for a predetermined time or longer.

In this case, the protective means performs the safe operation by performing the protective operation for safety. As a protective operation, the operation of the compressor may be stopped for safety. The protection means may be achieved by increasing the amount of liquefied refrigerant flowing in the refrigerant supply means.

According to a second aspect of the present invention, a refrigeration cycle comprising a mixed refrigerant composed of a plurality of refrigerants having different characteristics as a composition is circulated through the operation of a compressor and comprises at least a refrigerant circuit comprising a compressor, a condenser, a decompression device, and an evaporator. Is means for detecting the physical state of the mixed refrigerant circulating in the refrigerant circuit, storage means for storing the liquefied refrigerant which is disposed in the refrigerant circuit and changed from the mixed refrigerant to the liquid phase in the refrigerant circuit, and liquefaction stored in the storage means in the refrigerant circuit. Refrigerant recycling means for recycling the refrigerant, and control means for controlling the refrigerant recycling means based on the physical state of the mixed refrigerant detected by the detection means, wherein the recycling of the liquefied refrigerant into the refrigerant circuit by the detection means Is controlled based on the detected physical state, The physical state of the mixture refrigerant circulating in each time is converged to a predetermined range.

According to the refrigerating cycle of the second aspect of the present invention, depending on the physical state of the mixed refrigerant detected by the detecting means, the liquefied refrigerant stored in the storing means is returned to any position of the refrigerant circuit regardless of the low pressure position or the high pressure position. In it is recycled.

When the liquefied refrigerant is returned as described above, the detection means detects the physical state of the mixed refrigerant in the refrigerant circuit and returns the refrigerant based on the detected physical state, so that the mixed refrigerant circulating in the refrigerant circuit converges to a predetermined range. Can be. Therefore, the mixed refrigerant circulating in the refrigerant circuit can be prevented from increasing abnormally.

When the mixed refrigerant is formed of at least R-32 (difluoromethane) and R-125 (pentafluoroethane), the pressure in the refrigerant circuit becomes excessively high so that the present invention can be applied more effectively.

If the refrigerating recirculation means is designed to guide the liquefied refrigerant stored in the storage means to the neck portion of the gas-liquid separation means, the pressure of the refrigerant in the neck portion is reduced so that the refrigerant stored in the liquid reservoir is stored without a driving force. Can be reliably returned to the circuit.

Moreover, this structure can be made simpler if the reduced pressure part is designed to have a smaller diameter.

Detailed description of the preferred embodiment

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. 12 is a perspective view of a domestic air conditioner using a refrigeration cycle according to an embodiment of the present invention. This type of air conditioner consists of a user side unit "A" (eg, indoor unit "A") arranged indoors and a heat source side unit "B" (eg, outdoor unit "B") arranged outdoors. These are connected to each other through the refrigerant tube (300).

1 is a refrigerant circuit diagram of an air conditioner according to the present invention.

Prior to the description of the refrigerant circuit, the mixed refrigerant circulating through the refrigerant circuit will be described first. As the refrigerant, a mixed refrigerant containing at least refrigerant components having different characteristics such as boiling point and condensation pressure is used.

In other words, the mixed refrigerant may be composed of two-component, three-component, or four-component systems.

R formed by mixing 52% by weight of R-134a (tetrafluoroethane), 25% by weight of R-125 (pentafluoroethane) and 23% by weight of R-32 (difluoroethane) as a three-component mixed refrigerant -407 is used. In general, the boiling point of R-134a is -26 ° C, the boiling point of R-125 is -48 ° C, and the boiling point of R-32 is -52 ° C. At this mixing ratio, the boiling point and condensation pressure of the mixed refrigerant are maintained at -43.9 ° C and 18.66 bar, respectively. In the mixed refrigerant thus prepared, R-32 and R-125 having a lower boiling point than R-134a are easily evaporated at room temperature, so that R-134a is likely to remain in the liquid phase. When the designated component (R-134a) of the refrigerant component in the mixed refrigerant remains in the liquid phase in the refrigerant circuit, the mixing ratio of the mixed refrigerant circulating in the refrigerant circuit changes significantly, indicating that the refrigeration cycle sufficiently achieves the initial expected freezing effect. Make it difficult

Specifically, when the content of R-134a (i.e., the refrigerant component having a high boiling point) decreases in the refrigerant circuit, the gas pressure of the low boiling refrigerant component increases in the refrigerant circuit, so that an excess pressure occurs in the refrigerant circuit.

In the case of a two-component mixed refrigerant, R-410A or R-410B is used as a mixed refrigerant, and R-410A is formed by mixing 50% by weight of R-32 and 50% by weight of R-125, and having a boiling point of -52.2 ° C,- It has a dew point of 52.2 ° C. and a condensation pressure of 27.30 bar. R-410B is formed by mixing 45% by weight of R-32 and 55% by weight of R-125 and has properties similar to R-410A.

Now, when comparing a conventional single refrigerant such as HCFC-22 and a mixed refrigerant having the composition under certain conditions, the following results were obtained:

Under specified conditions, the discharge temperature of the compressor is 66 ° C for HCFC-22 and 73.6 ° C for R-140A; Condensation pressure is 17.35 bar for HCFC-22, 27.30 bar for R-140A, and evaporation pressure is 6.76 bar for HCFC-22 and 10.86 bar for R-410A.

As a result, the mixed refrigerant (i.e., R-410A) is higher in temperature and pressure than the conventional single refrigerant (i.e., HCFC-22) throughout the entire refrigerant circuit.

