JP7095555B2 - Air conditioner - Google Patents

Description

The present invention relates to an air conditioner, and more specifically, the operation is stopped when the input voltage drops below the operable lower limit voltage of the air conditioner (hereinafter referred to as the lower limit voltage), and the input voltage becomes high. It relates to a low voltage protection function that resumes operation when the voltage returns to the lower limit or higher.

Conventionally, the low voltage protection function has been realized by using a comparator (see, for example, Patent Document 1). At one input end of this comparator, a reference voltage for determining whether or not an input voltage lower than the lower limit voltage is supplied to a device subject to low voltage protection, for example, an air conditioner, is input, and the other The voltage to be compared corresponds to the input voltage is input to the input end. Then, when the lowered comparative voltage crosses the reference voltage, the output voltage of this comparator is inverted. When the compared voltage becomes less than the reference voltage using this change in output voltage, the power of the air conditioner subject to low voltage protection is turned off, or the control unit of the air conditioner subject to low voltage protection is turned off. Stop the operation of. A feedback resistor (referred to as a hysteresis resistor) that generates a hysteresis voltage for a change in the output signal of the comparator is connected between the output end of the comparator and the input end of the comparative voltage.

On the other hand, for example, some air conditioners realize such a low voltage protection function by software.
When other equipment that generates a large change in input voltage, such as a large refrigerator, is connected to the power supply line in which such an air conditioner is installed, the input voltage always changes with the operation of these equipment. It is fluctuating. Further, the voltage of the smoothing capacitor used in the DC power supply device of the air conditioner also constantly fluctuates depending on the load condition. Therefore, when determining the hysteresis voltage in consideration of these voltage fluctuations, it is necessary to provide a margin and take a large hysteresis voltage so as not to cause erroneous detection. As a result, the upper limit low voltage threshold value, which is the threshold value of the voltage at which the air conditioner is restarted after being temporarily stopped by the low voltage protection function, becomes relatively high. As a result, when the output voltage of the rectifier 3 is lower than the upper limit low voltage threshold and is slightly higher than the lower limit voltage due to the decrease in the input voltage, the low voltage protection function allows the air conditioner to be restarted once it is stopped. There is a problem that it disappears.

Next, the air conditioner equipped with the low voltage protection function by the above-mentioned software will be described in detail.
FIG. 3 is a block diagram showing an air conditioner 100 that operates using a three-phase AC power supply.
The air conditioner 100 includes an outdoor unit 140 and an indoor unit 150, and a three-phase AC power supply 2 is connected to the outdoor unit 140.

The outdoor unit 140 includes a rectifier 3 to which a three-phase AC power supply 2 is connected to an input end, an inverter unit 8 to which a positive electrode input end and a negative electrode input end are connected to the positive and negative ends of the rectifier 3, and an inverter unit. It includes a compressor motor 9 connected to the output of 8 and an outdoor unit control unit 120 that controls the entire outdoor unit 140.

Further, the outdoor unit 140 is a relay 5 which is a switch connected in series between the positive electrode end of the rectifier 3 and the positive electrode input end of the inverter unit 8, and an inrush current prevention resistance connected in parallel to both ends of the relay 5. It has a resistance 4. Further, in the outdoor unit 140, a series circuit in which the negative electrode end of the smoothing capacitor 10 and the positive electrode end of the smoothing capacitor 11 are connected between the positive electrode input end and the negative electrode input end of the inverter unit 8 and the control power supply unit 14 are arranged in parallel. It is connected.

Further, a resistance 12 is connected to the smoothing capacitor 10 and a resistance 13 is connected to the smoothing capacitor 11 in parallel. This resistance is the balance resistance. Further, the output voltage of the rectifier 3 is applied to the balance resistance, the control power supply unit 14, and the inverter unit 8. Further, the connection point between the negative electrode end of the rectifier 3 and the negative electrode end of the smoothing capacitor 11 and the negative electrode input end of the inverter unit 8 is connected to the ground.

