JP5569406B2 - Air conditioner - Google Patents

Description

  The present invention relates to a power supply device and an air conditioner equipped with the same, and more specifically, the current detection means can be reduced in size by reducing the loss in the current detection means at high load, and the low load The present invention relates to a power supply device that stabilizes time control and an air conditioner including the same.

  Conventionally, in a power supply device equipped with a switching converter for power factor improvement and mounted on various electric devices, the current flowing to the input side of the power supply device is driven to simulate the input voltage. In some cases, the power factor is improved by reducing the phase difference between the input voltage and the current flowing on the input side of the power supply device (for example, see Patent Document 1).

  The power supply device described in Patent Document 1 includes a rectifier that rectifies an AC power supply voltage into a pulsating voltage, a boosting choke coil, a switching element, and an input voltage that is connected in parallel to the output side of the rectifier and detects an input voltage. A detection circuit, an input current detection circuit for detecting a current flowing in a boost choke coil connected in series between a rectifying element and a load (such as a motor connected to the output terminal of the switching power supply circuit), an input voltage detection circuit, And a control means for inputting a signal detected by the input current detection circuit and controlling on / off of the switching element.

  The control means detects the current flowing through the boosting choke coil, and drives the switching element so that it becomes a pseudo-like shape of the input voltage. Then, the control means compares the current value detected by the input current detection circuit with the target current value, and if the current current value is lower than the target current value, the switching element is turned on and the current current value is set to the target current value. Control the current value. As a result, an input current having a magnitude corresponding to the load is supplied, and the power factor is improved by reducing the phase difference between the input voltage and the input current.

JP-A-9-84355 (pages 4-6, FIG. 1)

  In the switching power supply circuit described above, for example, when a shunt resistor is used for the input current detection means, when the load is small, the time during which the switching element is turned on is controlled to be short. Since the value of the switching current flowing at this time becomes small, the detection level at the input current detection means becomes small, the current cannot be detected accurately, and the control may become unstable. Therefore, in order to perform stable control at low load, it is necessary to increase the detection level of the input current detection means by increasing the resistance value of the shunt resistor. However, when the resistance value of the shunt resistor is increased, there is a problem that power consumption at the shunt resistor at a large current increases and loss increases.

  The present invention solves the above-described problems, reduces the loss in the current detection means at the time of high load, thereby reducing the size of the current detection means, and stabilizes the control at the time of low load, and the power supply apparatus It aims at providing the air conditioner provided with.

In order to solve the above problems, an air conditioner of the present invention is an air conditioner including an outdoor unit including an outdoor unit control means and a power supply device,
The power supply device includes a rectifier circuit, an inductor, a diode, a smoothing capacitor, a switching element that switches a current flowing through the inductor , and a main switching element that always switches during a switching operation, a plurality of sub-switching elements, and the main switching device. A current detection means for detecting a current flowing through the switching element as a detection voltage , and a signal output from the outdoor unit control means corresponding to the load of the outdoor unit, and the number of the switching elements that perform the switching operation. A multiplier for inputting a designated number signal and the detection voltage and outputting a multiplied detection voltage; and a converter control means for inputting the detection voltage multiplied by the multiplier and outputting a switching signal to the switching element. And
The inductor and the diode are connected in series between one end on the output side of the rectifier circuit and one output end of the power supply device,
One end of each of the main switching element and the current detection means is connected, the other end of the main switching element is between the inductor and the diode, and the other end of the current detection means is the rectifier circuit. Connected to the other end of the output side,
The plurality of sub-switching elements have one end connected between the inductor and the diode, and the other end connected to the other end on the output side of the rectifier circuit,
The smoothing capacitor, the cathode side of one end of the diode, to the output side of the other ends of said rectifier circuit are connected respectively,
The power supply device drives a number of the switching elements corresponding to the number signal output from the outdoor unit control means,
The converter control means outputs a switching signal using the detection voltage multiplied by the multiplier.