In addition, when the mixed refrigerant containing R-410A and R-410B is used, since the boiling point between the refrigerant components of the mixed refrigerant is substantially different, the refrigerant composition of the mixed refrigerant hardly changes. It is not necessary to consider the problem caused by the temperature change.

Next, the refrigerant circuit of the air conditioner shown in FIG. 1 will be described.

The refrigerant circuit of the air conditioner shown in FIG. 1 includes a compressor (1), a four-way valve (2), an indoor heat exchanger (3), an expansion device (an solenoid valve) as a pressure reducing device (4), and an outdoor heat exchanger (5). ) And an accumulator 6, which are connected to each other via a refrigerant tube.

According to the switching position of the four-way valve and opening / closing operation of the solenoid valve 4, the flow direction of the refrigerant discharged from the compressor 1 into the refrigerant circuit is indicated by a solid arrow (cooling cycle), a dotted arrow (heating cycle) and a solid line with a dot. It is optionally determined as indicated by one of the arrows (defrost cycle).

In the cooling cycle, the heat exchanger 5 arranged on the outside side of the circuit serves as a condenser while the heat exchanger 3 on the inside side of the circuit serves as an evaporator.

In the heating cycle, the indoor heat exchanger 3 serves as a condenser while the outdoor heat exchanger 5 serves as an evaporator. In the defrost cycle (during heating operation) the solenoid valve 10 is opened if necessary and A portion of the hot refrigerant discharged from the compressor 1 is led to the outdoor heat exchanger 5 to increase the temperature of the outdoor heat exchanger 5.

This operation increases the temperature of the outdoor heat exchanger 5. When the defrost operation is sufficiently operated (e.g., when the outside air temperature is extremely low) or when the frost formation is excessively advanced, the progress of the frost formation is suppressed by performing the reverse cycle defrost operation indicated by the solid arrow. .

11 shows a control circuit of the air conditioner of the present invention.

The control circuit shown in FIG. 11 is divided into two control circuits by a dashed line at the center thereof.

One circuit on the left side of FIG. 11 is a control circuit for the indoor unit "A" (see FIG. 1), and the other circuit on the right side of FIG. 11 is a control circuit for the outdoor unit "B".

Both circuits are connected to each other through the power line 100 and the control line 200.

The indoor unit A includes a rectifier circuit 111, a motor power supply circuit 112, a control power supply circuit 113, a motor drive circuit 115, a switchboard 117, a receiver circuit 118a, and a display panel. 118 and the flap motor 119 is provided.

The rectifier circuit 111 rectifies and smoothes AC voltage (100 volts) supplied through the plug 110a. The motor power supply circuit 112 adjusts the DC bolt supplied to the DC fan motor 116 through the motor driving circuit 115 to generate a voltage of 10 to 36 volts.

The motor driving circuit 115 controls the supply time of the electric power supplied to the stator winding of the DC fan motor 116 in accordance with the signal transmitted from the microcomputer 114, so that the air to be blown to the room where the air conditioner is installed. To control.

The control power supply circuit 113 generates a DC voltage of 5 volts supplied to the microcomputer 114.

On the other hand, the motor drive circuit 115 is supplied from the microcomputer 114 and supplies power to the stator windings of the DC fan motor 116 in response to a signal based on the information of the rotational position of the DC fan motor 116. To control the switching time.

The switchboard 117 is fixedly mounted on the operation panel of the indoor unit A.

The switchboard 117 is provided with an on / off switch, a test operation switch, and the like.

The switch states of these components are input by the microcomputer 114 via key scanning operation. The receiving circuit 118a receives a remote control signal (for example, on / off signal, cooling / heating switching signal, room temperature setting signal, etc.) supplied from the wireless remote controller 160 and demodulated and transmitted to the microcomputer 114. Receive.

The display plate 118 dynamically turns on the LED based on the signal from the microcomputer 114 to display the operating condition of the air conditioner.

On the other hand, the flap motor 119 is adjusted by the indoor heat exchanger 7 and functions to move the flap to change the blowing direction of the air blown from the fan.

In addition, the control circuit is further provided with an indoor temperature sensor 120 for measuring the indoor temperature, a heat exchanger temperature sensor 121 for measuring the temperature of the indoor heat exchanger and a humidity sensor 122 for measuring the indoor humidity. have. Thus, the values measured by these sensors are analog-digital (A / D) converted and provided to the microcomputer 114. The microcomputer 114 inputs these inputs to transmit control signals to the outdoor unit B through the serial circuit 123 and the terminal plate V3 to set the driving capacity (power) of the four-way valve and the compressor 1. The calculation is performed based on the information (information received). Both the triac 126 and the heater relay 127 are provided with a driver (step by step) to control the power supplied to the reheat heater 125 used in the drying cycle of the air conditioner (the state of the refrigeration cycle used for cooling operation). Controlled by the microcomputer 114 via 124.

Reference numeral 130 denotes an external ROM which stores specific data indicating the type and characteristics of the air conditioner.

These specific data are withdrawn from the external ROM immediately after the plug 110 is connected to the plug socket and powered up and the microcomputer 114 is up and running.

The microcomputer 114 detects the input command from the wireless remote controller 160 or the state of the on / off switch or the detection of the test drive switch until specific data is completely withdrawn from the external ROM (this operation will be described below). None of these).

Next, the control circuit of the outdoor unit B will be described with reference to FIG.

