JP4136155B2 - Air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air conditioner that achieves air conditioning in a room by blowing out air whose temperature is controlled by a refrigerant into the room.
[0002]
[Prior art]
An air conditioner (hereinafter referred to as an “air conditioner”) that harmonizes indoor air uses a refrigerant that circulates in the refrigeration cycle for cooling or heating, or performs a cooling operation by a refrigeration cycle using a refrigerant and uses hot water. There is a hot water air conditioner (hot water air conditioner) that performs heating operation.
[0003]
In general, in an air conditioner, a flap motor that controls a cross flow fan and a flap together with a heat exchanger is provided in an indoor unit. The outdoor unit includes a compressor motor that drives a compressor, a fan motor that cools the outdoor heat exchanger, and the like. Is provided.
[0004]
In such an air conditioner, after operating power supplied to the indoor unit is transformed, it is converted into DC power of a predetermined voltage by a rectifying element, and the microcomputer is operated by this DC power.
[0005]
Generally, 12V and 5V DC power is used for the operation of the microcomputer. In the rectifier circuit provided in the air conditioner, a three-terminal regulator for 12V and a three-terminal regulator for 5V are used and are stepped down by a transformer. After the AC power is rectified, 12V DC is obtained by the 12V three-terminal regulator, and this power is input to the 5V three-terminal regulator to obtain 5V power.
[0006]
In the air conditioner, the cross flow fan and the flap motor are driven by the electric power supplied to the indoor unit, and AC power is supplied to the outdoor unit to drive the compressor motor. At this time, the operation of each device such as a crossflow fan, a flap motor, and a compressor is controlled by a microcomputer, and an operation display LED is turned on to display an operation state.
[0007]
By the way, when the power supply voltage decreases, the voltage of the DC power supplied to the microcomputer also decreases. In general, the microcomputer is set with an operable voltage, and stops operating when the supplied power falls below the operable voltage range.
[0008]
On the other hand, the power supply voltage supplied to the air conditioner varies depending on the surrounding environment. In the above-described general power supply circuit, the 5V three-terminal regulator uses the output power of the 12V three-terminal regulator, so the output voltage is less likely to be affected by changes in the power supply voltage. When a so-called instantaneous power failure occurs in which the output voltage is susceptible to voltage fluctuations of the AC power supply and the power supply voltage decreases instantaneously, the output voltage of the 12V three-terminal regulator decreases. As a result, the microcomputer may temporarily stop operation and be in a reset state.
[0009]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described facts, and an object thereof is to propose an air conditioner that prevents a microcomputer serving as a control means from being easily stopped and reset when an instantaneous power failure occurs. And
[0010]
[Means for Solving the Problems]
In order to achieve the above object, the present invention operates with a power supply circuit that outputs DC power of a predetermined voltage when a power supply of a predetermined voltage is supplied, and a power of a voltage within a predetermined range supplied from the power supply circuit. An air conditioner that performs air conditioning while controlling the operation of a load including a compressor provided in a refrigeration cycle by the power supply power of the predetermined voltage by the control means, the power supply voltage Detecting means for detecting a power failure in which the supply of power stops due to a decrease in power, and a stop for stopping the supply of power to the load when detecting that the power supply voltage has decreased by the detecting means To reduce power consumption and delay the stopping of the control means And a load suppression means.
[0011]
According to the present invention, a control unit such as a microcomputer operates when supplied with electric power having a voltage within a predetermined range, and controls an electric power load including a compressor to perform an air conditioning operation.
[0012]
At this time, if a power failure occurs and the power supply voltage drops, the detection means detects the voltage drop and activates the load suppression means before the voltage output from the power supply circuit reaches the voltage at which the control means operates. And stop supplying power to the load.
[0013]
Thereby, the time until the control means stops can be extended. That is, if the load is large at the time of a power failure, the voltage can be reduced in a short time or the load can be reduced to extend the time for the voltage to decrease, and the control means can be operated during that time. That is, the voltage drop can be temporarily suppressed, and the control means can be prevented from stopping instantaneously.
