DE112020006797T5 - POWER CONVERTER DEVICE - Google Patents

Abstract

A power converter device is configured to power a motor provided for a compressor with power supplied from a system power supply, the power converter device including an inverter to be connected to the system power supply and the motor and having an inductor , which is connected to a power line for supplying power from the system power supply to the converter, an auxiliary winding which is configured to be magnetically coupled to the inductor, a current detection unit which is connected to the auxiliary winding and is configured to a through detecting current flowing the inductor, and a controller connected to the current detection unit using wiring and configured to control the inverter. The controller includes a determination unit configured to compare a current value detected by the current detection unit with a predetermined threshold value, and a forced energization unit configured to perform heating control on the inverter by causing the Inverter energizes a winding of the motor without driving the motor when the determination unit determines that the current value is greater than the predetermined threshold.

Description

technical field

The present disclosure relates to a power converter device configured to supply power to a load device.

background technique

A power conversion device usually generates electrical noise and if sufficient preventive measures are not implemented, such a power conversion device will cause various problems. In particular, in a case where a power conversion device operates AC power, a plurality of devices are often connected using a common power line. Because of this, noise generated by some of the multiple devices, malfunctions of some of the multiple devices, or noise generated by a power conversion device sometimes causes other devices to malfunction.

Noise is mainly generated from charging and discharging phenomena caused by a fluctuating neutral point voltage accompanying electrical switching of a semiconductor element included in a device such as an inverter. To deal with such noise, power generated at a noise source is reduced and the noise is prevented from propagating along a noise propagation path.

Noise propagation is categorized into two types based on how the noise propagates. A first of the two types of noise is called normal mode noise, which occurs between signal lines or power lines. The normal mode noise is a noise component that is generated between power lines and propagates in the same direction as a signal or current of a power line. Because normal mode noise propagates along both power lines and the propagation path is easy to identify, dealing with normal mode noise is relatively easy. For example, in order to deal with the normal mode noise, a filter formed by a normal mode inductor and a line-to-line capacitor is installed on the signal lines or the power lines.

A second type of the two types of noise is called common mode noise or common mode interference that occurs between a signal line or a power line to ground. A current caused by the common mode noise is called a zero phase sequence current. The common mode noise propagates toward the ground along the signal line or the power line, passes through a metal case, stray capacitance, and other parts, and then returns to the noise source. Because the propagation path of common mode noise is difficult to identify, common mode noise is difficult to deal with. To deal with the common mode noise, as in the case of the normal mode noise, a filter formed by a common mode coil and a grounding capacitor is installed on the signal lines or power lines.

Common mode noise in a power converter device configured to convert DC power to AC power or to convert AC power to DC power propagates primarily along the path of ground via stray capacitance between the winding and core of a motor that is a load. Furthermore, in an air conditioning device, a common mode noise mainly propagates along a path of the ground via stray capacitances between the winding and the core of the motor of a compressor provided in the air conditioning device. In particular, it is known that when liquefied refrigerant accumulates inside a compressor while an outdoor unit is stopped in the air conditioning device, a stray capacitance between the winding and the core of the motor of the compressor increases due to the accumulation of the liquefied refrigerant, resulting in enlarging results in the propagation of common mode noise.

In order to deal with an increase in common mode noise caused by accumulation of coolant, an electric motor preheating device that has been proposed is configured to determine whether to perform preheat energization processing on an inverter based on an environmental signal such as an outside temperature (e.g , see patent literature 1).

citation list

patent literature

Patent Literature 1: Japanese Unexamined Patent Application Publication No. 11-159467

Summary of the Invention

Technical problem

However, the environmental signal for the electric motor pre-heating device disclosed in Patent Literature 1 does not reflect the state of refrigerant inside a compressor in some cases. In such cases, the amount of heat supplied to the refrigerant within the compressor may be too much or too little, resulting in too much, too little, or heating of the refrigerant within the compressor.