In the outdoor unit B, the terminal plates V'1, V'2 and V'3 are connected to the terminal plates V1, V2 and V3 of the indoor unit A, respectively. In Fig. 11, reference numeral 131 denotes a varistor connected in parallel to the terminal plates V'1 and V'2; Reference numeral 132 denotes a noise filter; Reference numeral 135 denotes a double voltage rectifying circuit, and reference numeral 136 denotes a noise filter.

Moreover, in FIG. 11, reference numeral 139 denotes a serial circuit for distributing the control signal supplied from the indoor unit from the power line through the terminal plate V'3, and the distributed signal is transmitted to the microcomputer 141. FIG. Reference numeral 140 denotes a current detector, which detects a current supplied to the outdoor unit B through a current conversion (C.T.) and converts the current into a signal for the microcomputer 141. Reference numeral 142 denotes a constant power circuit for generating an operating power of the microcomputer 141, and reference numeral 138 is based on a control signal from the microcomputer 141 to adjust the drive capacity (power) of the compressor 1. And a three-phase inverter circuit for controlling the power supplied to the compressor 1. The three phase inverter circuit 138 has six power transistors connected in the form of a three phase bridge. Reference numeral 143 denotes a motor portion for driving the compressor 1 of the refrigerating cycle, and reference numeral 144 denotes a delivery-side temperature sensor for detecting the temperature of the refrigerant sent from the compressor 1.

Reference numeral 145 denotes a fan motor arranged to blow air to the outdoor heat exchanger, and the speed of the fan motor is controlled in three stages. As described above, the four-way switching valve 2 and the solenoid valve 10 are designed to switch the refrigerant passage of the refrigeration cycle.

Moreover, an external temperature sensor for detecting the external temperature is provided in the outdoor unit B so as to be adjacent to the air inlet port, and a heat exchanger temperature sensor 149 for detecting the temperature of the outdoor heat exchanger is fastened to the outdoor heat exchanger. . The detected values obtained by these temperature sensors 148 and 149 are A / D converted and supplied to the microcomputer 141.

In addition, reference numeral 150 denotes an external ROM similar in function to the external ROM 130 of the indoor unit A. The specific data for the outdoor unit B is the same as the data of the external ROM 130 and stored in the external ROM 150. The reference character F represents the fuse used in the control circuits of the outdoor unit B and the indoor unit A, respectively.

Each of the microcomputers 114 and 141 (for example, the control unit) includes a ROM in which a program is stored, a RAM in which reference data is stored, and a central processing unit (CPU) for operating the program in the same housing. ("Intel Corporation Intel 87C196MC (MCS-96 series), etc. may be used)."

Subsequently, returning to FIG. 1, the structure of each refrigerant circuit will be described below.

Each of the indoor heat exchanger 3 and the outdoor heat exchanger 5 is provided with fans 3a and 5a so as to perform a heat exchange operation between the outside air or the indoor air and the refrigerant.

Both fans 3a and 5a are designed such that their respective air flow rates are variable, and for example, each fan 3a and 5a has three stages (i.e. low) in response to a signal from the control unit 21. Flow rate, heavy flow rate, and high flow rate) to change the flow rate of air.

In the cooling cycle, the four-way valve 2 allows the refrigerant to flow in the direction of the arrow indicated by the solid line as shown in FIG. 1 while in the heating cycle the four-way valve is dashed as shown in FIG. Allow the refrigerant to flow in the direction of the arrow marked with. By switching the four-way valve 2 in the manner as described above, the flow path of the refrigerant is switchable between the cooling cycle and the heating cycle.

The liquid reservoir 14 is arranged between the accumulator 6 and the four-way valve 2.

As shown in FIG. 2, in the liquid reservoir 14, the upper portion of the reservoir body 15 is connected to the refrigerant inlet tube 16, and the lower portion of the reservoir body 15 is the bottom portion of the reservoir body 15. It is connected to the liquid outlet tube 17 for discharging the liquefied storage refrigerant from the liquid.

Moreover, the gas outlet tube 18 extending upward is connected to the reservoir 14, and the tube end of the gas outlet tube 18 faces the refrigerant inlet tube 16 through the gas-liquid separator 19. It is arranged to. In the liquid reservoir 14 configured as described above, the gaseous refrigerant is guided into the accumulator 6 and the liquefied refrigerant stored in the liquid reservoir 14 is discharged from the reservoir 14 through the liquid outlet tube 17.

The liquid outlet tube 17 is connected to the liquefied refrigerant return circuit 20 to return the liquefied refrigerant to the accumulator 6 through the control valve 13 and the capillary tube 12.

The control valve 13 uses a step motor to adjust the opening degree.

The step motor changes the rotation angle in accordance with the pulse signal from the control device 21, and the rotation angle is controlled to change over 256 steps in response to the pulse signal from the control unit 21.

The control apparatus 21 includes the microcomputers 114 and 141 shown in FIG. 11 as described above and controls the entire refrigerant circuit. The accumulator 6 is substantially identical to the accumulator of the liquid reservoir 14 which will also be shown in FIG. 9 illustrating the second embodiment of the present invention.

In other words, as will be clear from FIG. 9, the accumulator 6 consists of an accumulator body 29, a liquid outlet tube 31 and a gas-liquid separator 33, and a gas state stored in the accumulator 6 Refrigerant from the gas outlet tube 31 is supplied to the suction side of the compressor (1) through the liquid outlet tube (31).