[0014]
In this way, when the operation time of the control means is extended, it is possible to prevent the control means from being reset due to an instantaneous power failure by taking measures against the power failure.
[0015]
According to a second aspect of the present invention, the power supply circuit outputs a first predetermined voltage output from a first predetermined voltage supplied to the control means, and a first predetermined voltage output from the first output means. And a second output means for outputting power of a second predetermined voltage supplied from the voltage power to the control means, and the detection means is set to the first predetermined voltage. Comparing means for comparing the corresponding third voltage with the second predetermined voltage, and a power failure determining means for determining a decrease in the power supply voltage based on a comparison result of the comparing means. .
[0016]
According to this invention, when the voltage of the power supply is reduced due to a power failure, the first output voltage is lowered before the second output voltage. A voltage drop due to a power failure can be detected before reaching the voltage at which the control means stops from the first output voltage and the second output voltage.
[0017]
That is, with a simple configuration that compares the voltage corresponding to the first output voltage and the second output voltage, it is possible to detect a power failure before the control means stops and delay the stop of the control means.
[0018]
The invention according to claim 3 is characterized in that the load suppression means stops at least the compressor.
[0019]
According to this invention, the compressor which is the largest load is stopped. Thereby, it can delay that a control means stops efficiently and reliably.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0021]
FIG. 1 shows a schematic configuration of an air conditioner applied to the present embodiment. This air conditioner is a hot water air conditioner (hereinafter referred to as “hot water air conditioner 10”) that performs cooling using a refrigerant circulating in the refrigeration cycle and also performs heating with hot water.
[0022]
The hot water air conditioner 10 includes an indoor unit 12 installed indoors and an outdoor unit 14 arranged outdoors.
[0023]
In the indoor unit 12, an indoor unit 22 including a heat exchanger 20 formed by an evaporator 16 as a refrigerant heat exchanger and a radiator 18 as a hot water heat exchanger is housed in a casing (not shown). . The outdoor unit 14 also includes a refrigerant unit 24 that forms a refrigeration cycle with the evaporator 16 of the indoor unit 12, and a hot water unit 26 that generates hot water and circulates the generated hot water between the radiator 18. I have.
[0024]
The outdoor unit 14 may be an integrated unit in which the refrigerant unit 24 and the hot water unit 26 are accommodated in the same casing, and the refrigerant unit 24 and the hot water unit 26 are provided separately. There may be.
[0025]
The air conditioner to which the present invention is applied may be a so-called multi-type in which each of the refrigerant unit 24 and the hot water unit 26 is connected to the plurality of indoor units 12, and the hot water unit 26 includes Other hot water heating equipment such as a floor mat for performing floor heating may be connected, or may be used for hot water supply.
[0026]
Furthermore, an air conditioner to which the present invention is applied may be one that performs cooling and heating with a refrigerant that circulates in the refrigeration cycle without using hot water, or may be dedicated to cooling.
[0027]
The indoor unit 22 and the refrigerant unit 24 are connected by refrigerant pipes 28A and 28B, and one end of the refrigerant pipes 28A and 28B is connected to the evaporator 16, respectively. The other ends of the refrigerant pipes 28A and 28B are connected to valves 32 and 48 provided in the refrigerant unit 24, respectively.
[0028]
The valve 32 is connected to the suction side of the compressor 40 via a muffler 34A and an accumulator 38, and the discharge side of the compressor 40 is connected to an outdoor heat exchanger 42 serving as a condenser via a muffler 34B. The outdoor heat exchanger 42 is connected to a valve 48 via a capillary tube 44 and a strainer / modulator 46, whereby a refrigerant circulation path sealed between the indoor unit 22 and the refrigerant unit 24 is formed. Is formed.