To address the above problem, the present disclosure provides a power conversion device configured to reduce excess or deficiency in the amount of heating or heat supplied to the refrigerant within the compressor.

the solution of the problem

A power converter device according to an embodiment of the present disclosure is configured to supply a motor provided for a compressor with power supplied from a system power supply, and the power converter device includes an inverter connected to the system power supply and the motor an inductor connected to a power line for supplying power from the system power supply to the inverter, an auxiliary winding configured to be magnetically coupled to the inductor, a current detection unit connected to the auxiliary winding and to configured to detect a current flowing through the inductor, and a controller connected to the current detection unit using wiring and configured to control the inverter. The controller includes a determination unit configured to compare a current value detected by the current detection unit with a predetermined threshold value, and a forced energization unit configured to perform heating control on the inverter by causing the inverter energizes a winding of the motor without driving the motor when the determination unit determines that the current value is greater than the predetermined threshold.

Advantageous Effects of the Invention

According to an embodiment of the present disclosure, a current value representing a detected value of a common mode noise is used to determine whether to heat the inside of the compressor, wherein the common mode noise increases in proportion to the amount of refrigerant that accumulates inside a compressor accumulates. Therefore, excess or deficiency in the amount of heat supplied to the refrigerant that accumulates inside the compressor can be avoided.

character list

• [ 1 ] 1 FIG. 14 is a circuit diagram showing an example configuration of a power conversion device according to Embodiment 1. FIG.
• [ 2 ] 2 FIG. 14 is a diagram showing an example configuration of an air conditioning device including the power conversion device disclosed in FIG 1 is shown.
• [ 3 ] 3 shows a circuit diagram showing an example configuration of the inverter used in 1 is shown.
• [ 4 ] 4 12 is a functional block diagram showing an example configuration of the controller used in 1 is shown.
• [ 5 ] 5 FIG. 12 shows an example of a graph in which the current value detected by the current detection unit in FIG 1 is shown is compared to a threshold value.
• [ 6 ] 6 FIG. 12 shows another example of a graph in which the current value detected by the current detection unit shown in FIG 1 is shown is compared to a threshold value.
• [ 7 ] 7 shows a hardware configuration diagram showing an example configuration of the in 4 control shown.
• [ 8th ] 8th shows a hardware configuration diagram showing another example configuration of the in 4 control shown.
• [ 9 ] 9 FIG. 12 is a flowchart showing an operation procedure of the power conversion device according to Embodiment 2. FIG.
• [ 10 ] 10 FIG. 12 is a circuit diagram showing an example configuration of power conversion devices according to Embodiment 2. FIG.
• [ 11 ] 11 FIG. 14 is a flowchart showing operational procedures of the power conversion device according to Embodiment 2. FIG.

Description of Embodiments

Embodiment 1

A power conversion device according to Embodiment 1 will be described. 1 FIG. 12 is a circuit diagram showing an example configuration of the power conversion device according to Embodiment 1. FIG. As in 1 1, a power converter device 10 comprises an inductor 1, a current detection unit 2 configured to detect a zero-phase sequence current flowing through the inductor 1, a rectifier circuit 6, an inverter 7 connected to a system power supply 8 and a load device 5 is to be connected and a controller 3, which is configured to control the converter or inverter 7. In Embodiment 1, the load device 5 is a motor, and the system power supply 8 is an AC power supply.

Three-phase conductor lines or three-phase wires are connected to the converter 7 and the load device 5 . A current sensor 41 is arranged on one of the two lines of the three-phase lines, and a current sensor 42 is arranged on the other of the two lines. The current sensors 41 and 42 are connected to the controller 3 using signal lines. The inductor 1 is connected to a power line for supplying power from the system power supply 8 to the converter 7 . In the example configuration included in 1 As shown, the inductor 1 is connected to a power line between the system power supply 8 and the rectifier circuit 6 . Along with the inductor 1, an auxiliary winding 9 configured to be magnetically coupled to the inductor 1 is arranged.

The current detection unit 2 is connected to the auxiliary winding 9 . Furthermore, the current detection unit 2 is connected to the controller 3 using wires 4 . The current detection unit 2 is configured to output to the controller 3 a current value Ic of a current detected using the auxiliary winding 9 . The current detection unit 2 is a current sensor, for example. The current detection unit 2 may be a current detection circuit including a short circuit and an active circuit, which are not illustrated.

The rectifier circuit 6 is configured to convert an AC power received from the system power supply 8 into a DC power, and to supply the DC power to the inverter 7 . The rectifier circuit 6 includes a rectifier 61, a coil 62, a diode 63, a switching element 64, and a smoothing capacitor 65. FIG. The inverter 7 is configured to follow the control by the controller 3, convert direct current received from the rectifier circuit 6 into alternating current, and energize the load device 5 with the alternating current.