In contrast, as described above, the refrigerant circuit is provided with a temperature sensor (detector) and a mixing ratio detector at a proper position to obtain a detection signal, and these detection signals are supplied to the control device 21. In this embodiment, the temperature detectors or sensors T1, T2 are each at the outlet side of each of the outdoor heat exchanger 5 and the indoor heat exchanger 3 when each heat exchanger 3, 5 serves as a condenser. Is arranged to detect the coolant temperature.

Furthermore, a temperature detector or sensor T3 for detecting the refrigerant temperature is arranged on the delivery side of the compressor 1, and another temperature detector or sensor T4 for detecting the refrigerant temperature is a four-way valve. It is arrange | positioned at the low pressure side between (2) and the indoor heat exchanger (3).

These detection signals are input to the control unit 21. In the refrigeration cycle of the present invention, by detecting the refrigerant temperature by these temperature detectors or sensors T1 and T2, abnormalities in the mixing ratio of the mixed refrigerant and or abnormal abnormal high pressure in the refrigerant circuit are indirectly detected.

Moreover, the temperature detectors T1 and T2 are arranged on both the outlet sides of these heat exchangers 3 and 5 because they match the detection of the refrigerant temperature for both the cooling and heating cycles.

Furthermore, the mixing ratio detector W1 is arranged between the four-way valve 2 and the compressor 1 to directly detect the mixing ratio of the mixed refrigerant circulating through the refrigerant circuit, and transmits a detection signal to the controller 21. Supply. A temperature detector Ta for detecting the external temperature is provided on the outdoor heat exchanger 5 side and the detection signal is input to the control device 21.

In the state of receiving these detection signals from the temperature sensors or detectors T1, T2, T3 and T4, the control device 21 detects the values of these detection signals and the external air temperature sensor or detector Ta for calculation. Compare the value of the outside air temperature and determine whether the refrigerant temperature exceeds a predetermined temperature. The reason why the refrigerant temperature is compared with the external air temperature as described above is whether the refrigerant is over compressed (ie under excessively high pressure) since the refrigerant temperature is sensitive to the external air temperature as evident in FIG. This is because it is difficult to judge the ratio based on only the refrigerant temperature. Output a predetermined number of pulses to open the control valve 13 to increase the opening degree of the control valve 13 to prevent the refrigerant from being excessively compressed in the refrigerant circuit when the coolant temperature exceeds the predetermined temperature. do.

Similarly, in the state of receiving the detection signal from the mixing ratio detector W1, the control unit 21 starts the necessary calculation processing with the detection signal, and if necessary, the control valve 13 so that the mixing ratio of the high boiling point refrigerant is constant. Supply a single pulse to close the control valve or a single pulse to close the control valve to the control valve (13).

The refrigerant mixing ratio detector includes a sound velocity measuring device for measuring the sound velocity of the liquefied mixed refrigerant in the refrigerant circuit, a thermometer for measuring the temperature of the mixed refrigerant, and a pressure gauge for measuring the pressure of the mixed refrigerant to ensure the concentration of the refrigerant. To measure.

The method of measuring the mixing ratio of the mixed refrigerant is not limited to this method and may be made based on changes in physical properties such as specific gravity of the refrigerant, evaporation temperature, and the like.

The mixing ratio detector is described in detail in Japanese Patent Application Laid-Open No. 7-304298.

The mixing ratio detector includes a microcomputer in which data representing the relationship between speed, temperature and pressure is programmed. The mixing ratio detector is a display unit for inputting the measured values of the mixing refrigerant's speed, temperature and pressure. Calculation processing is performed to display the concentration (composition ratio) and to supply this data to the microcomputer 141.

As for the detection signals supplied from the temperature sensors or detectors T1, T2, T3, and T4 and the mixing ratio detector W1, not all of these detection signals are necessarily used in the refrigeration cycle of the present invention.

The control process of the refrigeration cycle will be clear from the description below, but one or two detection signals as needed may be used to control the control valve 13.

The control method will be described according to the following control process.

In the refrigerant circuit shown in FIG. 1, in the cooling cycle, the four-way valve 2 shown in FIG. 1 is located at the operating position indicated by the solid line, and the refrigerant is the compressor 1, the outdoor heat exchanger 5 , In order to circulate through the pressure reducing device 4, the indoor heat exchanger 3, the four-way valve 2, the liquid reservoir 14 and the accumulator 6.

In contrast, during the heating cycle, the four-way valve 2 is located in the operating position indicated by the broken line in FIG. 1, and the refrigerant is stored in the compressor 1, the indoor heat exchanger 3, the pressure reducing device 4, the outdoor heat exchanger. (5), through the four-way valve (2), the liquid reservoir (14) and the accumulator (6) in order to circulate.

In the liquid reservoir 14, the mixed refrigerant is separated into a gas and a liquid phase so that the liquefied mixed refrigerant is stored at the bottom of the reservoir 14, while the gaseous mixed refrigerant is supplied to the accumulator 6 through the gas outlet tube 18. do.

As a result, only the liquefied mixed refrigerant is stored in the liquid reservoir 14.

Therefore, since the low boiling point refrigerant component tends to evaporate from the storage tank 14, the refrigerant having a higher boiling point is mainly stored in the liquid storage tank 14 as the liquefied refrigerant.

On the other hand, since the higher boiling point refrigerant component in the refrigerant circuit tends to liquefy faster than the lower boiling point refrigerant component in the heat exchangers 3 and 5, the mixing ratio of the mixed refrigerant may change. Changes in the mixing ratio often lead to abnormal high pressures in the refrigerant circuit. Therefore, in order to prevent such an abnormally high pressure in this circuit, the following control process is performed.