[0029]
In the hot water air conditioner 10, the cooling mode and the dry mode are selected, whereby the compressor 40 is driven to rotate and the refrigerant is circulated. The refrigerant unit 24 is provided with a blower fan 52 for cooling the outdoor heat exchanger 42. The blower fan 52 suppresses the temperature rise of the outdoor heat exchanger 42 and reduces the cooling capacity due to the temperature rise. It is preventing.
[0030]
On the other hand, the indoor unit 22 is provided with a cross flow fan 90, and indoor air is sucked by the cross flow fan 90. The sucked air passes through the heat exchanger 20 (the evaporator 16 and the radiator 18) and is blown out into the room. At this time, in the hot water air conditioner 10, when the refrigerant circulated by driving the compressor 40 circulates in the evaporator 16 of the indoor unit 22, heat is exchanged with the air passing through the evaporator 16 to cool the refrigerant. It is supposed to be.
[0031]
On the other hand, the indoor unit 22 is provided with a hot water inlet nipple 66A and a hot water outlet nipple 66B. The hot water unit 26 of the outdoor unit 14 is provided with a hot water inlet nipple 56A and a hot water outlet nipple 56B. The evaporator 18 is connected to the hot water outlet nipple 66 </ b> B and is connected to the hot water inlet nipple 66 </ b> A via the flow rate adjustment valve 68.
[0032]
The indoor unit 22 and the hot water unit 26 are connected by, for example, flexible hot water pipes (hereinafter referred to as “hot water tubes 30A and 30B”), and one hot water tube 30A is connected to the indoor unit 22. The hot water inlet nipple 66A and the hot water outlet nipple 56B of the hot water unit 26 are connected to each other, and the other hot water tube 30B connects the hot water outlet nipple 66B of the indoor unit 22 and the hot water inlet nipple 56A of the hot water unit 26.
[0033]
Further, the hot water inlet nipple 56A of the hot water unit 26 is connected to the hot water outlet nipple 56B via a pressure tank 60 having a pressure cap 58, a hot water circulation pump 62 and a hot water heat exchanger 64. Thereby, a circulation path of warm water is formed between the radiator 18 of the indoor unit 22 and the warm water unit 26, and warm water (water) is circulated by operating the pump 62.
[0034]
The hot water unit 26 is provided with a gas burner 70 to which a combustion gas is supplied from outside the apparatus. In the hot water unit 26, the gas passing through the hot water heat exchanger 64 is heated by the gas burner 70 to generate hot water, and the hot water generated by the pump 62 is circulated between the radiator 18 of the hot water unit 22. .
[0035]
In the hot water air conditioner 10, in the cooling mode, the flow rate adjustment valve 68 provided in the indoor unit 22 is closed and the operation of the hot water unit 26 is stopped. However, when the heating mode or the dry mode is selected, the gas burner 70 is ignited and the pump 62 is operated. Thereby, the hot water is supplied to the radiator 18 of the indoor unit 22 by opening the flow rate adjustment valve 68 of the indoor unit 22.
[0036]
At this time, in the hot water unit 26, the hot water heat is adjusted so that the temperature detected by the high temperature thermistor 84 provided between the hot water outlet nipple 56B and the hot water heat exchanger 64 becomes a predetermined temperature (eg, 82 ° C.) of about 80 ° C. Heating of warm water in the exchanger 64 is adjusted. Further, the opening degree of the flow variable valve 68 is adjusted based on the room temperature and the set temperature.
[0037]
Thus, the hot water air conditioner 10 performs heating or dehumidification so that the room temperature becomes the set temperature.
[0038]
The hot water unit 26 is connected with a pressure injection nipple 76 via a check valve 74 between the hot water heat exchanger 64 and the pump 62, and the pressure tank 60 is connected to the drain tank 72 via the pressure cap 58. Has been. Thereby, in the hot water unit 26, water (for example, tap water) to be circulated can be injected from the pressure injection nipple 76, and excess water can be discharged to the drain tank 72. .