In the air conditioner power supply apparatus configured as described above, a number of switching elements corresponding to the number signal are driven. The power supply device further includes a multiplier that outputs a detection voltage multiplied by a number signal that specifies the number of switching elements that perform a switching operation and a detection voltage, and a detection voltage that is multiplied by the multiplier. Converter control means for outputting a switching signal to the switching element, and when the switching current is large at high load, the switching current can be dispersed by simultaneously turning on the plurality of switching elements. Therefore, even if the resistance value of the current detection means is increased in order to increase the detection level of the current detection means at low load and stabilize the control at low load, the current detection means at high load due to dispersion of switching current. Loss can be reduced. Furthermore, the current detection means can be reduced in size by reducing the loss in the current detection means.

It is a principal part block diagram of the air conditioner which is an Example of this invention. FIG. 3 is an explanatory diagram illustrating a driving principle of a switching element in an embodiment of the present invention. It is a flowchart explaining the process in the outdoor unit control means in the Example of this invention.

  Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. As an embodiment, an air conditioner having an outdoor unit and an indoor unit will be described by taking a power supply device provided in the outdoor unit as an example. The present invention is not limited to the following embodiments, and can be variously modified without departing from the gist of the present invention.

  As shown in FIG. 1, an air conditioner 100 according to the present invention includes an outdoor unit 1 and an indoor unit 3. The outdoor unit 1 includes a rectifier circuit 11, a step-up coil 12 that is an inductor, a diode 13, an inverter 14, a compressor 15, a first switching element 16 that is a main switching element, and a second that is a sub-switching element. A switching element 17, a shunt resistor 18, a smoothing capacitor 19, an outdoor unit control means 20, a converter control means 25, an AND circuit 26, and a multiplier 27 are provided. The converter control means 25 is configured by a conventional circuit that inputs an input current calculation signal (to be described later) and a load size of the air conditioner 100 from the multiplier 27 and performs boosting and power factor improvement.

  In addition to the above, the outdoor unit 1 includes various devices and parts necessary for the operation of the outdoor unit 1, such as heat exchangers, accumulators, valves such as four-way valves and expansion valves, exhaust fans, refrigerant piping, and various sensors. Although provided, it is not directly related to the present invention, and therefore detailed description thereof is omitted. Further, in the configuration described above, the outdoor unit 1 is obtained by removing the inverter 14 and the compressor 15 (hereinafter referred to as a load unless otherwise required) and the outdoor unit control means 20. Is configured. Further, the inverter 14 is provided with inverter control means (not shown) for controlling the operation of the inverter 14, and PWM driving is performed on a three-phase brushless motor (not shown) provided in the compressor 15 (capacity variable type compressor). Yes. The inverter control means, for example, grasps the magnitude of the load (high load / low load) by the PWM drive pulse width and outputs it to the outdoor unit control means 20.

  The rectifier circuit 11 is a circuit that rectifies an AC power supply voltage supplied from the AC power supply 2 to obtain a pulsating voltage, and is configured by a bridge diode or the like. As shown in FIG. 1, one end of each of the first line 4 and the second line 5 is connected to the input side of the rectifier circuit 12. The other ends of the first line 4 and the second line 5 are connected to the AC power supply 2 in the indoor unit 3, and when the switch 30 provided in the indoor unit 3 is turned on, as described above, the rectifier circuit 11 is supplied with AC power.

  A booster coil 12 and a diode 13 are connected in series between one end on the output side of the rectifier circuit 11 and one end on the input side of the inverter 14. The collector terminals of the first switching element 16 and the second switching element 17 are connected between the booster coil 12 and the diode 13. A shunt resistor 18 is connected in series between the emitter terminal of the first switching element 16, the other end on the output side of the rectifier circuit 11, and the other end on the input side of the inverter 14. The emitter terminal of the second switching element 17 is connected between the other end on the output side of the rectifier circuit 11 and the other end on the input side of the inverter 14. The one end and the other end on the input side of the inverter 14 correspond to the output end of the power supply device.

  The smoothing capacitor 19 has one end between the cathode side of the diode 13 and one end on the input side of the inverter 14, and the other end between the other end on the output side of the rectifier circuit 11 and the other end on the input side of the inverter 14. , Each connected.