2 FIG. 12 is a diagram showing an example configuration of an air conditioning device including the power conversion device shown in FIG 1 is shown. As in 2 1, an air conditioning apparatus 100 includes an outdoor unit 102 configured to generate a heat source and an indoor unit 103 disposed in a place where the generated heat source is used.

The outdoor unit 102 includes a compressor 21, a four-way valve 22, a heat source side heat exchanger 23, and the power conversion device 10. As shown in FIG. A motor (not shown) of the compressor 21 corresponds to the load device 5 shown in FIG 1 is shown. The indoor unit 103 has an expansion valve 24 , a load-side heat exchanger 25 and a controller 20 . A refrigerant pipe 26 connects the compressor 21, the heat source side heat exchanger 23, the expansion valve 24 and the load side heat exchanger 25, and a refrigerant circuit 27 through which the refrigerant flows is formed.

The compressor 21 is configured to suck and compress refrigerant and then discharge the refrigerant. The compressor 21 is an inverter type compressor, and the capacity of the compressor 21 is variable. The four-way valve 22 is configured to respond as an operation mode to the indoor unit 103 and the flow direction of the refrigerant circulating through the refrigerant circuit 27 . The expansion valve 24 is configured to decompress the refrigerant and allow the refrigerant to expand. Examples of the expansion valve 24 include an electronic expansion valve. The controller 20 is to be connected to each of the four-way valve 22, the power conversion device 10 and the expansion valve 24 using signal lines, not shown. The controller 20 is configured to control a coolant circuit of the coolant circulating through the coolant circuit 27 . Examples of the controller 20 include a microcomputer.

In the example configuration included in 2 1, the controller 20 is in the indoor unit 103. However, the controller 20 may be provided in the outdoor unit 102 or arranged in a place other than the outdoor unit 102 or the indoor unit 103.

3 Fig. 12 is a circuit diagram showing an example configuration of the inverter used in 1 is shown. The converter 7 has six switching elements 71 and six flywheel diodes 72 each connected in parallel to one of the six switching elements 71 . Examples of the switching elements 71 include a power semiconductor device such as an insulated gate bipolar transistor (IGBT). The switching elements 71 can each be a metal oxide semiconductor field effect transistor (MOSFET) or a thyristor. The six switching elements 71 are to be connected to the motor of the compressor 21 and are grouped into two switching elements 71 to be connected to a winding in U-phase, two switching elements 71 to be connected to a winding in V-phase and two switching elements 71 to be connected in one winding in W-phase.

Next, a configuration of the controller 3 shown in 1 is shown, described. 4 12 is a functional block diagram showing an example configuration of the controller used in 1 is shown. The controller 3 includes an inverter control unit 31, a determination unit 32 configured to determine whether refrigerant has accumulated inside the compressor 21 based on the current value Ic, and a forced energization unit 33 configured to operate the inverter 7 to control to generate heat in the motor of the compressor 21 when refrigerant has accumulated inside the compressor 21. A computing device such as a microcomputer executes software, and thereby the various functions of the controller 3 are performed. The controller 3 can also be formed by hardware such as a device having a circuit for implementing the various functions.

The inverter control unit 31 is connected to both ends of the smoothing capacitor 65 by using wires that are not illustrated and are configured to monitor a DC bus voltage appearing between both ends of the smoothing capacitor 65 . The inverter control unit 31 is configured to control the rotation speed of the motor of the compressor 21 in response to a rotation speed command value received from a higher-level device. In Embodiment 1, the higher-level device is the controller 20. The inverter control unit 31 is configured to modulate the pulse width of a pulse voltage output from the inverter 7 by turning on and off the six switching elements 71 based on detected values given by the current sensors 41 and 42 are obtained, and the rotation speed command value. Examples of modulation control include pulse width modulation (PWM) control.

The determination unit 32 is configured to compare the current value Ic detected by the current detection unit 2 with a predetermined threshold value Ith. If the current value Ic is greater than the threshold Ith, the determination unit 32 gives the forced energization unit 33 information indicating that the current value Ic is greater than the threshold Ith.