Further, the outdoor unit 140 includes a first DC voltage detection unit 6 that detects the output voltage of the rectifier 3 and outputs the detection result as the first DC voltage value to the outdoor unit control unit 120. Since the first DC voltage value changes according to the input voltage, it corresponds to the input voltage of the air conditioner 100. Further, the first DC voltage detection unit 6 and the inverter unit 8 are supplied with power from the control power supply unit 14.

On the other hand, the outdoor unit control unit 120 is communicatively connected to the indoor unit 150, and outputs an inverter control signal to the inverter unit 8 and a relay control signal to the relay 5. Further, inside the outdoor unit control unit 120, a power supply management unit 130 that cuts off / supplies a DC voltage to the inverter unit 8 in response to a decrease / increase in the voltage of the three-phase AC power supply 2 is provided.

The power supply management unit 130 is a DC voltage threshold that opens the power-on monitoring unit 131, the power-off monitoring unit 132, and the relay 5, and is an upper limit that outputs a predetermined upper limit low voltage threshold. The low voltage threshold storage unit 133, the lower limit low voltage threshold storage unit 135 that outputs the lower limit low voltage threshold that is a DC voltage threshold that "closes" the relay 5 and has a predetermined value, and the relay to the relay 5. It includes a flip flop 134 that outputs a control signal. The upper limit low voltage threshold value> the lower limit low voltage threshold value, and the voltage difference between them is the hysteresis voltage.

The power-on monitoring unit 131 constantly monitors whether or not a first DC voltage, which is the lowest DC voltage capable of operating the air conditioner 100, is supplied. Therefore, the power-on monitoring unit 131 inputs the first DC voltage value and the upper limit low voltage threshold value, and outputs an input signal consisting of a pulse signal only when the first DC voltage value becomes equal to or higher than the upper limit low voltage threshold value. ..

The flip flop 134 to which the input signal is input to the set terminal outputs a high level relay control signal from the Q terminal, and the relay 5 to which the high level relay control signal is input closes the contact and outputs from the rectifier 3. The DC voltage to be generated is supplied to the smoothing capacitors 10 and 11. As a result, power is supplied to the inverter unit 8 and the outdoor unit 140 becomes operable.

On the other hand, the power cutoff monitoring unit 132 constantly monitors whether or not it is impossible to supply the first DC voltage capable of operating the air conditioner 100. Therefore, the power supply disconnection monitoring unit 132 outputs a disconnection signal consisting of a pulse signal only when the first DC voltage value and the lower limit low voltage threshold are input and the first DC voltage value becomes less than the lower limit low voltage threshold. do.

The flip-flop 134 in which the disconnect signal is input to the reset terminal outputs a low-level relay control signal from the Q terminal, and the relay 5 to which the low-level relay control signal is input opens the contact, and the rectifier 3 is positive. Disconnect the extreme and the positive end of the smoothing capacitor 10. As a result, the voltage to the inverter unit 8 is cut off, and the outdoor unit 140 stops operating.

Next, the operation from turning on to turning off the three-phase AC power supply 2 will be described. The relay 5 is "open" before the power is turned on, and the voltage between the positive end of the smoothing capacitor 10 and the negative end of the smoothing capacitor 11 is zero volt. When the power is turned on to the outdoor unit 140, the first DC voltage is output from between the positive end and the negative end of the rectifier 3. This voltage charges the smoothing capacitors 10 and 11 via the resistor 4, and the voltage of the smoothing capacitors 10 and 11 gradually rises.

As described above, the power-on monitoring unit 131 constantly monitors whether or not the input voltage, that is, the output voltage of the rectifier 3 is equal to or higher than the minimum operable DC voltage of the air conditioner 100. Then, the power supply management unit 130 closes the relay 5 when the first DC voltage value becomes equal to or higher than the upper limit low voltage threshold value. On the contrary, when the three-phase AC power supply 2 is cut off, the second DC voltage, which is the voltage of the smoothing capacitors 10 and 11, gradually decreases.

Therefore, the first DC voltage also gradually decreases. As described above, the power supply disconnection monitoring unit 132 constantly monitors whether or not the output voltage of the rectifier 3 is less than the minimum DC voltage at which the air conditioner 100 can operate. Therefore, the power supply management unit 130 opens the relay 5 when the first DC voltage value becomes less than the lower limit low voltage threshold value.

