JP2023064504A - Inverter device and blow device - Google Patents

Abstract

To stop a load (e.g., a heater) without outputting a failure signal.SOLUTION: An inverter device (1) comprises: a power module (5) in which, when any one of an upper arm drive part (5H) and a lower arm drive part (5L) is defined as a first drive part, and the other is defined as a second drive part, the first drive part and the second drive part are connected with a first load (121), and that has a function of outputting a failure signal from the second drive part in a case where an input control power supply voltage is reduced to be lower than an allowable value; a first DC cable way (L1) for feeding power to the first drive part from a DC power supply (7) via a switch (10); and a second DC cable way (L2) for feeding power to the second drive part from the DC power supply (7).SELECTED DRAWING: Figure 1

Description

The present disclosure relates to an inverter device and a blower device using the same.

Air conditioners to which a blower having a function of ventilation or humidification is added have been provided (see, for example, Patent Document 1). At the time of heating, fresh outdoor air can be taken in together with moisture, and the air heated to an appropriate temperature by a heater can be introduced into the room. Humidification units for overseas use an IPM (intelligent power module) to operate the heater in order to comply with harmonic regulations. The operation of the heater for warming the air requires air blowing, and when air is not being blown for some reason, it is necessary to stop the operation of the heater as well.

The simplest and surest way to implement an interlock that does not operate the heater when the air is not blown is to not apply the control power supply voltage to the IPM when the air is not blown.

JP 2012-107799 A

For example, suppose that when the air conditioner is started, a blower for ventilation or humidification is also started. In this case, (1) when the fan in the blower is not rotating, (2) the control power supply voltage of the IPM is set to 0V, thereby preventing the operation of the heater. However, (3) the IPM whose control power supply voltage has become 0V issues a Fo (False out) signal to the functional microcomputer, which is the control unit of the IPM, by the built-in low voltage detection function. Upon receiving the Fo signal, the functional microcomputer informs the basic microcomputer, which is the central control unit of the air conditioner. (4) The basic microcomputer stops the blower.

(5) After that, the blower cannot be operated because the abnormality continues to occur. (6) Therefore, the user once turns off the power of the air conditioner and restarts it. However, even if it is restarted, it returns to the above state (1), and the blower cannot be operated.

It is therefore an object of the present disclosure to stop a load (eg, heater) without signaling a failure.

(1) In the inverter device of the present disclosure, one of the upper arm drive section and the lower arm drive section is the first drive section and the other is the second drive section, and the first drive section and the second drive section is connected to a first load, and a power module having a function of outputting a failure signal from the second drive unit when the input control power supply voltage falls below an allowable value; A first DC electric circuit for supplying power to the drive section and a second DC electric circuit for supplying power from the DC power supply to the second drive section are provided.

In the inverter device configured in this way, the first load can be stopped without outputting a failure signal. If the temporary drive condition inadequacy state is resolved, a quick restart is possible. A power module is, for example, a packaged device called an IPM, but a circuit configured by using individual circuit elements with functions equivalent to those of an IPM also corresponds to a power module. .

(2) In the inverter device of (1) above, the switch may be opened when a signal to stop the second load, which is the condition for driving the first load, is received.
In this case, the switch is opened and the power supply to the first driving section is stopped. When the power supply is stopped, the gate voltage cannot be maintained and the switching element of the first driving section is turned off.

(3) The inverter device of (2) above includes a control unit that controls the power module and the second load, and when the failure signal is input to the control unit, the control unit causes the power module to stop the first load and the second load through
When a failure signal is issued, both the first load and the second load are stopped under the control of the control unit via the power module.

(4) The inverter device of (2) or (3) further includes an interlock circuit that controls opening and closing of the switch based on the operating state of the fan, which is the second load, wherein the interlock circuit When the number of rotations of the two loads is less than the predetermined number of rotations, the switch is opened.
As a result, an interlock is established in which the operation of the first load is conditioned by the number of revolutions of the second load being equal to or greater than a predetermined number of revolutions.

(5) The blower includes the inverter device according to (3) or (4), a heater as the first load, and a humidification fan or ventilation fan as the second load. .

It is a figure which shows an example of the external appearance of an air conditioner. It is a functional schematic diagram of an air conditioner. 3 is a circuit diagram of an inverter device that drives a fan of the blower; FIG. FIG. 5 is an example of a flowchart relating to the operation of the blower, where circled A, B, and C in FIG. 4 are connected to circled A, B, and C in FIG. 5, respectively. FIG. 5 is an example of a flowchart relating to the operation of the blower, where circled A, B, and C in FIG. 5 are connected to circled A, B, and C in FIG. 4, respectively.