  The pulsating voltage output from the rectifier circuit 11 passes through the diode 13 and is smoothed by the smoothing capacitor 19. On the other hand, when the first switching element 16 is turned on and the booster coil 12 is short-circuited, the energy stored in the booster coil 12 causes the diode 13 to be released when the first switching element 16 is turned off and opened. The voltage is boosted by passing and adding to the voltage of the smoothing capacitor 19. The inverter 14 converts the input DC voltage into an AC voltage and drives a three-phase brushless motor (not shown) of the compressor 15.

The first switching element 16 and the second switching element 17 are insulated gate bipolar transistors (hereinafter referred to as IGBT) having the same characteristics. In the present embodiment, the first switching element 16 and the second switching element 17 use IGBTs having the same characteristics, but may be other switching elements such as MOS-FETs having the same characteristics. Further, two types of switching elements having different characteristics may be used.
As shown in FIG. 1, the gate of the first switching element 16 is connected to the converter control means 25. The gate of the second switching element 17 is connected to the output terminal of the AND circuit 26.

  The outdoor unit control means 20 is provided on a control board (not shown) of the outdoor unit 1. As shown in FIG. 1, the outdoor unit control means 20 includes a microcomputer 21, a storage unit 22, a communication unit 23, and a sensor input unit 24. A detection signal from each sensor of the outdoor unit 1 is input to the microcomputer 21 via the sensor input unit 24, and communication data including control details of the outdoor unit 1 transmitted from the indoor unit 3 is transmitted to the communication unit 23. Is input through. The microcomputer 21 controls the inverter 14 based on these inputted various information.

  The storage unit 22 includes a ROM and a RAM, and stores a control program for the outdoor unit 1, detection values corresponding to detection signals from the sensors, current setting information for the outdoor unit 1, and the like. The communication unit 23 is an interface that performs communication with the indoor unit 3. The sensor input unit 24 receives detection signals from the sensors.

  The converter control means 25 receives the input voltage detected by an input voltage detection means (not shown) and the voltage value Vf detected by the shunt resistor 18 via the multiplier 27. Further, the converter control unit 25 inputs a voltage corresponding to the magnitude of the load taken in by the outdoor unit control unit 20 from the outdoor unit control unit 20. Based on these input signals, converter control means 25 outputs a switching signal so that the current flowing through the input side of the power supply apparatus becomes a pseudo shape of the input voltage.

  The AND circuit 26 has one input terminal connected to the outdoor unit control means 20 and the other end connected to the gate of the first switching element 16 and the converter control means 25. The output terminal of the AND circuit 26 is connected to the gate of the second switching element 17 as described above. The AND circuit 26 outputs a switching signal to the gate of the second switching element 17 when the switching signal output from the converter control means 25 is input and the number signal of the switching elements output from the outdoor unit control means 20 is a Hi signal. To do. As a result, the second switching element 17 is also switched and driven simultaneously with the first switching element 16.

  The multiplier 27 has one input terminal connected between the first switching element 16 and the shunt resistor 18, and the other end connected between the AND circuit 26 and the outdoor unit control means 20. The output terminal of the multiplier 27 is connected to the converter control means 25. A detection voltage detected by the shunt resistor 18 is input to the multiplier 27. Further, the multiplier 27 has a number signal output from the outdoor unit control means 20, that is, a voltage corresponding to the number of driving switching elements (for example, 0V (Lo signal) if the number of driving switching elements is one), If there are two, 5V (Hi signal)) is input. The multiplier 27 calculates the input current by using the input detection voltage as it is when the voltage corresponding to the number of switching elements to be driven is 0 V, and when the voltage is 5 V, the input detection voltage is doubled. The signal is output to the converter control means 25 as a signal.

  The indoor unit 3 includes various devices and components necessary for the operation of the indoor unit 3 such as a heat exchanger, a blower fan, a refrigerant pipe, various sensors, and an indoor unit control unit in addition to the switch 30 described above. The detailed description is omitted because it is not directly related to the invention.

  Next, in FIG. 1 and FIG. 2, in the air conditioner 100 including the power supply device according to the present embodiment, the current corresponding to the load of the air conditioner 100 and flowing on the input side of the power supply device is similar to the input voltage. The principle, operation, and effect of driving each switching element will be described so as to be shaped. The shunt resistor 18 is the current detection means of the present invention.