Next, the operation of the air conditioner 100 at a low voltage will be described with reference to the explanatory diagram of FIG.
The horizontal axis of FIG. 4 is time, and with respect to the vertical axis, FIG. 4 (1) shows the first DC voltage (thick solid line) and the second DC voltage (thin broken line), and FIG. 4 (2) shows the relay control signal. Shows. In addition, t50 to t53 are times.

On the other hand, the rated voltage range of the air conditioner 100 is 220V to 240V, and the lower limit rated voltage value (220V-10%) is 198V (phase voltage). Therefore, when this voltage is rectified, it becomes about 485V. Further, the DC voltage that can be operated by the air conditioner 100 in the example of FIG. 3 is 360V. That is, it is necessary to set 360V as the lower limit low voltage threshold value in the first DC voltage, and set the voltage equal to or higher than the lower limit low voltage threshold value and smaller than 485V as the upper limit low voltage threshold value. In the example of the air conditioner 100, the upper limit low voltage threshold value is set to 370V.

As shown in FIG. 4 (1), the first DC voltage gradually decreases after t50 in response to the decrease in the input voltage, and when this becomes less than the lower limit low voltage threshold value at t51, the power supply management unit 130 The relay control signal is set to a low level and the relay 5 is set to "open". At the same time, the outdoor unit control unit 120 stops the operation of the outdoor unit 140 and the indoor unit 150, that is, stops the operation of the air conditioner 100. When the relay 5 is "open", a current flows through the resistance 4 to the control power supply unit 14, the smoothing capacitors 10, 11 and the resistors 12 and 13, so that the potential difference generated by the resistance 4 is larger than the first DC voltage. The second DC voltage becomes low.

After that, when the first DC voltage becomes equal to or higher than the upper limit low voltage threshold value due to an increase in the input voltage, the power supply management unit 130 sets the relay control signal to a high level and closes the relay 5, so that the air conditioner 100 operates. To resume.
Here, if the input voltage stabilizes and the first DC voltage remains at 368 V during the period from t51 to t53, the air conditioner 100 remains stopped. Therefore, in an area where the power supply condition is poor such that the output voltage of the rectifier 3 is higher than the lower limit low voltage threshold value and lower than the upper limit low voltage threshold value, the operation stop time is practically long. Therefore, if the hysteresis voltage, which is the difference between the lower limit low voltage threshold value and the upper limit low voltage threshold value, is appropriately small, the operating time becomes longer in an area where the power supply condition is poor, and the user's comfort can be improved.

Therefore, when the upper limit low voltage threshold value is smaller than 370 volts and the lower limit low voltage threshold value is larger than 360 volts, the lower limit low voltage threshold value + α, for example, 365 V, is set as the upper limit low voltage threshold value, as described above, the second DC voltage. May be β volt lower than the lower limit low voltage threshold. When the first DC voltage is t52 at the lower limit low voltage threshold value + α, there is no guarantee that the outdoor unit 140 can operate at 360 V or higher even if the relay 5 is closed here. This is because when the relay 5 is closed and the operation of the inverter unit 8 is started, the operation is started at a low voltage. When the voltage input to the inverter 8 is low, the inverter type air conditioner starts operation by increasing the current as compared with the case where the input voltage is the rated voltage in order to obtain the rated air conditioning capacity. Therefore, the current flowing through the relay 5 becomes as large as about 20 amperes. As a result, the voltage of the smoothing capacitors 10 and 11 drops, and the contact resistance of the contact of the relay 5 causes a voltage drop of about 1 to 2 volts, so that the voltage input to the inverter 8 drops. ..

Therefore, hysteresis is set by setting the upper limit low voltage threshold value larger than the lower limit low voltage threshold value + α so that the relay 5 is "open" at least until t53 where the first DC voltage exceeds the upper limit low voltage threshold value obtained experimentally. It was necessary to take a large voltage. Further, it is necessary to add a margin to the upper limit low voltage threshold value in consideration of various conditions such as an increase in contact resistance due to aging of the relay 5, a decrease in the capacitance of the smoothing capacitors 10 and 11, and a temperature condition.