5 FIG. 12 shows an example of a graph in which the current value detected by the current detection unit shown in FIG 1 is shown, is compared with the threshold value. The vertical axis of 5 represents the current value Ic and the horizontal axis of 5 represents the measurement time. The length of the measurement time is 20 ms. the inside 5 The graph shown represents the current value Ic monitored while the compressor 21 is operating in a normal condition. the inside 5 The graph shown indicates that the current value Ic is 22.6 mA rms and that the current value Ic is smaller than the threshold value Ith in this case.

6 FIG. 12 illustrates another example of a graph in which the current value detected by the current detection unit shown in FIG 1 is shown, is compared with the threshold value. The vertical and horizontal axis in 6 are the same as those in 5 . the inside 6 The graph shown represents the current value Ic observed while refrigerant accumulates inside the compressor 21. FIG. the inside 6 The graph shown indicates that the current value Ic is 69.3 mA rms and that the current value Ic is greater than the threshold Ith in this case.

If the determination unit 32 determines that the current value Ic is larger than the threshold value Ith, the forced energization unit 33 performs heating control on the inverter 7 . When liquefied refrigerant accumulates inside the compressor 21, the heater control is used to vaporize the refrigerant accumulated inside the compressor 21 by heating the motor of the compressor 21. The forced energization unit 33 performs the heater control on the inverter 7 and operates to that the inverter 7 energizes a winding of the motor of the compressor 21 without driving the motor, thereby causing the motor to generate heat. An example of the heater control disclosed in Patent Literature 1, a detailed description of the heater control in Embodiment 1 is omitted. The forced energization unit 33 performs the heating control for a predetermined period of time to avoid overheating the engine.

Part of a sample controller 3 hardware used in 4 shown is described here. 7 is a hardware configuration diagram showing an example configuration of the controller included in 4 is shown. In a case where various functions of the controller 3 are performed using hardware, the controller 3 shown in 4 is formed by a processing circuit 80 shown in FIG 7 is shown. Functions provided by the converter control unit 31, the determination unit 32, and the forced energization unit 33 described in FIG 4 are implemented using the processing circuitry 80. FIG.

In the case where various functions are performed using hardware, the processing circuitry 80 corresponds, for example, to a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an application specific integrated circuit (ASIC), a field programmable gate array (FPGA ), or a combination thereof. The functions provided by the converter control unit 31, the determination unit 32 and the forced energization unit 33 can be implemented individually by using the processing circuit 80. Alternatively, the functions provided by the converter control unit 31, the determination unit 32 and the forced energization unit 33 can all be implemented by using the Processing circuit 80 may be implemented.

Another part of an example hardware of the controller 3, which is in 4 shown will be described. 8th shows a hardware configuration diagram showing another sample configuration of the controller included in 4 is shown. In a case where various functions of the controller 3 are executed using software, the controller 3 shown in 4 is formed by a processor 81 and a memory 82, as in FIG 8th shown. Functions provided by the converter control unit 31 , the determination unit 32 and the forced energization unit 33 are implemented by using the processor 81 and the memory 82 . the 8th Figure 12 illustrates processor 81 and memory 82 communicatively coupled to each other.

In a case where various functions are executed using software, functions provided by the converter control unit 31, the determination unit 32, and the forced energization unit 33 are implemented using software, firmware, or a combination of software and firmware. The software and firmware are described as programs and stored in memory 82 . The processor 81 provides functions of each unit by reading and executing the programs stored in the memory 82. The memory 82 stores the threshold value Ith.

A non-volatile semiconductor memory is used as the memory 82 . Examples of such non-volatile semiconductor memory include read only memory (ROM), flash memory, erasable and programmable ROM (EPROM), and electrically erasable and programmable ROM (EEPROM). In addition, a volatile semiconductor memory such as a random access memory (RAM) can be used as the memory 82 . Furthermore, a detachable recording medium can be used as the memory 82 . Examples of such a detachable recording medium include a magnetic disk, a flexible disk, an optical disk, a compact disk (CD), a mini disk (MD), and a digital versatile disk (DVD).

Next, an operation of the power conversion device 10 according to Embodiment 1 will be described. 9 FIG. 14 is a flowchart showing an operation procedure of the power conversion device according to Embodiment 1. FIG. The controller 3 is configured to 9 to follow the process shown and to carry out the processing at regular or regular intervals.