For clarity of explanation, in the following description, reference numerals indicating respective temperature sensors or detectors and mixing ratio detectors are also used to indicate supplied detection signals. For example, reference numeral T1 also denotes a temperature value detected by the temperature sensor or detector T1.

(Control Process 1)

As shown in FIG. 4, when the control process starts, the control device 21 determines whether or not a predetermined time has elapsed in step S1.

If it is determined that the predetermined time has elapsed, the process proceeds to step S2 and reception of the mixing ratio detection signal is started. The predetermined time mentioned above is a time required for stabilizing the state of the refrigerant in the refrigerant circuit, and the time is set to 30 seconds, 1 minute or the like.

In step S2, a detection signal from the mixing ratio detector W1 is received to measure the mixing ratio of the refrigerant, and then the process proceeds to step S3.

In step S3, it is determined whether or not the thus determined mixing ratio of the high boiling point refrigerant component is lower than the predetermined value α. If the mixing ratio is lower than the predetermined value α, the process proceeds to step S4 to output a single valve opening pulse to the control valve 13, so that the control valve 13 is controlled to a defined opening degree according to the measured value. In step S4, the supply amount of the high boiling point refrigerant stored in the liquid reservoir supplied to the suction port (low pressure side) of the compressor 1 through the capillary tube and the accumulator 6 is increased by opening the control valve 13. Therefore, the mixing ratio of the mixed refrigerant circulating through the refrigerant circuit is maintained at a predetermined value. As a result, abnormal high pressure, ie, abnormally high pressure, of the refrigerant due to the change in the mixing ratio of the refrigerant can be prevented. Moreover, the optimum mixing ratio of the mixed refrigerant can be maintained and the high driving efficiency and stability of the refrigerant can be maintained. Accordingly, the process proceeds to the return stage.

In step S3, if the mixing ratio W1 detected by the mixing ratio detector W1 is not lower than the predetermined value α, the process proceeds to step S5 where the mixing ratio W1 is a predetermined value. It is determined whether it is higher than (β).

If the mixing ratio W1 is higher than the predetermined value β, the process goes to step S6 and outputs a single valve closing pulse to the control unit 21 to close the control valve 13.

If the mixing ratio W1 is not higher than the predetermined value β, the process proceeds to the start step shown in FIG. 4 after the return step. The predetermined values α and β are set as the ranges allowed to prevent chattering of the control valve 13.

In order to prevent the occurrence of such chattering, the mixed ratio detector W1 may be provided with a predetermined insensitive region.

(Control process 2)

In the flowchart shown in FIG. 5, it is determined whether a predetermined time has elapsed in step S11 when the control process starts. If the predetermined time has elapsed, the process proceeds to step S12 where reception of the mixed ratio detection signal is started. After the reception of the detection signals T1 and T2 indicating the detected temperatures T1 and T2 on the outlet side of the heat exchangers 5 and 3 serving as the condenser in step S12 is started, the process is started. The flow proceeds to step S13.

On the contrary, if the detected temperature T1 or T2 is higher than the predetermined temperature Te in step S13, it is determined whether the mixing ratio of the refrigerant circulating through the refrigerant circuit exceeds a predetermined value and then the process is performed. The flow proceeds to step S14.

In step S14, the control valve 13 has a predetermined opening degree (a predetermined number of valve opening pulses is supplied) to return the high boiling point refrigerant stored in the liquid reservoir 14 to the accumulator 6 as in the control step 1. To be opened. As described above, since the opening and closing ratio of the control valve 13 is corrected based on the mixing ratio of the refrigerant estimated through the temperature of the outlet side of the condenser, the mixing ratio of the mixed refrigerant circulating through the refrigerant circuit is simple. It can be reliably controlled. Accordingly, this process proceeds to the return stage.

In contrast, if the temperature T1 or T2 detected in step S13 is not higher than the predetermined temperature Te, the process proceeds to step S15 so that the detected temperatures T1 and T2 become the predetermined temperature ( It is determined whether or not lower than Tb).

If the temperatures T1 and T2 detected in step S15 are lower than the predetermined temperature Tb, the process proceeds to step S16, whereby the control valve is closed as in the control process 1. If the detected temperatures T1 and T2 are not lower than the predetermined temperature Tb, the process proceeds to the return step.

(Control process 3)

In the control process 3 shown in FIG. 6 as in the control processes 1 and 2, the abnormal high pressure of the refrigerant circuit determines whether the value of the detection signal in the temperature detector T1 or T2 is higher than the predetermined temperature Ta. Based on the determination, the process is determined in steps S21 to S23.

If abnormal high pressure is determined in the refrigerant circuit, the process proceeds to step S24.

In step S24, fan 5a (or fan 3a during heating cycle) of condenser 5 (outdoor heat exchanger 5 during cooling cycle and indoor heat exchanger 3 during heating cycle) is previously driven It is determined whether or not it is controlled.

If the fan has not been driven yet, the process proceeds to step S25 to drive the fan 5a.

By driving the fan 5a of the condenser 5 in step S25, the cooling efficiency of the condenser 5 is improved, liquefaction of the refrigerant is promoted, and the refrigerant circuit is suppressed from becoming high pressure.