As described above, the input voltage of the input voltage is constantly fluctuating with the operation of other devices connected to the power supply line to which the air conditioner 100 is connected. Further, the voltage of the smoothing capacitor applied to the inverter 8 also constantly fluctuates depending on the load state, and when determining the hysteresis voltage in consideration of these, it is necessary to provide a margin and take a large hysteresis voltage. As a result, there is a problem that the upper limit low voltage threshold becomes relatively high and the voltage at which the operation of the air conditioner 100 is restored becomes high. Therefore, there has been a demand for an air conditioner that can be used in areas where power supply conditions are poor.

Japanese Unexamined Patent Publication No. 2000-4537 (paragraph numbers 0003 to 0011)

The present invention solves the above-mentioned problems, and is used in an air conditioner equipped with a switch that supplies / shuts off power to the main unit, an inrush current prevention resistor connected in parallel to this switch, and a power supply control unit. The purpose is to reduce the hysteresis voltage when supplying / shutting off the air conditioner to ensure that the air conditioner is started.

In order to solve the above-mentioned problems, the invention according to claim 1 of the present invention is an air conditioner provided with an outdoor unit, wherein the outdoor unit is.
A commutator that rectifies an AC power supply and outputs a DC voltage,
A smoothing capacitor connected between the positive and negative ends of the rectifier,
With the load connected in parallel to the smoothing capacitor,
A switch connected in series to the positive or negative end of the rectifier and one end of the smoothing capacitor,
An inrush current prevention resistor connected in parallel to the switch,
A first DC voltage detecting means that detects the output voltage of the rectifier and outputs it as a first DC voltage value.
A second DC voltage detecting means that detects the voltage across the smoothing capacitor and outputs it as a second DC voltage value.
It is characterized by comprising a power supply management means for short-circuiting the switch when both the first DC voltage value and the second DC voltage value change to a predetermined low voltage threshold value or more.

Further, according to the second aspect of the present invention, the power supply management means provided in the outdoor unit described above is used when the first DC voltage value changes to less than the low voltage threshold value, or the second one. The switch is opened when the DC voltage value changes below the low voltage threshold value.

By using the above means, according to the air conditioner according to the present invention, in the power supply management means, when both the first DC voltage value and the second DC voltage value become equal to or higher than the low voltage threshold, the switch is short-circuited and the rectifier is used. The output voltage of is supplied to the load. That is, in order to close the switch after confirming that the input voltage and the corresponding first DC voltage and the load, for example, the voltage supplied to the inverter are both equal to or higher than the operable voltage of the air conditioner, the air conditioner is started. It can be done reliably.

It is a block diagram which shows the Example of the air conditioner by this invention. It is explanatory drawing explaining the operation of the power-source management part by this invention. It is a block diagram which shows the conventional air conditioner. It is explanatory drawing explaining the operation of the conventional power-source management part.

Hereinafter, embodiments of the present invention will be described in detail as examples based on the accompanying drawings. The parts not directly related to the present invention, such as the refrigerant circuit such as the heat exchanger and the expansion valve and the fan motor, are not shown and described. In addition, the same numbers are assigned to the same parts as those described in the background art.

FIG. 1 is a block diagram showing an air conditioner 1 according to the present invention. The air conditioner 1 includes an outdoor unit 40 and an indoor unit 50, and a three-phase AC power supply 2 is connected to the outdoor unit 40.

The outdoor unit 40 includes a rectifier 3 to which a three-phase AC power supply 2 is connected to an input end, an inverter unit 8 to which a positive electrode input end and a negative electrode input end are connected to the positive and negative ends of the rectifier 3, and an inverter unit. It includes a compressor motor 9 connected to the output of 8 and an outdoor unit control unit 20 that controls the entire outdoor unit 40.

Further, the outdoor unit 40 includes a relay 5 which is a switch connected in series between the positive electrode end of the rectifier 3 and the positive electrode input end of the inverter unit 8, and a resistance 4 connected in parallel to both ends of the relay 5. .. Further, in the outdoor unit 40, a series circuit in which the negative electrode end of the smoothing capacitor 10 and the positive electrode end of the smoothing capacitor 11 are connected between the positive electrode input end and the negative electrode input end of the inverter unit 8 and the control power supply unit 14 are arranged in parallel. It is connected.