The current detection unit 2 detects a current flowing through the inductor 1 and outputs the detected current value Ic to the controller 3 . In response to the current value Ic input to the controller 3 (step S101), the determination unit 32 compares the current value Ic with the threshold value Ith (step S102). If it is determined that the current value Ic is larger than the threshold value Ith, the determination unit 32 outputs to the forced energization unit 33 information indicating that the current value Ic is larger than the threshold value Ith.

If the determination unit 32 determines that the current value Ic is larger than the threshold value Ith, the forced energization unit 33 performs the heating control on the inverter 7 (step S103). Although the motor of the compressor 21 is not running at this time, power is supplied to the semiconductor elements such as the switching elements 71 in the inverter 7 because of the operation of the inverter 7 and heat is generated due to energy losses in the motor of the compressor 21 generated. The heat generated due to of the energy losses heats the coolant that has accumulated inside the engine.

After the forced energization unit 33 performs the heating control of the inverter 7 in step S103, the determination unit 32 returns to step S101. Then, the determination unit 32 compares the current value Ic inputted from the current detection unit 2 with the threshold value Ith to determine whether the heater control has provided excessive or insufficient heat to the refrigerant inside the compressor 21 (step S102). If it is determined that the current value Ic is less than or equal to the threshold value Ith, the determination unit 32 ends the processing.

The description in Embodiment 1 was given with respect to a case where the system power supply 8 is an AC power supply, but the system power supply 8 may be an AC power supply. In such a case, the rectifier circuit 6 in the example configuration shown in 1 is shown can be omitted. Additionally provides 1 12 illustrates a case where the system power supply 8 supplies AC power by using three-phase three-wires, but the system power supply 8 may supply AC power by using single-phase wires or three-phase four-wires.

Furthermore, the description in Embodiment 1 has been given with respect to a case where the inductor 1 is connected to the power line between the system power supply 8 and the rectifier circuit 6, but where the inductor 1 is connected to the power line between the system power supply 8 and the load device 5 is not limited to any particular position. For example, the inductor 1 can be connected between the rectifier circuit 6 and the converter 7 or between the converter 7 and the load device 5 . Furthermore, the controller 20 can have the function of the controller 3 .

The power conversion device 10 according to Embodiment 1 includes the inductor 1, the auxiliary winding 9 configured to be magnetically connected to the inductor 1, the current detection unit 2, the converter 7 to be connected to the system power supply 8, and the motor and the controller 3 is configured to control the converter 7 . The inductor 1 is connected to the power line for supplying power from the system power supply 8 to the converter 7 . The current detection unit 2 is configured to output to the controller 3 using the wiring 4 the current value Ic detected using the auxiliary winding 9 . The determination unit 32 is configured to compare the current value Ic detected by the current detection unit 2 with the threshold value Ith. If the determination unit 32 determines that the current value Ic is larger than the threshold value Ith, the forced energization unit 33 performs the heating control on the inverter 7 by causing the inverter 7 to energize the winding of the motor without driving the motor.

According to Embodiment 1, when the current value Ic representing a detected value of the common mode noise is used to determine whether to heat the inside of the compressor 21, the common mode noise increases in proportion to the amount of refrigerant inside the compressor 21 accumulates. Therefore, excess or deficiency in the amount of heat supplied to the refrigerant that accumulates inside the compressor 21 can be avoided.

Embodiment 2

An air conditioning device according to Embodiment 2 has plural combinations provided with the inductor 1, the current detection unit 2, and the inverter 7, and the number of combinations corresponds to the number of load devices 5 included in 1 are shown. The same components shown in embodiment 1 are denoted by the same reference numerals in embodiment 2 and will not be described in detail. In Embodiment 2, a part that is different from the configuration described in Embodiment 1 will be described in detail, and a similar part of the configuration will not be described.

A configuration of the power conversion devices included in the air conditioning device according to Embodiment 2 will be described. 10 FIG. 12 is a circuit diagram showing an example configuration of the power conversion devices according to Embodiment 2. FIG.

An air conditioning device 100 according to Embodiment 2 has two compressors 21 in FIG 2 shown configuration and has power converter devices 10a and 10b, each corresponding to one of the two compressors 21, as shown in FIG 1 shown, correspond. The motor of one of the two compressors 21 corresponds to a load device 5a, and the motor of the other of the two compressors 21 corresponds to a load device 5b. Each of the power conversion devices 10a and 10b has a configuration similarly to the configuration of the power converter device 10 described in Embodiment 1, and detailed description regarding the power converter devices 10a and 10b is omitted.