In this control operation of the fan, when the fan 5a has already been driven, the fan 5a is further driven at high speed in step S25. For example, if the fan 5a is easily driven at low speed in the case of being driven in three stages of low speed, slave speed and high speed, the fan 5a is driven at medium speed or high speed.

When the indoor heat exchanger 3 serves as a condenser during the heating cycle, the fan 3a is driven at low or medium speeds when the fan 3a has not yet been driven.

In step S26, it is determined whether a predetermined time has elapsed after the drive control of the fan.

If the predetermined time has elapsed, the process returns to step S23 to determine again whether the value of the detection signal at the temperature detector T1 or T2 is higher than the predetermined temperature Ta.

In other words, it is determined whether the abnormal high pressure of the refrigerant circuit is reduced under the fan drive control of step S25. When it is determined that abnormal high pressure still remains in the refrigerant circuit, the process proceeds to step S24. In this case, once the fan has been driven, the process proceeds to step S27 and the control valve 13 is controlled to open as in the control processes 1 and 2.

As described above, the two stage control operation in the refrigerating cycle of the present invention is performed with the fans 3a and 5a and the control valve 13 for the following reasons.

Since the increase in the refrigerant temperature is not necessarily based on the change in the mixing ratio of the refrigerant, a slight increase in the refrigerant temperature can be suppressed by the fans 3a and 5a of the condenser.

Moreover, the high pressure of the refrigerant circuit is controlled when the fans 3a and 5a fail to reduce the refrigerant temperature.

If the value of the detection signal T1 or T2 of the temperature detector T1 or T2 in step S23 is not greater than the predetermined temperature Ta, the process proceeds to steps S28 and S29 to control step 2 of control process 2 ( The same control as in S15 and S16 is performed.

(Control process 4)

As shown in FIG. 7, the control process 4 is substantially similar to the control process 2 shown in FIG. 5, and the temperature of the temperature detector T4 at the low pressure side of the refrigerant circuit is replaced by the temperature detectors T1 and T2. What is detected is different from the control process 2. In other words, the detected temperature signal T4 from the temperature detector T4 disposed on the low pressure side of the refrigerant is received in step S32, and the temperature T4 is greater than the predetermined value Tc in step S33. It is determined whether it is higher.

If it is determined in step S33 that T4 is higher than Tc, the process proceeds to step S34 where the control valve 13 is opened and the high boiling point refrigerant component stored in the liquid reservoir 14 on the low pressure side of the compressor 1 Is returned. As described above, the mixing ratio of the refrigerant is estimated based on the temperature at the low pressure side of the refrigerant circuit, and the abnormal high pressure is reduced because the opening / closing ratio of the control valve 13 is controlled based on the estimated mixing ratio of the refrigerant. Simple temperature measurement can be prevented from occurring in the refrigerant circuit.

If T4 is lower than the predetermined value Td in step S33, the process proceeds to step S36 and the control valve 13 is closed.

(Control process 5)

As shown in the steps S41 to S44 and the steps S48 and S49 of FIG. 8, the abnormal high pressure of the refrigerant circuit in the control process 5 causes the opening of the control valve 13 and the like in the control process 4 shown in FIG. Judgment is made based on the detection temperature T4 to control the closing operation.

Control process 5 is characterized by a series of steps S45, S46 and S47.

In other words, after the control valve 13 is opened in step S44, the change gradient M of the opening degree of the control valve 13 is detected in step S45, and then the change gradient M (the valve opening pulse is It is determined whether the output period) exceeds a predetermined fixed value Mo.

In step S46, it is determined whether the change gradient M continues to exceed the fixed value Mo for a predetermined time. If the change gradient M continues to exceed Mo for a predetermined time, for example, 30 seconds, the process proceeds to step S47 where the protective operation is performed. In other words, the refrigerant leaks from the refrigerant circuit when a predetermined time has elapsed while the change gradient M of the opening degree of the control valve 13 (the period during which the valve opening pulse is output) exceeds the fixed value Mo. Is estimated. As a result, in this case, the control device 21 performs a protective operation to stop the operation of the compressor 1, for example, so that the operation of the refrigerant circuit for safety is stopped.

Moreover, the control device 21 simultaneously provides an alarm for checking the refrigerant circuit.

The protective operation may be performed by bringing the control valve 13 to the fully open state.

Here, the opening and closing operations of the control valve 13 will be described in relation to the overall operation of the air conditioner.

In the heating cycle, the operation is performed while the control valve 13 is fully open for a predetermined time in order to perform high efficiency operation when the external air temperature is low.

In the defrost cycle, operation is performed while the control valve 1 is completely closed in order to shorten the defrost time.

Moreover, this operation is performed while the control valve is completely closed for a predetermined time in order to improve the refrigeration cycle at the start indicator when the refrigeration cycle is started after the refrigeration cycle has been stopped for a long time.

Next, a second embodiment according to the present invention will be described with reference to FIG.

The second embodiment of the present invention provides that the liquefied refrigeration circuit 20 is provided with a recirculation mechanism 27 having no control valve 13 and a capillary tube 12 and a first embodiment of the present invention of FIG. different.

As shown in FIG. 9, the inlet tube 23 of the accumulator 6 is connected to the gas outlet tube 18 of the liquid reservoir 14 in the recirculation mechanism 27. The inlet tube 23 is designed to narrow the passage and is formed with a reduced pressure portion 25 that serves as an adjustment mechanism.

The reduced pressure portion 25 of the inlet tube 23 may be designed such that the passage is narrow or the orifice is inside, such as a venturi tube type having a small diameter portion.