[0039]
A branch pipe 80 provided with a thermal valve 78 is connected between the hot water heat exchanger 64 and the pump 62. The branch pipe 80 is provided with a hot water outlet nipple 82A provided in parallel with the hot water outlet nipple 56B, and between the hot water outlet nipple 82A and the hot water inlet nipple 82B provided in parallel with the hot water inlet nipple 56A. Can be connected to a hot water tube for circulating hot water to a floor mat (not shown). When the floor mat is connected, the hot water unit 26 controls the heating of the hot water so that a predetermined temperature is supplied by the low temperature thermistor 86 provided in the branch pipe 80.
[0040]
On the other hand, as shown in FIG. 2, the indoor unit 22 of the hot water air conditioner 10 is provided with a control board 102 provided with a microcomputer (hereinafter referred to as “microcomputer 100”) as a control means for controlling the operation of the hot water air conditioner 10. It has been.
[0041]
The control board 102 includes a power board 104, a display board 106, a switch board 108, a power relay board 110, a unit protection temperature fuse 112, a flow variable valve 68, a fan motor 114 for driving the cross flow fan 90, and the indoor unit 12. A flap motor 116 for operating a flap provided at a blow-out opening (not shown) is connected.
[0042]
The indoor unit 22 includes a room temperature sensor 118 for detecting the indoor temperature, a humidity sensor 120 for detecting the indoor humidity, and a refrigerant heat exchange temperature sensor 122 for detecting the temperature of the evaporator 18 and the temperature of the radiator 16. A hot water heat exchange temperature sensor 124 and the like are provided, which are connected to the control board 102, respectively.
[0043]
The indoor unit 22 is supplied with AC power for operation on the power supply board 104, and power is supplied to the control board 102 from the power supply board 104. The indoor unit 22 is provided with an output terminal 126 for supplying power to the refrigerant unit 24, and AC power is supplied to the output terminal 126 via the power relay board 110. The output terminal 126 is connected to the refrigerant unit 24 and supplies electric power for operation to the refrigerant unit 24 via the power relay board 110.
[0044]
The power relay board 110 is provided with a power relay 140 together with the power relay 130. The power relay 140 is normally closed when the contact 142 is opened and the hot water air conditioner 10 is operated in the cooling mode or the dry mode. Further, the microcomputer 100 performs on / off control of the refrigerant unit 24 by opening / closing the contact 134 of the power relay 130.
[0045]
That is, in the hot water air conditioner 10 applied to the present embodiment, the compressor motor 92 of the refrigerant unit 24 is rotationally driven at a constant speed according to the frequency of the supplied AC power, whereby the compressor 40 is Operated at a constant speed. In addition, the compressor 40 is operated / stopped by turning on / off the compressor motor 92 to control the cooling capacity.
[0046]
The microcomputer 100 controls the cooling capacity by turning on / off the compressor motor 92 by turning on / off the power relay 130.
[0047]
The hot water unit 26 is supplied with electric power for operation separately from the indoor unit 22, but can be supplied with electric power for operation via a terminal 136 provided in the indoor unit 22.
[0048]
In addition, the control board 102 is connected to a control board (not shown) provided in the hot water unit 26 via the wiring 138, whereby the microcomputer 100 controls the operation (on / off) of the hot water unit 26. ing.
[0049]
On the other hand, the display substrate 106 is provided with a receiving circuit 132 that receives an operation signal sent from a remote control switch for driving operation (not shown), and the operation signal received by the receiving circuit 132 is read into the microcomputer 100. The microcomputer 100 controls the refrigerant unit 24 and the hot water unit 26 together with the indoor unit 22 based on the operation signal and the detection results of sensors such as the room temperature sensor 118 and the refrigerant heat exchanger temperature sensor 122 to perform the air conditioning operation.
[0050]
In addition, the display board 106 is provided with a plurality of LEDs 128 serving as a cooling lamp, a heating lamp, and a timer lamp, and these LEDs 128 are lit based on settings such as an operation mode and a timer operation to indicate an operation state. It is supposed to be displayed.