As in 10 As shown, the controllers 3a and 3b are connected to each other using a signal line 19. In Embodiment 2, at least one of two of the controllers 3a and 3b included in 10 are shown, having the determination unit 32, which is shown in 4 is shown, and the other of the controllers 3a and 3b may not have the determination unit 32 shown in FIG 4 is shown. In the following description, it is assumed that the controller 3a has the determination unit 32 and that the controller 3b does not have the determination unit 32 .

A current detection unit 2a is configured to detect a current flowing through an inductor 1a and to output a detected current value Ic1 to the controller 3a by using a wire 4a. The current detection unit 2b is configured to detect a current flowing through an inductor 1b and output a detected current value Ic2 to the controller 3b by using a wire 4b. The controller 3b is configured to transmit the current value Ic2 received from the current detection unit 2b to the controller 3a. The determination unit 32 in the controller 3a is configured to compare each of these current values Ic1 and Ic2 with the threshold value Ith. If the current value Ic2 is larger than the threshold value Ith, the determination unit 32 transmits to the controller 3b information indicating that the current value Ic2 is larger than the threshold value Ith. In response to the information indicating that the current value Ic2 is larger than the threshold value Ith received from the controller 3a, the forced energization unit 33 of the controller 3b performs the heating control on an inverter 7b.

A description is given here with respect to an example of control performed when the current values Ic1 and Ic2 are larger than the threshold value Ith and the current value Ic1 is not equal to the current value Ic2. When heating control is performed on an inverter 7a, the forced current supply unit 33 in the controller 3a causes the inverter 7a to output power proportional to the current value Ic1. When heating control is performed on the inverter 7b, the forced energization unit 33 in the controller 3b causes the inverter 7b to output power proportional to the current value Ic2. This control is effective in a case where power to be consumed for performing the heating control on the inverters 7a and 7b is restricted. In summary, the forced energization unit 33 in the controller 3a is configured to perform heating control on the inverter 7a, and the forced energization unit 33 in the controller 3b is configured to perform heating control on the inverter 7b in such a manner that a predetermined limit for the power is not exceeded.

A description is given here regarding another example of control performed when the current values Ic1 and Ic2 are larger than the threshold value Ith. The forced energization unit 33 in the controller 3a and the forced energization unit 33 in the controller 3b communicate with each other so as not to perform heating control on the inverters 7a and 7b at the same time. For example, after the forced energization unit 33 in the controller 3a performs the heating control in the inverter 7a, the forced energization unit 33 in the controller 3b performs the heating control on the inverter 7b. In this case, a temporary increase in performance in the air conditioning device 100 can be avoided.

Next, an operation of the power converter devices 10a and 10b according to Embodiment 2 will be described. 11 FIG. 12 is a flowchart showing operational procedures of the power converter devices according to Embodiment 2. FIG. Controllers 3a and 3b are configured to 11 to follow the flow shown and from processing at regular intervals.

In response to the current value Ic1 input to the controller 3a from the current detection unit 2a (step S201), the determination unit 32 compares the current value Ic1 with the threshold value Ith (step S202). If it is determined that the current value Ic1 is less than or equal to the threshold value Ith, the current value Ic2 is input to the determination unit 32 from the controller 3b (step S203). The determination unit 32 compares the current value Ic2 with the threshold value Ith (step S204). If it is determined that the current value Ic2 is greater than the threshold Ith, the determination unit 32 transmits to the controller 3b information indicating that the current value Ic2 is greater than the threshold Ith. In response to the information indicating that the current value Ic2 is larger than the threshold value Ith received from the controller 3a, the forced energization unit 33 in the controller 3b performs the heating control on the inverter 7b (step S205).

Although the motor connected to the inverter 7b is not running at this time, power is supplied to the semiconductor elements such as the switching elements 71 in the inverter 7b because of the operation of the inverter 7b, and heat is generated due to the energy losses of the motor of the compressor 21. The heat generated due to the energy losses heats the refrigerant that has accumulated inside the motor. If it is determined in step S204 that the current value Ic2 is less than or equal to the threshold value Ith, the determination unit 32 ends the processing.