An embodiment of the present disclosure will be described below with reference to the drawings.

<<External configuration of the air conditioner>>
FIG. 1 is a diagram showing an example of the appearance of an air conditioner 100. As shown in FIG. The air conditioner 100 includes an outdoor unit 101 and an indoor unit 102 . A housing 101c of the outdoor unit 101 is composed of a main body unit 101a containing a refrigerant circuit and a blower (ventilation/humidification unit) 101b provided on the top. The outdoor unit 101 and the indoor unit 102 are connected to each other via refrigerant pipes 103 and air pipes 104 .

<<Functional diagram of air conditioner>>
FIG. 2 is a functional schematic diagram of the air conditioner 100. As shown in FIG. A main unit 101a of the outdoor unit 101 includes a filter 106, an expansion valve 107, a heat exchanger 108, a four-way switching valve 109, a compressor 110, an accumulator 111, and a gas shutoff valve 112 in order from the liquid shutoff valve 105. It constitutes a known refrigerant circuit connected as shown. The heat exchanger 108 is provided with a fan 113 for passing air.

The indoor unit 102 includes a heat exchanger 113, an expansion valve 114, and a fan 115, which are connected as shown. The outdoor unit 101 and the indoor unit 102 are interconnected by a liquid refrigerant pipe 103L and a gas refrigerant pipe 103G.

The air blower 101b includes a fan 120 for air intake and exhaust, a heater 121, a humidification rotor 122, and an air blower 123 for adsorption. The air blower 101b can discharge the indoor air taken into the indoor unit 102 to the outside, and also can add moisture to fresh outdoor air and send it indoors. Also, in winter, the air warmed by the heater can be taken into the room. Air blower 101 b is connected to indoor unit 102 via air pipe 104 .

《Inverter device for air blower》
FIG. 3 is a circuit diagram of the inverter device 1 that drives the fan 120 and the heater 121 of the blower device 101b. The main circuit portion of the inverter device 1 is configured by connecting a full-bridge rectifier circuit 3 connected to an AC power supply 2, a smoothing capacitor 4, and an IPM 5 as shown. The AC voltage of the AC power supply 2 is full-wave rectified by the rectifier circuit 3 and smoothed by the smoothing capacitor 4 to provide the DC voltage to the DC electric circuit 6 . A DC voltage is supplied to the IPM5. The illustrated rectifier circuit 3 (AC/DC converter) is merely an example, and an AC/DC converter having another circuit configuration may be used. Also, the IPM 5 can be a packaged one, but instead of this, a "power module" is used as a non-packaged inverter circuit portion that uses individual circuit elements to perform functions equivalent to those of the IPM. There may be.

The IPM 5 includes an upper arm (high side) driving portion 5H and a lower arm (low side) driving portion 5L. The drive unit 5H for the upper arm includes switching elements Qu, Qv, and Qw, and an HVIC 51 that is a gate drive circuit for the upper arm. The lower arm driving section 5L includes switching elements Qx, Qy, Qz, and an LVIC 52 that is a gate driving circuit for the lower arm. A diode is connected in anti-parallel to each switching element. Each switching element is, for example, an IGBT (Insulated Gate Bipolar Transistor), but may be a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor).

The switching element Qu and the switching element Qx are located between two lines of the DC electric circuit 6 and connected in series with each other. The switching element Qv and the switching element Qy are located between two lines of the DC electric circuit 6 and connected in series with each other. The switching element Qw and the switching element Qz are located between two lines of the DC electric circuit 6 and connected in series with each other.

The gate and emitter of each of the switching elements Qu, Qv, and Qw are connected to the HVIC 51, but only the gate connections of the switching elements Qu and Qw involved in driving the heater 121 are shown here, and the others are omitted. ing. Similarly, the gate and emitter of each of the switching elements Qx, Qy, and Qz are connected to the LVIC 52, but only the gate connections of the switching elements Qx and Qz involved in driving the heater 121 are shown here. are omitted. Boot capacitors 53 and 54 are connected to the HVIC 51 . The boot capacitors 53 and 54 form a bootstrap circuit for applying gate voltages higher than the emitter voltages to the switching elements Qu and Qw.