[0051]
By the way, as shown in FIG. 3, a power supply substrate 104 includes a transformer 150, a bridge rectifier 152, a capacitor 154, a three-terminal regulator 156 serving as a first output means, and a three-terminal regulator 158 serving as a second output means ( (Hereinafter referred to as “regulators 156, 158”), and AC power of, for example, single-phase 100V is supplied to the primary side of the transformer 150. In addition, a varistor diode 160 is connected to the primary side of the transformer 150, thereby preventing an overvoltage from being applied to the transformer 150.
[0052]
A bridge rectifier 152 is connected to the secondary side of the transformer 150, and AC power transformed to a predetermined voltage by the transformer 150 is subjected to both-wave rectification by the bridge rectifier 152, and then smoothed by the capacitor 154 to be DC. Converted to electric power. The smoothed DC power is supplied to the regulator 156. Thereby, for example, 12V DC power is output. In this embodiment, the capacity of the capacitor 154 is 2200 μF as an example.
[0053]
Further, the regulator 158 is input with the DC power output from the regulator 156, whereby the regulator 158 outputs, for example, 5V DC power.
[0054]
The DC voltage output from the regulators 156 and 158 of the power supply board 104 is supplied to the control board 102, and the microcomputer 100 is driven by the DC voltage together with various components provided on the control board 102.
[0055]
Also in the power supply substrate 104, when the voltage of the AC power supply input to the temporary side of the transformer 150 is reduced as in a general power supply circuit, the output voltage on the secondary side is also reduced. For example, when a voltage of 12 V or more is input to the regulator 156, the output voltage Va is held at a constant voltage of 12 V. When the input voltage is lower than 12 V, the output voltage Va is reduced according to the decrease of the input voltage. Also decreases.
[0056]
Further, the regulator 158 holds the output voltage Vb at a constant voltage of 5V if the output voltage Va of the regulator 156, which is the input voltage, is 5V or more, but if the output voltage Va drops below 5V, Vb is also lowered.
[0057]
On the other hand, the microcomputer 100 provided on the control board 102 operates when the output voltage Va of the power supply board 104 is within a predetermined range (for example, 12V to 5V) and the output voltage Vb is 5V. Each of them stops operating when it falls below this voltage.
[0058]
On the other hand, a voltage drop detection circuit 162 is provided on the control board 102. The voltage drop detection circuit 162 includes a comparator 164 and voltage dividing resistors 166 and 168.
[0059]
The output voltage Vb of the regulator 158 is input to one input terminal of the comparator 164 as a reference voltage. Further, voltage dividing resistors 166 and 168 are connected to the other input terminal of the comparator 164, and the output voltage Va of the regulator 156 is input via the voltage dividing resistors 166 and 168.
[0060]
That is, the voltage Vc obtained by dividing the output voltage Va according to the resistance ratio of the voltage dividing resistors 166 and 168 is input.
[0061]
The output of the comparator 164 is off (L level) when the voltage Vc is higher than the voltage Vb, but the output is turned on (H level) when the voltage Vc is lower than the voltage Vb.
[0062]
The output of the comparator 164 is input to the microcomputer 100, and the microcomputer 100 detects whether or not the voltage drop of the AC power supply has occurred from the output of the comparator 164. That is, the microcomputer 100 uses the voltage drop detection circuit 162 to determine whether or not the voltage of the AC power supply has dropped from the output voltages Va and Vb of the regulators 156 and 158.
[0063]
In the present embodiment, the resistance values R1 and R2 of the voltage dividing resistors 166 and 168 are set to 12 kΩ and 10 kΩ, respectively, so that it can be detected that a voltage drop has occurred when the output voltage Va of the regulator 156 drops to 9 V. (R1 = 12k, R2 = 10k).
[0064]
As described above, the power relays 130 and 140 of the power relay board 110 are connected to the microcomputer 100. When the power relay 140 is turned on and the power relay 130 is turned on / off during the cooling operation, the refrigerant unit 24 is turned on. The compressor motor 92 is turned on / off to adjust the cooling capacity.