Further, a resistance 12 is connected to the smoothing capacitor 10 and a resistance 13 is connected to the smoothing capacitor 11 in parallel. This resistance is the balance resistance. Further, the voltage of the rectifier 3 is applied to the balance resistance, the control power supply unit 14, and the inverter unit 8. Further, the connection point between the negative electrode end of the rectifier 3 and the negative electrode end of the smoothing capacitor 11 and the negative electrode input end of the inverter unit 8 is connected to the ground.
Here, the resistance 4 is 15.6 ohms, the smoothing capacitor 10 and the smoothing capacitor 11 are 3840 microfarads, respectively, and the resistance 12 and the resistance 13 are 20.5 kiloohms each.

Further, the outdoor unit 40 detects the output voltage of the rectifier 3 corresponding to the input voltage, and outputs the detection result as the first DC voltage value to the outdoor unit control unit 20. The first DC voltage detecting unit (first DC voltage detecting means). ) 6, a second DC voltage detection unit (second DC) that detects the voltage applied to the series circuit of the smoothing capacitor 10 and the smoothing capacitor 11 and outputs the detection result as the second DC voltage value to the outdoor unit control unit 20. The voltage detecting means) 7 is provided. The first DC voltage value corresponds to the input voltage of the air conditioner 1, and the second DC voltage value indicates the voltage value applied to the inverter unit 8. Further, the first DC voltage detection unit 6 and the second DC voltage detection unit 7 divide the voltage to be detected by a series resistance connected to the voltage to be detected, for example, and output the voltage value by analog / digital conversion. do.

The first DC voltage detection unit 6, the second DC voltage detection unit 7, the inverter unit 8, and the outdoor unit control unit 20 are supplied with power from the control power supply unit 14. Even if the relay 5 is "open", power is supplied from the rectifier 3 to the input end of the control power supply unit 14 via the resistor 4, and the amperage is about 0.3 amperes regardless of the state of the relay 5. A degree of current is flowing.

On the other hand, the outdoor unit control unit 20 is communicatively connected to the indoor unit 50, and outputs an inverter control signal to the inverter unit 8 and a relay control signal to the relay 5. Further, inside the outdoor unit control unit 20, a power supply management unit (power supply management means) 30 that cuts off / supplies a DC voltage to the inverter unit 8 in response to a voltage drop / increase of the three-phase AC power supply 2 is provided. ..

The power supply management unit 30 is a DC voltage threshold value for opening / short-circuiting (opening / closing) the power-on monitoring unit 31, the power-off monitoring unit 32, and the relay 5, and sets a predetermined low voltage threshold value. It includes a low voltage threshold storage unit 33 for output and a flip flop 34 for outputting a relay control signal to the relay 5.

The power-on monitoring unit 31 constantly monitors whether or not the lowest DC voltage (first DC voltage and second DC voltage) that the air conditioner 1 can operate is supplied. Therefore, the power-on monitoring unit 31 has input the first DC voltage value, the second DC voltage value, and the low voltage threshold value, and the voltages of the first DC voltage value and the second DC voltage value become equal to or higher than the low voltage threshold value. The input signal consisting of the pulse signal is output only at the time.

The flip flop 34 to which the input signal is input to the set terminal outputs a high-level relay control signal from the Q terminal, and the relay 5 to which the high-level relay control signal is input closes the contact and outputs from the rectifier 3. The DC voltage to be generated is supplied to the smoothing capacitors 10 and 11. As a result, power is supplied to the inverter unit 8 and the outdoor unit 40 can operate.

On the other hand, the power supply disconnection monitoring unit 32 constantly monitors whether or not the air conditioner 1 cannot supply the operable first DC voltage and the second DC voltage. Therefore, the power supply disconnection monitoring unit 32 has input the first DC voltage value, the second DC voltage value, and the low voltage threshold value, and the voltage of either the first DC voltage value or the second DC voltage value is a low voltage. A disconnection signal consisting of a pulse signal is output only when the voltage becomes less than the threshold value.