Since the negative pressure generated in the mechanism is set in the depressurization portion 25 serving as an adjusting mechanism, a predetermined amount of liquefied refrigerant stored in the liquid reservoir 14 is returned to the refrigerant circuit without using power and a driving mechanism.

In other words, by setting the negative pressure of the depressurization portion 25 of the inlet tube 23 to an appropriate value (the value previously obtained through experiment), the mixing ratio of the specific refrigerant component of the mixed refrigerant circulating through the refrigerant circuit is kept constant. I can keep it.

According to the second embodiment of the present invention shown in FIG. 9, since the mixing ratio (i.e., mixing ratio of specific refrigerant components) of the mixed refrigerant in the refrigerant circuit is kept constant, an abnormal increase in the refrigerant pressure due to the change of the mixing ratio Can be prevented from occurring in the refrigerant circuit.

Moreover, the initial suitable value of the mixing ratio of the refrigerant in the refrigerant cycle of the present invention is kept constant in the refrigerant circuit so that the refrigeration cycle can be operated with high operating efficiency and the safety of the refrigerant can be maintained.

Further, in the second embodiment of the present invention, in contrast to the first embodiment shown in FIG. 1, among the control devices which perform the control operation based on the mixing ratio detector, the temperature sensor or the detector and the detection signals from these detectors, Since neither is required, the structure of the second embodiment can be simplified.

Like the liquid reservoir 14, the accumulator 6 consists of the accumulator body 29, the liquid outlet tube 31 and the gas-liquid separator 33, and the gas outlet tube 31 toward the suction side of the compressor 1. Supply the refrigerant in the gas state sent from the).

The refrigerant thus supplied to the compressor 1 is compressed in the compression portion 41 and then passes through the margin of the motor portion 43 into the outlet opening 47 where the refrigerant is sent to the refrigerant circuit.

The present invention is not limited to the above embodiments and various modifications may be made without departing from the main subject matter of the invention.

For example, it is also possible to use only one of the temperature detectors T1, T2, T3, T4 and the mixing ratio detector W1 in the refrigerant circuit shown in FIG. In other words, it is also possible to control the control valve 13 based on any of the detection signals.

Moreover, the capillary 27b may be fitted in the recirculation mechanism 27 as shown in FIG. 10 to be loaded. In this case, backflow of the liquid in the recirculation mechanism 27 can be prevented.

The present invention relates to a refrigeration cycle and its application is not limited to air conditioners. In other words, the present invention is applicable to any apparatus using a refrigeration cycle.

For example, the present invention may be applied to a refrigerator, a large air conditioner, a prefabricated refrigerator, and the like.

1 is a refrigerant circuit diagram of an air conditioner of an embodiment of the present invention (refrigeration cycle);

2 is a longitudinal sectional view of the liquid reservoir used in the refrigerant circuit shown in FIG.

3 is a graph illustrating a relationship between a refrigerant temperature and external air temperature;

4 is a flowchart showing a control process according to the first control process in the air conditioner of the present invention in a diagram;

5 is a flowchart showing a control process according to the second control process in the air conditioner of the present invention in a diagram;

6 is a flowchart showing a control process according to a third control process in the air conditioner of the present invention in a diagram;

7 is a flowchart showing a control process according to a fourth control process in the air conditioner of the present invention in a diagram;

8 is a flowchart showing a control process according to a fifth control process in the air conditioner of the present invention in a diagram;

9 is a sectional view of an essential part of a second embodiment of the present invention;

10 is a sectional view showing a third embodiment of the present invention;

11 is a control circuit diagram of an air conditioner of the present invention; And

12 is a perspective view of an air conditioner of an embodiment of the present invention.

"Description of Symbols for Major Parts of Drawings"

1: compressor 2: 4-way valve

3: indoor heat exchanger 4: pressure reducing device

5: outdoor heat exchanger 6: accumulator

10: solenoid valve 14: liquid storage tank

15: reservoir body 16: refrigerant inlet tube

17: liquid outlet tube 18: gas outlet tube

19: Gas-liquid separator 20 liquefied refrigerant return circuit

21: controller

Claims (15)