In contrast, if it is determined in step S202 that the current value Ic1 is larger than the threshold value Ith, the current value Ic2 is input to the determination unit 32 from the controller 3b (step S206). The determination unit 32 compares the current value Ic2 with the threshold value Ith (step S207). If it is determined that the current value Ic2 is less than or equal to the threshold Ith, the determination unit 32 outputs information indicating that the current value Ic1 is greater than the threshold Ith to the forced energization unit 33 in the controller 3a.

In response to the information indicating that the current value Ic1 is larger than the threshold value Ith specified by the determination unit 32, the forced energization unit 33 performs the heating control on the inverter 7a (step S208). Although the motor connected to the converter 7a is not running at this time, power is supplied to the semiconductor elements such as the switching elements 71 in the converter 7a due to the operation of the converter 7a, and heat is generated due to the energy losses in the motor of the compressor 21. The heat generated due to the energy losses heats the refrigerant that has accumulated inside the motor.

If it is determined in step S207 that the current value Ic2 is larger than the threshold value Ith, the determination unit 32 compares the current value Ic1 with the current value Ic2 (step S209). If the current value Ic1 is not equal to the current value Ic2, the forced energization unit 33 in the controller 3a performs heating control by causing the inverter 7a to output power proportional to the current value Ic1. In addition, the determination unit 32 transmits to the controller 3b information related to the current value Ic2 and information indicating that the current value Ic2 is larger than the threshold value Ith. In response to the information regarding the current value Ic2 and the information indicating that the current value Ic2 is larger than the threshold value Ith received from the controller 3a, the forced energization unit 33 in the controller 3b performs heating control by causing the inverter 7b to output power proportional to the current value Ic2. In this way, heating control is performed on the inverters 7a and 7b (step S210).

In step S210, which occurs in 11 1, the refrigerant in each of the compressors 21 is heated in proportion to the current value Ic indicating a detected value of common mode noise that increases in proportion to the amount of refrigerant that has accumulated. Therefore, an excess or deficiency in the amount of heat supplied to the refrigerant, which accumulates inside the compressor 21, will be avoided. After steps S205, S208 and S210, the determination unit 32 returns to step S201.

Similar to the system power supply 8 in Embodiment 1, the system power supply 8 in Embodiment 2 is not limited to an AC power supply and may be an AC power supply. In addition, the AC power provided by the system power supply 8 is not limited to the one provided using three-phase three-wires, but the system power supply 8 may provide AC power using a single-phase wire or three-phase four-wires. Furthermore, the position where the inductor 1a is connected to the power line between the system power supply 8 and the load device 5a is not limited to that in FIG 10 shown position and the position where the inductor 1b is connected to the power line between the system power supply 8 and the load device 5b is also not limited to that in FIG 10 shown position limited.

In Embodiment 2, one of the controllers 3a and 3b can be configured to control both the inverters 7a and 7b. The controller 20 that is in 2 shown may have the functions of controls 3a and 3b.

In Embodiment 2, a description was given with respect to the case where there are two load devices 5, reference being made to load devices 5a and 5b, but the number of load devices is not limited to two and may be three or more. The air conditioning device 100 according to Embodiment 2 may have a plurality of combinations each including the inductor 1, the current detection unit 2, and the inverter 7 shown in FIG 1 are shown, and the number of combinations corresponds to the number of load devices 5. In this case, is the determination unit 32 is configured to determine whether two or more of the plurality of current detection units 2 detect a current value Ic that is greater than the threshold value Ith, the current value Ic being received from each of the plurality of current detection units 2. If it is determined that two or When more of the plurality of current detection units 2 detect the current value Ic larger than the threshold value Ith, the forced energization unit 33 performs heating control on two or more of the inverters 7 provided in the combinations each containing one or one of the two or more of the have a plurality of current detection units 2 .

When the heating control is performed, the forced current supply unit 33 can cause each of the two or more of the inverters 7 to output power in proportion to the current value Ic detected by the current detection unit 2 present in the combination including the inverter 7 . In this case, two or more compressors 21 can be warmed up or heated, so that a predetermined limit for the power is not exceeded. When heating control is performed on two or more of the inverters 7, the forced energization unit 33 can sequentially perform the heating control on the two or more of the inverters 7 one by one. In this case, a temporary increase in power consumption of the air conditioning device 100 can be avoided.