The flip-flop 34 in which the disconnect signal is input to the reset terminal outputs a low-level relay control signal from the Q terminal, and the relay 5 to which the low-level relay control signal is input opens the contact and the rectifier 3 is positive. Disconnect the extreme and the positive end of the smoothing capacitor 10. As a result, the power supply to the inverter unit 8 is cut off, and the outdoor unit 40 stops operating.

Next, the operation from turning on to turning off the three-phase AC power supply 2 will be described. The relay 5 is "open" before the power is turned on, and the voltage between the positive end of the smoothing capacitor 10 and the negative end of the smoothing capacitor 11 is zero volt. When the power is turned on to the outdoor unit 40, the first DC voltage is output from between the positive end and the negative end of the rectifier 3. This voltage charges the smoothing capacitors 10 and 11 via the resistor 4, and the voltage of the smoothing capacitors 10 and 11 gradually rises.

As described above, the power-on monitoring unit 31 constantly monitors whether or not the air conditioner 1 has a minimum DC voltage that can be operated. Then, the power supply management unit 30 inputs the output voltage of the rectifier 3 corresponding to the input voltage and the inverter unit 8 when both the first DC voltage value and the second DC voltage value are equal to or higher than the low voltage threshold value. When both voltages are equal to or higher than the voltage at which the air conditioner 1 can operate, the relay 5 is "closed" and the air conditioner 1 is started. As a result, the air conditioner 1 can be reliably started by avoiding the input voltage shortage and the input voltage shortage of the inverter unit 8.

On the other hand, when the three-phase AC power supply 2 is cut off, the second DC voltage, which is the voltage of the smoothing capacitors 10 and 11, gradually decreases. Further, the first DC voltage also gradually decreases through the resistor 4. As described above, the power disconnection monitoring unit 32 constantly monitors whether the voltage supplied in the air conditioner 1 is less than the minimum DC voltage capable of operating the air conditioner 1. Then, the power supply management unit 30 inputs the output voltage of the rectifier 3 corresponding to the input voltage and the inverter unit 8 when either the first DC voltage value or the second DC voltage becomes less than the low voltage threshold value. The relay 5 is set to "open" when either of the voltages to be generated becomes lower than the voltage at which the air conditioner 1 can operate. As a result, the air conditioner 1 can be reliably stopped when the input voltage is insufficient or the input voltage of the inverter unit 8 is insufficient.
As described above, not only the first DC voltage value corresponding to the input voltage but also the second DC voltage value which is the input voltage of the inverter unit 8 is monitored, so that the first DC voltage is as explained in the background technology. The upper limit low voltage threshold and the lower limit low voltage threshold based on the value are not used. Therefore, the margin of the hysteresis voltage can be reduced.

The rated voltage range of the air conditioner 1 is 220V to 240V, and the lower limit rated voltage value (220V-10%) is 198V (phase voltage). Therefore, when this voltage is rectified, it becomes about 485V. Further, the DC voltage that the air conditioner 1 in the example of FIG. 1 can operate is 360V. That is, in the first DC voltage, 360 V is set as a low voltage threshold for stopping the operation of the air conditioner 1, and 365 V is set as a voltage for restarting the operation of the air conditioner 1.

Further, as described above, the resistance 4 is 15.6 ohms, and the resistance 12 and the resistance 13 are 20.5 kiloohms each. Therefore, when the relay 5 is “open” and the first DC voltage is 360 V, these are used. The current flowing through the resistor is about 0.009 amps. Further, even when the inverter unit 8 is stopped, about 0.001 amperes flow inside, and about 0.3 amperes flow into the control power supply unit 14. Therefore, a total of 0.31 amperes flows through the resistor 4, and the potential difference is about 4.8 volts.