The heater 121 is connected between an interconnection point Pux between the switching elements Qu and the switching elements Qx and an interconnection point Pwz between the switching elements Qw and Qz. Current flows through the heater 121 when both the switching elements Qu and Qz are on and when both the switching elements Qw and Qx are on. The IPM 5 can convert the DC voltage of the DC electric circuit 6 into a three-phase AC voltage, but since the load is the heater 121, the heater 121 is actually supplied with two-phase AC power. The switching element Qv and the switching element Qy are not involved in driving the heater 121 (always off).

However, the connection of the heater 121 is not limited to the illustrated connection. Any two of the three phases may be used. If the heater is star-connected like a three-phase motor winding, all three phases may be used.

Gate drive of the IPM 5 requires a control power supply voltage in addition to the gate control signal. The electrical paths to which the control power supply voltage is applied include an electrical path VN1 (also referred to as voltage VN1) and an electrical path VP1 (also referred to as voltage VP1). A voltage that is the source of the control power supply voltage is supplied from a DC power supply 7 including a switching power supply and a regulator. The DC power supply 7 generates a stable DC voltage VN<b>1 (eg, 15 V) from the AC voltage of the AC power supply 2 . It should be noted that the numerical values of the voltage or the number of revolutions described in the present disclosure are merely illustrative examples, and are not limited to the illustrated numerical values.

An electric line VN1 is a primary side electric line directly connected to the DC power supply 7, and a capacitor 8 is provided between it and GND. The electric circuit VP1 is a secondary electric circuit in which the switch 10 is interposed between the electric circuit VN1 and a capacitor 9 is provided between the electric circuit VP1 and GND. The voltage of electric line VN1 is always 15V as long as DC power supply 7 outputs 15V. The voltage of the electrical path VP1 is, for example, 0.8 V when the switch 10 is open and 15 V when the switch 10 is closed. As the switch 10, for example, a P-channel Metal-Oxide-Semiconductor Field Effect Transistor (P-MOSFET) can be used, but other elements having equivalent functions may be used.

The HVIC 51 is supplied with the control power supply voltage from the first DC electric line L1 connected to the electric line VP1. The LVIC 52 is supplied with the control power supply voltage from the second DC line L2 connected to the line VN1.

As control circuit elements, a control section (functional microcomputer) 11, a fan driving circuit 12, and an interlock circuit 13 are provided. The control unit 11 is a microcomputer or a device having equivalent functions, and gives gate signals to the HVIC 51 and the LVIC 52 . A fan drive circuit 12 for driving the fan 120 receives an instruction of the rotation speed of the fan 120 from the control unit 11 , detects the actual rotation speed, and sends a rotation speed detection signal to the control unit 11 and the interlock circuit 13 .

The interlock circuit 13 opens the switch 10 when the fan speed is less than a predetermined value, and closes the switch 10 when the fan speed is greater than or equal to the predetermined value. The control unit 11 can communicate with the central control unit (basic microcomputer) of the air conditioner 100 . Although the interlock circuit 13 is an external circuit of the control section 11 in this circuit example, it may be provided by software as an internal function of the control section 11 .

Both HVIC 51 and LVIC 52 incorporate a low voltage detection function. The HVIC 51 stops the operations of the switching elements Qu and Qw when the voltage VP1 is lower than the allowable lower limit. LVIC 52 stops the operation of switching elements Qx and Qz when voltage VN1 is lower than the allowable lower limit. Also, the LVIC 52 sends a Fo signal (failure signal) to the POE port of the controller 11, for example, when the voltage VN1 is lower than the allowable lower limit. The Fo signal is also output from the LVIC 52 for overcurrent detection and overheat detection (temperature protection) in the lower arm.

When the POE port becomes L (Low) level by the Fo signal, the gate signal from the control section 11 is forcibly cut off. It should be noted that the input of the Fo signal is not limited to the POE port, and may be another general-purpose input port. When the Fo signal is input to the general-purpose input port, the control unit 11 switches the gate signal from H (High) level to L level by software processing. There is some delay time due to the intervention of software processing.

Upon receiving the Fo signal, the control unit 11 (functional microcomputer) stops the IPM 5 and the fan drive circuit 12 and also transmits the abnormality to the control unit (basic microcomputer) of the air conditioner 100 . After receiving the Fo signal from the IPM 5, the functional microcomputer waits for the Fo signal to be canceled without resetting, and can resume operation when the abnormality is resolved. The basic microcomputer can perform its own basic operation (air conditioning) even when the functional microcomputer is receiving the Fo signal. Therefore, even if the secondary function of the functional microcomputer cannot be used, the main function of the basic microcomputer can be used.