  FIG. 2 is a diagram for explaining the driving principle of the switching element. In FIG. 2, the vertical axis represents the detected voltage value Vf detected by the shunt resistor 18, and the horizontal axis represents the switching current value Is flowing through the switching element when the switching element is turned on. Vy on the vertical axis represents a design upper limit value that can be applied to the shunt resistor 18. Ix on the horizontal axis is a design upper limit value of the current that can be passed through the booster coil 12, and at this time, the load of the power supply device is maximized. The horizontal axis indicates the load size L of the power supply device in association with the switching current value Is described above, and the maximum load value Lx corresponds to the upper limit value Ix of the switching current value Is. .

  As shown in FIG. 2, when the switching current value Is is smaller than Ix / 2, that is, when the load size L is smaller than Lx / 2, only the first switching element 16 is driven. At this time, the switching current value Is is equal to the current value Ia flowing through the first switching element 16 when the first switching element 16 is turned on.

  When the switching current value Is is equal to or greater than Ix / 2, that is, when the load size L is equal to or greater than Lx / 2, the first switching element 16 and the second switching element 17 are driven simultaneously. At this time, the switching current value Is includes a current value Ia flowing through the first switching element 16 when the first switching element 16 is turned on and a current value Ib flowing through the second switching element 17 when the second switching element 17 is turned on. Is equal to the sum of

  The resistance value of the shunt resistor 18 is determined based on a design upper limit value of the current that can flow through the booster coil 12. As described in the background art, generally, when the shunt resistor 18 is connected between the emitter terminal or collector terminal of the first switching element 16 and the output side of the rectifier circuit 11, it is added to the shunt resistor 18. The resistance value of the shunt resistor 18 is set so that the current that can flow through the booster coil 12 becomes the design upper limit value when the voltage that can be applied becomes the design upper limit value.

  The design upper limit value of the current that can be passed through the booster coil 12 is determined by the booster coil 12 determined from the specifications of the power supply device. The voltage detection level at the shunt resistor 18 is determined by the magnitude of the resistance value of the shunt resistor 18. When the resistance value of the shunt resistor 18 is large, the power consumption at the shunt resistor 18 increases as the current flowing through the booster coil 12 increases. In other words, the loss at the shunt resistor 18 increases. It is necessary to make the resistance value of the shunt resistor 18 as small as possible. However, when the resistance value of the shunt resistor 18 is decreased, the load of the power supply device is decreased, that is, the detection level (the level of the detection voltage value Vf) at the shunt resistor 18 is decreased as the current flowing through the booster coil 12 is decreased. The voltage cannot be accurately detected by the shunt resistor 18.

In the power supply device, the input voltage detected by the input voltage detection means and the current flowing through the booster coil are detected and captured, and the switching element is switched so that the current flowing through the input side of the power supply device has a pseudo similarity to the input voltage. . Therefore, if the current flowing through the booster coil 12 cannot be accurately detected, the control may become unstable.
From the above, in the power supply device, when the load is low, that is, when the current flowing through the booster coil 12 is small, the resistance value of the shunt resistor 18 is increased to increase the voltage detection level. When is large, it is desired to reduce the current flowing through the shunt resistor to reduce the power consumption (loss is reduced).

  Therefore, in this embodiment, the shunt resistor 18 is connected in series to the first switching element 16 that always performs the switching operation, and the detection voltage value Vf applied to the shunt resistor 18 is detected. The resistance value of the shunt resistor 18 is a resistance value at which the detected voltage value Vf becomes Vy when the switching current value Is is Ix / 2, which is a half value of the upper limit value Ix.

  The number of switching elements to be driven is determined according to the load L, not the current flowing through the shunt resistor 18, as configured above. Specifically, as shown in FIG. 2, only the first switching element 16 is driven until the switching current value Is reaches Ix / 2 (the load size L is Lx / 2), and the switching current value Is is Ix / 2 (the load size L is Lx / 2) or more, the first switching element 16 and the second switching element 17 are driven simultaneously, and the switching current value Is and the current Ia flowing through the first switching element 16 and the first switching element 16 are driven. 2 is distributed to the current Ib flowing through the switching element 17. In the case where the first switching element 16 and the second switching element 17 are the IGBTs of this embodiment, each switching element operates so that the currents flowing through them are balanced, so that the current concentrates on one switching element. Will not flow.