In each of the power conversion devices 10a and 10b according to Embodiment 2, the combination of the inductor 1, the current detection unit 2 and the converter 7 is arranged. The determination unit 32 is configured to determine whether two or more of the plurality of current detection units 2 detect the current value Ic that is larger than the threshold value Ith, the current value from each of the plurality of current detection units 2 being received. If it is determined that two or more of the plurality of current detection units 2 detect the current value Ic larger than the threshold value Ith, the forced energization unit 33 performs heating control on two or more of the inverters 7 present in the combinations each one having two or more of the plurality of current detection units 2 .

According to Embodiment 2, even in a case where there are multiple compressors 21, the current value Ic representing a detected value of common mode noise is used to determine whether to heat the inside of each compressor 21, where the common mode noise increases in proportion to the amount of refrigerant accumulated inside the compressor 21 . Therefore, excess or deficiency in the amount of heat supplied to the refrigerant accumulated inside each of the plurality of compressors 21 can be avoided.

Furthermore, in Embodiment 2, in a case where the power to be consumed for heating control is limited in the air conditioning device 100 having the multiple inverters 7, the power to each of the multiple inverters 7 is distributed based on the accumulation of Refrigerant distributed within the compressor 21, which is connected to the converter 7. Therefore, damage to each compressor 21 due to accumulation of refrigerant individually can be avoided.

Reference List

1, 1a, 1b

inductor,

2, 2a, 2b

current detection unit,

3, 3a, 3b

Steering,

4, 4a, 4b

Wiring,

5, 5a, 5b

load device,

6, 6a, 6b

rectifier circuit,

7, 7a, 7b

converter,

8th

system power supply,

9, 9a, 9b

auxiliary winding,

10, 10a, 10b

power converter device,

19

signal line,

20

Steering,

21

Compressor,

22

four-way valve,

23

brine side heat exchanger,

24

expansion valve,

25

load side heat exchanger,

26

coolant pipe,

27

coolant circuit,

31

converter control unit,

32

destination unit,

33

forced current unit,

41, 41a, 41b

current sensor,

42, 42a, 42b

current sensor,

61, 61a, 61b

rectifier,

62.62a, 62b

Kitchen sink,

63, 63a, 63b

Diode,

64, 64a, 64b

switching element,

65, 65a, 65b

smoothing capacitor,

71

switching element,

72

freewheeling diode,

80

processing circuit,

81

Processor,

82

Storage,

100

air conditioning device,

102

outdoor unit,

103

indoor unit

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• JP 11159467 [0008]

Claims (5)

A power converter device configured to power a motor provided for a compressor with power supplied from a system power supply, the power converter device comprising: an inverter to be connected to the system power supply and the motor; an inductor connected to a power line for supplying power from the system power supply to the inverter; an auxiliary winding configured to be magnetically coupled to the inductor; a current detection unit connected to the auxiliary winding and configured to detect a current flowing through the inductor; and a controller connected to the current detection unit using wiring and configured to control the inverter, wherein the controller comprises a determination unit configured to compare a current value detected by the current detection unit with a predetermined threshold value, and a forced energization unit configured to perform heating control on the inverter to cause the inverter to energize a winding of the motor without driving the motor when the determination unit determines that the current value is greater than the predetermined threshold. power converter device claim 1 , wherein the power converter device has a plurality of combinations each having the inductor, the current detection unit and the converter, wherein the determination unit is configured to determine whether two or more of the plurality of current detection units detect a current value that is greater than the predetermined threshold value, wherein the current value is received from each of the plurality of current detection units, and the forced energization unit is configured to, when the determination unit determines that two or more of the plurality of current detection units detect a current value that is greater than the predetermined threshold value, performing the heating control on two or more of the inverters each being the inverter present in combinations each including one of the two or more of the plurality of current detection units. power converter device claim 2 , wherein the forced current supply unit is configured to, when the heating control is performed on the two or more of the converters each being the converter, causing the converter to output power proportional to the current value detected by the current detection unit present in a combination is, which has the converter. power converter device claim 2 , wherein the forced energization unit is configured to, when the heating control is performed on the two or more of the converters each being the converter, sequentially performing the heating control on the two or more of the converters each being the converter one after the other. Power converter device according to one of Claims 1 until 4 , further comprising: one or more rectifier circuits, each configured for, in a case where the system power supply is an AC power supply, converting AC power received from that of the system power supply into DC power and supplying the DC power to a respective one or more converters, wherein one or more inductors are each connected to the power line between the system power supply and a respective one of the one or more rectifier circuits.

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