[0065]
On the other hand, when the microcomputer 100 detects a voltage drop by the voltage drop detection circuit 162, the microcomputer 100 stops energization of the relay coil 144 of the power relay 140. The power relay 140 closes the contact 142 by exciting the relay coil 144 in the cooling mode or the dry mode, but opens the contact 142 when the energization of the relay coil 144 is stopped. Thereby, the compressor motor 92 of the refrigerant unit 24 is stopped.
[0066]
When the microcomputer 100 detects a voltage drop, the microcomputer 100 stops the flap motor 116 and the fan motor 114 and turns off the operation display LED 128 to instantaneously suppress the power consumption in the hot water air conditioner 10. The stoppage of the microcomputer 100 due to the decrease is delayed.
[0067]
The operation of the present embodiment will be described below.
[0068]
In the hot water air conditioner 10, when an operation in the heating mode is instructed by operating a remote control switch (not shown), the hot water unit 26 of the outdoor unit 14 can be activated. In the hot water unit 26, the gas burner 70 is ignited and the pump 62 is operated. Thereby, the water in the circulation path of the warm water is heated by the warm water heat exchanger 64 to generate warm water, and this warm water is circulated between the warm water unit 26 and the indoor unit 22.
[0069]
In the indoor unit 22, the hot water is circulated while adjusting the circulation amount of the hot water by operating the opening degree of the flow control valve 68. Thereby, the air blown into the room as the conditioned air from the indoor unit 22 is heated when passing through the radiator 18 and the room is heated.
[0070]
On the other hand, in the hot water air conditioner 10, when an operation in the cooling mode is instructed, the power relay 130 is turned on to supply electric power for operation to the refrigerant unit 24. Thereby, in the refrigerant unit 24, the compressor 40 is rotationally driven at a rotation speed corresponding to the frequency of the AC power, the refrigerant circulation is started, and the air blown out as the conditioned air from the indoor unit 22 is integrated with the radiator 18. It cools when passing the provided evaporator 16. Thereby, the room is cooled.
[0071]
In the hot water air conditioner 10, when operated in the cooling mode, the flow rate adjustment valve 68 of the indoor unit 22 is closed and the operation of the hot water unit 26 is stopped. At this time, since water remains in the radiator 18 integrated with the evaporator 16, the temperature of the evaporator 16 is detected by the refrigerant heat exchanger temperature sensor 122, and when this temperature falls to a predetermined temperature, the power relay By turning off 130 and preventing the temperature of the evaporator 16 from further decreasing, the air in the radiator 18 is overcooled and frozen by the air that has passed through the evaporator 16 or the evaporator 16. Is preventing.
[0072]
By the way, the hot water air conditioner 10 is provided with a voltage drop detection circuit 162 on the control board 102, and the microcomputer 100 detects an instantaneous power failure of the AC power supply by the voltage drop detection circuit 162.
[0073]
Since this voltage drop detection circuit 162 has a simple configuration using the comparator 164 and the voltage dividing resistors 166 and 168, for example, the comparator 164 is unused in the IC provided on the control board 102. You can use what you have.
[0074]
The voltage Vc corresponding to the output voltage Va of the regulator 156 of the power supply substrate 104 and the output voltage Vb of the regulator 158 are input to the comparator 164 of the voltage drop detection circuit 162. At this time, if the voltage of the AC power supply is within a predetermined range, the output voltage Va of the regulator 156 becomes about 12 V, and the voltage Vc divided by the voltage dividing resistors 166 and 168 and inputted to the comparator 164 is the output voltage Vb. The higher voltage is about 6.5 V, and the output of the comparator 164 is kept at the L level.
[0075]
Here, when the instantaneous power failure occurs in the AC power supply, the voltage of the AC power supply decreases, so that the voltage input to the regulator 156 also decreases.