  If the magnitude of the load is equal to or greater than a predetermined value (Lx / 2 or more in the present embodiment), the second switching element 17 is also driven. Therefore, as shown in FIG. 2, the load increases and the switching current value Is increases. Even then, the detected voltage value Vf applied to the shunt resistor 18 rises only up to Vy. When the shunt resistor 18 is connected between the emitter terminal or collector terminal of the first switching element 16 and the output side of the rectifier circuit 11, the current detection can be achieved by trying to obtain the same low load detection level as in the present invention. In the present invention, even when the resistance value of the shunt resistor 18 is increased, the loss at high load can be reduced, so that the shunt resistor 18 can be reduced in size, and The detection level at the time of low load can be raised and stable control of the power supply device can be performed.

  Next, a specific operation of the air conditioner 100 including the power supply device according to the present invention will be described with reference to the flowchart shown in FIG. The flowchart shown in FIG. 3 explains the flow of processing in the microcomputer 21 of the outdoor unit control means 20, where ST represents a step and the subsequent numbers represent step numbers. Note that FIG. 3 mainly describes the processing related to the present invention. Switching of the four-way valve in the outdoor unit 1, the rotation speed of the compressor 15 corresponding to the set temperature designated by the user, and the opening of each expansion valve are explained. Description of other processing such as degree adjustment is omitted.

  When the user operates the remote controller to instruct the indoor unit 3 to start operation, or when the air conditioner 100 starts operating at the reserved operation start time, the switch 30 of the indoor unit 3 is turned on and the outdoor unit 1 is turned on. The microcomputer 21 activated when the power is turned on activates the converter control means 25 of the outdoor unit 1 (ST1). The activated converter control means 25 detects an input voltage by an input voltage detection means (not shown) and stores it. Converter control means 25 detects and stores detected voltage value Vf. Since the initial value of the number signal output from the outdoor unit control means 20 is the Lo signal (0 V), the multiplier of the multiplier 27 is “1”.

  Next, the microcomputer 21 takes in the magnitude of the current load of the air conditioner 100 from the inverter 14 (ST2). Note that the microcomputer 21 stores the magnitude of the loaded load in the storage unit 22. Next, the microcomputer 21 determines the number of driving switching elements according to the stored load size (ST3). Specifically, the microcomputer 21 compares the magnitude of the acquired load with the threshold value of the load stored in the storage unit 22 (load magnitude L: Lx / 2), and if the acquired load is smaller than the threshold value. If only the first switching element 16 is equal to or greater than the threshold value, a number signal is output so that the first switching element 16 and the second switching element 17 are switched.

Next, the microcomputer 21 outputs a number signal corresponding to the determined number of drive switching elements to the AND circuit 26 and the multiplier 27 (ST4). The number signal is, for example, a Lo signal when only the first switching element 16 is driven, and a Hi signal when the first switching element 16 and the second switching element 17 are simultaneously driven.
The microcomputer 21 that performed the process of ST4 returns the process to ST2.

  The multiplier 27 to which the number signal is input outputs to the converter control means 25 an input current calculation signal obtained by multiplying the detection voltage Vf detected by the shunt resistor 18 by the number signal. Converter control means 25 calculates the input current flowing through booster coil 12 using the input current calculation signal. The converter control means 25 outputs a switching signal to the first switching element 16 and the AND circuit 26 so that the input current is pseudo-similar to the input voltage.

Specifically, converter control means 25 outputs a Hi switching signal to first switching element 16 and AND circuit 26 for a predetermined time. The first switching element 16 to which the Hi signal is input is turned on for a predetermined time. The AND circuit 26 outputs the Hi signal to the second switching element 17 when the Hi signal from the outdoor unit control means 20 and the Hi signal from the converter control means 25 are input, and the second switching element 17 It turns on for the same time as the first switching element 16.