On the other hand, while the relay 5 is "closed" and the inverter unit 8 is operating at maximum capacity, about 20 amperes flow to the contacts of the relay 5. The contact resistance of the relay 5 is several millimeters to several tens of milliohms, but in the worst case, it may be around 100 milliohms due to aging. Therefore, when the relay 5 is "closed", it is assumed that the potential difference between both ends of the relay 5 is about 2 volts. That is, when the input voltage is stable and the relay 5 is "closed", the second DC voltage is lower than the first DC voltage value by this potential difference.

Next, the operation of the air conditioner 1 at the time of low voltage will be described with reference to the explanatory diagram of FIG.
The horizontal axis of FIG. 2 is time, and with respect to the vertical axis, FIG. 2 (1) shows the first DC voltage (thick solid line) and the second DC voltage (thin broken line), and FIG. 2 (2) shows the relay control signal. 2 (3) shows a disconnection signal, FIG. 2 (4) shows an input signal, and FIG. 2 (5) shows an inverter control signal. In addition, t0 to t6 are times.

As shown in FIG. 2 (1), in response to the decrease in the input voltage, the second DC voltage, which is lower than the first DC voltage by the potential difference due to the contact resistance of the relay 5 described above, is t0 or later. The second DC voltage is below the low voltage threshold due to a sudden increase in load at t1, for example, an increase in the mechanical load of the motor 9, which increases the current of the inverter section 8. It has become.

Then, the power supply disconnection monitoring unit 32 of the power supply management unit 30 that detects that the second DC voltage is less than the low voltage threshold output a disconnection signal at t1 as shown in FIG. 2 (3), and this signal is output. The input flip-flop 34 lowers the relay control signal and opens the relay 5. At the same time, the outdoor unit control unit 20 stops the output of the inverter control signal to stop the operation of the inverter unit 8.

As described above, in the present invention, since the power supply management unit 30 monitors not only the first DC voltage corresponding to the input voltage but also the second DC voltage actually supplied to the inverter unit 8, it depends on the contact resistance of the relay 5. Even if there is a potential difference, the inverter unit 8 can be accurately stopped / operated. Therefore, the margin can be reduced when determining the hysteresis voltage.

On the other hand, when the relay 5 is "open" at t1, a current flows through the resistor 4 to the control power supply unit 14, the smoothing capacitors 10, 11 and the like, so that the potential difference generated by the resistor 4, that is, described above. When the first DC voltage is 360 volts, the second DC voltage is lower than the first DC voltage by about 4.8 volts. This potential difference becomes the hysteresis voltage.
After that, when the second DC voltage becomes equal to or higher than the low voltage threshold due to the decrease in load and the first DC voltage becomes equal to or higher than the low voltage threshold at t2, the power-on monitoring unit 31 of the power supply management unit 30 detects this. , As shown in FIG. 2 (4), an input signal is output, and the flip flop 34 to which this signal is input sets the relay control signal to a high level and closes the relay 5, so that the DC voltage is supplied to the inverter section 8. Is supplied. Then, the outdoor unit control unit 20 starts outputting the inverter control signal, operates the inverter unit 8, and restarts the operation of the outdoor unit 40.

As described above, in the present invention, when the operation of the outdoor unit 40 is restarted, that is, the condition for changing the relay 5 from "open" to "closed" is that both the first DC voltage and the second DC voltage are equal to or higher than the low voltage threshold value. That is. This means that in addition to monitoring the input voltage, it is also monitored that the second DC voltage actually supplied to the inverter unit 8 is equal to or higher than the voltage (low voltage threshold) that can be reliably operated, and the outdoor unit 40 is monitored. The operation can be reliably restarted. Further, by monitoring the opening / closing of the relay 5 with the second DC voltage, the resistor 4 can be used not only as a function as an inrush current prevention resistance but also as a hysteresis resistance.

In the circuit described in the background technique of FIG. 3, the hysteresis voltage is the difference between the upper limit low voltage threshold value and the lower limit low voltage threshold value. Since this hysteresis voltage is a predetermined value and is different from the actual hysteresis voltage, it is necessary to determine a large margin of the hysteresis voltage as described above. On the other hand, in the present invention, since the voltage of the resistor 4 is the actual hysteresis voltage, the margin of the hysteresis voltage may be small.