[0076]
On the other hand, in the voltage drop detection circuit 162, the output voltage Va of the regulator 156 decreases, so that the voltage Vc also decreases. The comparator 164 switches the output to the H level when the voltage Vc falls below the output voltage Vb of the regulator 158.
[0077]
In the voltage drop detection circuit 162, the resistance values R1 and R2 of the voltage dividing resistors 166 and 168 are set so that the voltage Vc drops below the voltage Vb when the output voltage Va reaches about 9V. When the output voltage Va of the regulator 156 decreases to about 9 V due to the decrease, the output of the comparator 164 turns on.
[0078]
On the other hand, the microcomputer 100 monitors the output of the comparator 164 of the voltage drop detection circuit 162. FIG. 5 shows an example of processing executed by the microcomputer 100. For example, the processing is executed when the hot water air conditioner 10 is in an operating state.
[0079]
In this flowchart, in the first step 200, it is confirmed whether or not the output of the comparator 164 has been turned on, that is, whether or not the output of the comparator 164 has been switched to the H level. Normally, if the voltage of the AC power supply is not lowered, the comparator 164 is in an off state. For this reason, a negative determination is made in step 200.
[0080]
On the other hand, when the voltage of the AC power supply decreases and the output of the comparator 164 is turned on, in step 202, the energization of the relay coil 144 of the power relay 140 is stopped and the supply of power to the refrigerant unit 24 is shut off. Thereby, the compressor motor 92 stops operation. At the same time, in the next step 204, the fan motor 114, the flap motor 116 and the like provided in the indoor unit 22 are stopped, the LED 128 is turned off, and when the flow rate adjustment valve 68 is operating, The operation of each load device is stopped by cutting off the supply of power to reduce power consumption.
[0081]
As a result, as shown in FIG. 4, when a voltage drop of the AC power supply occurs due to an instantaneous power failure, the output voltage Va output from the regulator 156 first decreases, and the output voltage Va continues to decrease as it is. As shown in the two-point production, the output voltage Vb of the regulator 158 also decreases, and the microcomputer 100 stops operating.
[0082]
On the other hand, in the hot water air conditioner 10, when the output voltage Va of the regulator 156 reaches the predetermined voltage Vs, the comparator 164 of the voltage drop detection circuit 162 is turned on. The microcomputer 100 stops loads such as the fan motor 114 and the flap motor 114 together with the compressor motor 92 when the comparator 164 of the voltage drop detection circuit 162 is turned on.
[0083]
In the hot water air conditioner 10, the power consumption is reduced by stopping the operation of the load, and the electric power stored in the coil and the capacitor, particularly the capacitor 154 provided on the power supply substrate 104 is discharged. A decrease in the output voltage Vb is suppressed.
[0084]
As a result, as shown in FIG. 4, the time until the output voltage Vb of the regulator 158 decreases is extended from time t1 to time t2. Therefore, the microcomputer 100 does not stop its operation immediately even if the voltage supplied to the power supply board 104 decreases due to a power failure or the like. For example, when the frequency of the AC power supply is 50 Hz, the microcomputer 100 is stopped in about 3 cycles (t1≈60 msec) after a power failure. Can be delayed. In particular, in the hot water air conditioner 10, the compressor motor 92 that drives the compressor 40 occupies a large load. Even if the compressor motor 92 is stopped, the operating time of the microcomputer 100 can be greatly extended.
[0085]
In addition, if the voltage supplied to the power supply substrate 104 rises during the time t2 from when the power failure starts until the microcomputer 100 stops operating, the output voltage of the regulator 156 increases. The microcomputer 100 does not stop. That is, the microcomputer 100 can be prevented from stopping its operation if it is an instantaneous power failure within the time t2.
[0086]
On the other hand, as shown in the flowchart of FIG. 5, the microcomputer 100 stores the current operation state of the hot water air conditioner 10 in the memory while the operation stop is extended (step 206). Thereby, when the power failure of the AC power supply is restored, the operation can be started in the operation state before the power failure.