A mixed refrigerant comprising a plurality of refrigerants having different characteristics is circulated, and a refrigerant circuit including at least a compressor, a condenser, an expansion device, and an evaporator having a low pressure side, and the mixed refrigerant is circulated through the operation of the compressor. In a refrigeration cycle, Detecting means for detecting a physical state of the mixed refrigerant circulating in the refrigerant circuit, wherein the physical means includes a condensation temperature of the mixed refrigerant; Storage means disposed in the refrigerant circuit for storing liquefied refrigerant in the refrigerant circuit; Refrigerant supply means for supplying liquefied refrigerant stored in the storage means to a predetermined position in the refrigerant circuit in which the mixed refrigerant circulating in the refrigerant circuit is located on the low pressure side of the compressor; Flow rate adjusting means for adjusting the amount of liquefied refrigerant passing through the refrigerant supply means; Control means for controlling the flow rate adjusting means based on the physical state of the mixed refrigerant detected by the detecting means, wherein the flow rate of the liquefied refrigerant passing through the refrigerant supply means is in a physical state detected by the detecting means. Control means controlled on the basis of the control unit so that the physical state of the mixed refrigerant circulating in the refrigerant circuit converges to a predetermined range; And A fan for blowing air to the condenser, The control means controls the flow rate adjusting means to increase the amount of liquefied refrigerant flowing in the refrigerant supply means and the air flow rate of the fan when the condensation temperature detected by the detecting means exceeds a predetermined temperature. Refrigeration cycle, characterized in that. The refrigeration cycle according to claim 1, wherein the flow rate adjusting means includes a refrigerant flow passage through which the mixed refrigerant flows and expansion means for narrowing the refrigerant flow passage to expand the mixed refrigerant mixture. 3. The refrigerating cycle according to claim 2, wherein the physical quantity of the mixed refrigerant detected by said detecting means is a ratio of a specific refrigerant in the mixed refrigerant. The refrigeration cycle according to claim 1, wherein the control means controls the opening and closing operations of the flow rate adjusting means based on the condensation temperature detected by the detecting means. The refrigeration cycle according to claim 1, wherein the physical quantity of the mixed refrigerant detected by said detecting means is the temperature of the mixed refrigerant existing in a reduced pressure state in said refrigerant circuit. 6. The amount of the liquefied refrigerant flowing in the refrigerant supply means according to claim 5, wherein the control means controls the flow rate adjusting means so that the temperature of the mixed refrigerant detected by the detecting means is lower than a predetermined temperature. Refrigeration cycle, characterized in that. A mixed refrigerant comprising a plurality of refrigerants having different characteristics is circulated, and a refrigerant circuit including at least a compressor, a condenser, an expansion device, and an evaporator having a low pressure side, and the mixed refrigerant is circulated through the operation of the compressor. In a refrigeration cycle, Detection means for detecting a physical state of the mixed refrigerant circulating in the refrigerant circuit; Storage means disposed in the refrigerant circuit for storing liquefied refrigerant in the refrigerant circuit; Refrigerant supply means for supplying liquefied refrigerant stored in the storage means to a predetermined position in the refrigerant circuit in which the mixed refrigerant circulating in the refrigerant circuit is located on the low pressure side of the compressor; Flow rate adjusting means for adjusting the amount of liquefied refrigerant passing through the refrigerant supply means; Control means for controlling the flow rate adjusting means based on the physical state of the mixed refrigerant detected by the detecting means, wherein the flow rate of the liquefied refrigerant passing through the refrigerant supply means is in a physical state detected by the detecting means. Control means for controlling based on the control to allow the physical state of the mixed refrigerant circulating in the refrigerant circuit to converge to a predetermined range; And And a protection means for performing a protection operation when the gradient of the flow rate of the mixed refrigerant flowing in the refrigerant supply means by the flow rate adjusting means continuously exceeds a predetermined value for a predetermined time or more. . 8. The refrigeration cycle according to claim 7, wherein the protection operation of the protection means stops the operation of the compressor. 9. The refrigeration cycle according to claim 8, wherein the protection operation of the protection means increases the amount of liquefied refrigerant flowing in the refrigerant supply means. 8. The refrigeration cycle according to claim 7, wherein the flow rate adjusting means includes a refrigerant flow passage through which the mixed refrigerant flows and expansion means for narrowing the refrigerant flow passage to expand the mixture refrigerant mixture. The refrigeration cycle according to claim 10, wherein the physical quantity of the mixed refrigerant detected by said detecting means is a ratio of a specific refrigerant in the mixed refrigerant. 8. The refrigeration cycle according to claim 7, wherein the physical quantity of the mixed refrigerant detected by said detecting means is the temperature of the mixed refrigerant existing in a reduced pressure state in said refrigerant circuit. 13. The amount of the liquefied refrigerant flowing in the refrigerant supply means according to claim 12, wherein the control means controls the flow rate adjusting means so that the temperature of the mixed refrigerant detected by the detecting means is lower than a predetermined temperature. Refrigeration cycle, characterized in that. A mixed refrigerant comprising a plurality of refrigerants having different characteristics is circulated, and a refrigerant circuit including at least a compressor, a condenser, an expansion device, and an evaporator having a low pressure side, and the mixed refrigerant is circulated through the operation of the compressor. In a refrigeration cycle, Detection means for detecting a physical state of the mixed refrigerant circulating in the refrigerant circuit; Storage means disposed in the refrigerant circuit for storing liquefied refrigerant in the refrigerant circuit; Refrigerant supply means for supplying liquefied refrigerant stored in the storage means to a predetermined position in the refrigerant circuit in which the mixed refrigerant circulating in the refrigerant circuit is located on the low pressure side of the compressor; Flow rate adjusting means for adjusting the amount of liquefied refrigerant passing through the refrigerant supply means; Control means for controlling the flow rate adjusting means based on the physical state of the mixed refrigerant detected by the detecting means, wherein the flow rate of the liquefied refrigerant passing through the refrigerant supply means is in a physical state detected by the detecting means. Control means for controlling based on the control to allow the physical state of the mixed refrigerant circulating in the refrigerant circuit to converge to a predetermined range; And A gas-liquid separation means installed in the vacuum side of the compressor in the refrigerant circuit, The refrigerant supply means supplies the liquefied refrigerant to the inlet port of the gas-liquid separation means through the flow rate adjusting means, and the mixed refrigerant circulating in the refrigeration cycle includes at least R-32 (difluoromethane) and R- A refrigeration cycle, characterized in that formed by 125 (pentafluoroethane). The physical quantity of the mixed refrigerant detected by the detecting means is any one of a ratio of a specific refrigerant in the mixed refrigerant and a temperature of the mixed refrigerant present in a reduced pressure in the refrigerant circuit. Refrigeration cycle.