As described above, in the power supply device for an air conditioner of the present invention, the number of switching elements corresponding to the number signal is driven. In addition, the power supply device receives a number signal that specifies the number of switching elements that perform switching operation and a detection voltage, and outputs a detection voltage multiplied by a multiplier 27, and a detection voltage multiplied by the multiplier 27 is input. Since the converter control means 25 for outputting a switching signal to the first switching element 16 and the second switching element 17 is provided , when the current flowing through the booster coil 12 is large when the switching element is turned on, The current If flowing through the shunt resistor 18 can be reduced by simultaneously turning on the switching element 16 and the second switching element 17. Therefore, even if the resistance value of the current detection means is increased in order to increase the detection level of the current detection means at low load and stabilize the control at low load, the current detection means at high load due to dispersion of switching current. Loss can be reduced. Furthermore, the current detection means can be reduced in size by reducing the loss in the current detection means.

  Moreover, if the power supply device of the present invention is mounted on an air conditioner as described in the present embodiment, the number of driving switching elements provided in the power supply device is determined according to the load of the air conditioner. Therefore, by reducing the loss in the current detection means at the time of high load, the current detection means can be downsized, and the air conditioner can be downsized. Moreover, since the loss in the current detection means at the time of high load can be reduced, the detection level at the current detection means at the time of low load can be raised, and the air conditioning control at the time of low load can be stabilized.

  In the above-described embodiments, the power supply device including one main switching element and one sub-switching element has been described as an example. However, the maximum switching current value and current corresponding to the required load are described. Two or more sub-switching elements may be provided according to the upper limit value of the voltage applied to the detection means. Although the case where a shunt resistor is provided as the current detection means has been described, another detection means such as a current transformer may be used instead of the shunt resistance.

  The number of switching elements to be driven is determined by the outdoor unit control means and the corresponding number signal is output to the AND circuit 26 and the multiplier 27. However, a comparator is provided in the power supply device of the outdoor unit 1, The signal corresponding to the load of the power supply apparatus is input to one input terminal, and the signal corresponding to the threshold value for determining the number of switching elements driven to the other input terminal is input, and the comparison result is input to the AND circuit 26 and By outputting to the multiplier 27, the number of switching elements to be driven may be determined using hardware instead of using the outdoor unit control means using software. As a result, the number of drive switching elements can be switched at higher speed.

DESCRIPTION OF SYMBOLS 1 Outdoor unit 2 AC power supply 3 Indoor unit 4 1st line 5 2nd line 11 Rectifier circuit 12 Boost coil 13 Diode 14 Inverter 15 Compressor 16 1st switching element 17 2nd switching element
18 shunt resistor 19 smoothing capacitor 20 outdoor unit control means 21 microcomputer 22 storage unit 23 communication unit 24 sensor input unit 25 converter control unit 26 AND circuit 27 multiplier 30 switch 100 air conditioner Ia current value flowing when the first switching element is turned on Ib Current value that flows when second switching element is turned on 1s Switching current value Vf Detection voltage value Ix Upper limit value in design of current that can be supplied to power supply device Vy Upper limit value in design of voltage applied to shunt resistor

Claims (1)

An air conditioner including an outdoor unit equipped with an outdoor unit control means and a power supply device,
The power supply device includes a rectifier circuit, an inductor, a diode, a smoothing capacitor, a switching element that switches a current flowing through the inductor , and a main switching element that always switches during a switching operation, a plurality of sub-switching elements, and the main switching device. A current detection means for detecting a current flowing through the switching element as a detection voltage , and a signal output from the outdoor unit control means corresponding to the load of the outdoor unit, and the number of the switching elements that perform the switching operation. A multiplier for inputting a designated number signal and the detection voltage and outputting a multiplied detection voltage; and a converter control means for inputting the detection voltage multiplied by the multiplier and outputting a switching signal to the switching element. And
The inductor and the diode are connected in series between one end on the output side of the rectifier circuit and one output end of the power supply device,
One end of each of the main switching element and the current detection means is connected, the other end of the main switching element is between the inductor and the diode, and the other end of the current detection means is the rectifier circuit. Connected to the other end of the output side,
The plurality of sub-switching elements have one end connected between the inductor and the diode, and the other end connected to the other end on the output side of the rectifier circuit,
The smoothing capacitor, the cathode side of one end of the diode, to the output side of the other ends of said rectifier circuit are connected respectively,
The power supply device drives a number of the switching elements corresponding to the number signal output from the outdoor unit control means,
The air conditioner characterized in that the converter control means outputs a switching signal using the detection voltage multiplied by the multiplier .

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