[0087]
In the present embodiment, a power failure is detected from a decrease in the output voltage Va of the regulator 156 using the voltage drop detection circuit 162, but the power failure detection is not limited to this. For example, the AC power supply voltage or the output voltage Va of the regulator 156 may be A / D converted and read by the microcomputer 100 to detect a power failure.
[0088]
In this embodiment, the power relay 140 is used to stop the compressor motor 92 when a power failure is detected. However, the power relay 140 is not provided, and the power relay 130 also supplies power to the refrigerant unit 24 when a power failure is detected. The supply may be cut off.
[0089]
Note that this embodiment does not limit the configuration of the present invention. In the present embodiment, the refrigerant unit 24 that operates the compressor 40 at a constant speed has been described. However, as the refrigerant unit, a so-called inverter air conditioner that controls the cooling capacity by operating the compressor 40 by inverter control is applied. Also good.
[0090]
Further, in the present embodiment, the hot water air conditioner 10 has been described. However, the present invention is not limited to the hot water air conditioner 10 and is applied to an air conditioner having a general configuration in which air conditioning is performed by a refrigerant circulating in the refrigeration cycle by operation of the compressor 40. be able to.
[0091]
【The invention's effect】
As described above, according to the present invention, the control means detects the power failure before reaching the voltage at which the control means such as the microcomputer stops, and stops the compressor and the load including the compressor, so that the control means instantly receives the power failure. It is possible to prevent a stop and reset. Moreover, if it is a power failure for a very short time, the outstanding effect that a control means will not be stopped is acquired.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a refrigeration cycle and a hot water circulation cycle of a hot water air conditioner applied as an air conditioner of the present invention.
FIG. 2 is a block diagram showing a schematic configuration of an electric circuit of the indoor unit.
FIG. 3 is a schematic configuration diagram of a power supply board and a voltage drop detection circuit provided in the indoor unit.
FIG. 4 is a diagram showing an outline of a change in output voltage output from a power supply board at the time of a power failure.
FIG. 5 is a flow that shows an outline of a power failure detection and a process at the time of power failure detection.
[Explanation of symbols]
10 Hot water air conditioner (air conditioner)
22 Indoor units
24 Refrigerant unit
40 compressor
92 Compressor motor (load)
100 microcomputer (control means, detection means, load suppression means, power failure determination means)
102 Control board (control means, detection means, load suppression means, power failure determination means)
104 Power supply board (power supply circuit)
114 Fan motor (load)
116 Flap motor (load)
128 LED (load)
140 Power relay (load suppression means)
156 Three-terminal regulator (first output means)
158 Three-terminal regulator (second output means)
162 Voltage drop detection circuit (detection means)
164 Comparator (comparison means)
Va first output voltage
Vb second output voltage

Claims (3)

A power supply circuit that outputs DC power of a predetermined voltage when supplied with power of a predetermined voltage; and a control unit that operates by power of a voltage within a predetermined range supplied from the power supply circuit, the predetermined voltage An air conditioner that achieves air conditioning while controlling the operation of a load including a compressor provided in the refrigeration cycle by the power of the control by the control means,
Detecting means for detecting a power failure in which the supply of power stops due to a decrease in the power supply voltage;
A load suppressing means for stopping the supply of power to the load when detecting that the power supply voltage is reduced by the detecting means , suppressing power consumption, and delaying the stopping of the control means ;
The air conditioner characterized by including. The power supply circuit outputs a first predetermined voltage power supplied to the control means, and a first predetermined voltage power output from the first output means to the control means. And a second output unit that outputs power of a second predetermined voltage to be supplied, and the detection unit includes a third voltage corresponding to the first predetermined voltage, A comparison means for comparing the second predetermined voltage;
The air conditioner according to claim 1, further comprising a power failure determination unit that determines a decrease in the power supply voltage based on a comparison result of the comparison unit.   The air conditioner according to claim 1 or 2, wherein the load suppression unit stops at least the compressor.

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