On the other hand, the first DC voltage and the second DC voltage temporarily increased after t2 resume to decrease, and both the first DC voltage and the second DC voltage are below the low voltage threshold value at t3. Therefore, as described above, the power supply management unit 30 sets the relay control signal to a low level and opens the relay 5.
At the same time, the outdoor unit control unit 20 stops the operation of the inverter unit 8.

Then, as the input voltage rises, the first DC voltage and the second DC voltage rise, and at t4, both the first DC voltage and the second DC voltage become equal to or higher than the low voltage threshold value, so that the power supply management unit 30 sends a relay control signal. Set to high level and close relay 5. On the other hand, the outdoor unit control unit 20 operates the inverter unit 8 to restart the operation of the outdoor unit 40.

On the other hand, the first DC voltage and the second DC voltage that gradually increased after t4 began to decrease again, and the first DC voltage became less than the low voltage threshold value at t5. Therefore, as described above, the power supply management unit 30 sets the relay control signal to a low level and opens the relay 5. At the same time, the outdoor unit control unit 20 stops the operation of the inverter unit 8. At t5, the second DC voltage has not dropped to the low voltage threshold. This is because when the first DC voltage drops sharply, the voltage charged in the smoothing capacitors 10 and 11 is discharged via the relay 5. When the contact resistance of the relay 5 increases due to aging, a potential difference of 1 to 2 volts may occur.

Then, when the first DC voltage and the second DC voltage rise due to the rise of the input voltage and both the first DC voltage and the second DC voltage reach the low voltage threshold or higher at t6, the power supply management unit 30 sets the relay control signal high. Set to level and set relay 5 to "closed". On the other hand, the outdoor unit control unit 20 operates the inverter unit 8 to restart the operation of the outdoor unit 40.

As described above, since the power supply management unit 30 monitors the second DC voltage in addition to the first DC voltage, the inverter unit 8 is accurately stopped / even if there is a potential difference due to the contact resistance of the relay 5. Can be driven. Therefore, the margin can be reduced when determining the hysteresis voltage, and the hysteresis voltage can also be reduced, so that the operation at the low voltage can be continued as much as possible.

In this embodiment, a three-phase input air conditioner is described, but the present invention is not limited to this, and a single-phase input may be used. Further, in this embodiment, an example using a balanced resistor is described, but the present invention is not limited to this, and may be a discharge resistor connected in parallel to a smoothing capacitor, a control power supply unit, or the like. A large load may be used instead of the resistor.

1 Air conditioner 2 Three-phase AC power supply 3 Rectifier 4 Resistance (inrush current prevention resistance)
5 Relay (switch)
6 1st DC voltage detection unit (1st DC voltage detection means)
7 Second DC voltage detection unit (second DC voltage detection means)
8 Inverter section (load)
9 Motor 10 Smoothing capacitor 11 Smoothing capacitor 12 Resistance (load)
13 Resistance (load)
14 Control power supply (load)
20 Outdoor unit control unit 30 Power supply management unit (power supply management means)
31 Power-on monitoring unit 32 Power-off monitoring unit 33 Low voltage threshold storage unit 34 Flip-flop 40 Outdoor unit 50 Indoor unit

Claims (2)

An air conditioner equipped with an outdoor unit, wherein the outdoor unit is
A commutator that rectifies an AC power supply and outputs a DC voltage,
A smoothing capacitor connected between the positive and negative ends of the rectifier,
With the load connected in parallel to the smoothing capacitor,
A switch connected in series to the positive or negative end of the rectifier and one end of the smoothing capacitor,
An inrush current prevention resistor connected in parallel to the switch,
A first DC voltage detecting means that detects the output voltage of the rectifier and outputs it as a first DC voltage value.
A second DC voltage detecting means that detects the voltage across the smoothing capacitor and outputs it as a second DC voltage value.
An air conditioner including a power supply management means for short-circuiting the switch when both the first DC voltage value and the second DC voltage value change to a predetermined low voltage threshold value or more. The power supply management means is characterized in that the switch is opened when the first DC voltage value changes to less than the low voltage threshold value or when the second DC voltage value changes to less than the low voltage threshold value. The air conditioner according to claim 1.

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