Although the Fo signal is generally output from the LVIC 52, it may be output from the HVIC 51 as well.

《Operation of the blower》
4 and 5 are examples of flowcharts relating to the operation of the blower 101b. Circled A, B, and C in FIG. 4 are connected to circled A, B, and C in FIG. 5, respectively. It is the control unit 11, the fan drive circuit 12, and the interlock circuit 13 that can execute the flow chart.

First, in step S1, the control unit 11 determines whether or not there is an abnormality in the entire system managed by itself (step S1). If there is no abnormality or the abnormality disappears, the state of the fan 120 is changed from stopped to operating (step S2). Next, wait for the rotation speed of the fan 120 to rise to the command rotation speed (steps S3 and S4), and when the rotation speed N exceeds A (for example, 300) [rpm], turn the switch 10 from off (open) to on ( closed) (step S5). As a result, D (for example, 15 V±10%) [V] is applied to the HVIC 51 as the voltage VP1 (step S6). It should be noted that the fan drive circuit 12 and the interlock circuit 13 are the main actors of steps S3, S4, and S5.

LVIC 52 is already supplied with voltage VN1. Next, the controller 11 waits for the rotational speed of the fan 120 to reach the commanded rotational speed B (eg, 1000 rpm) (steps S7 and S8), and charges the boot capacitors 53 and 54 (step S9). Further, the control unit 11 transmits gate signals to the switching elements Qx and Qz (step S9).

Next, in FIG. 5, the controller 11 supplies gate signals to the switching elements Qu, Qw, Qx, and Qz to drive the heater 121 (step S10). Note that the fan driving circuit 12 and the interlock circuit 13 execute steps S13, S14, S15, S16, and S17 in FIG. 5 described below.

In step S11, the POE port (FIG. 3) of the control unit 11 does not become L level ("NO" in step S11), and the rotation speed N of the fan does not fall below A [rpm] ("NO" in step S15). ), the controller 11 continues to drive the heater 121 . If the POE port is not at L level but the rotation speed N of the fan 120 is lower than A [rpm], the rotation speed of the fan 120 is insufficient while the heater 121 is in operation, indicating that the heater 121 should be stopped.

Therefore, the interlock circuit 13 outputs a stop signal for the heater 121 by switching the switch 10 from on to off (step S16). After that, when the voltage VP1 becomes lower than C (eg, 10) [V] (step S17), the HVIC 51 stops the gate signal (step S18). As a result, the heater 121 is stopped. After that, if the fan 120 returns to a normal state (step S19), the controller 11 returns to step S3 (FIG. 4). As a result, steps S3 to S10 are executed again, and the heater 121 is driven.

Due to the presence of steps S15 to S19, the heater 121 is temporarily stopped to return the fan 120 to a normal state without causing the LVIC 52 to issue the Fo signal even when the number of rotations of the fan 120 is insufficient while the heater is being driven. You can give them the chance to come back. Thus, the operation of the fan 120 and the heater 121 can be resumed.

On the other hand, when the LVIC 52 detects the low voltage and issues the Fo signal, the POE port becomes L level ("YES" in step S11). When the POE port becomes L level, the control unit 11 stops the gate signal (step S12) and stops driving the heater 121. FIG. After that, the fan 120 continues to stop until the number of rotations N of the fan 120 becomes smaller than A [rpm] (steps S12 and S13). When the rotation speed N of the fan 120 becomes smaller than A [rpm], the interlock circuit 13 switches the switch 10 from on to off (step S), and returns to step S1 (FIG. 4).

《Summary of Disclosure》
The above disclosure can be generalized and expressed as follows. For example, one of the drive unit 5H of the upper arm and the drive unit 5L of the lower arm is set as the first drive unit, the other is set as the second drive unit, and the heater 121 is set as the first load. The inverter device 1 has a first drive section and a second drive section connected to a first load, and has a function of outputting a failure signal from the second drive section when the input control power supply voltage drops below an allowable value. A module (IPM 5), a first DC electric line L1 that feeds power from the DC power supply 7 to the first driving section via the switch 10, and a second DC electric line L2 that feeds power from the DC power supply 7 to the second driving section. there is

In the inverter device 1 configured as described above, for example, when it is desired to stop driving the first load, the switch 10 of the first DC electric circuit is opened to cut off the supply of the control power supply voltage to the first driving section. As for the power supply of the control power supply voltage from the two DC electric lines to the second drive unit, it is possible to carry out a power supply form in which this is continued. As a result, the first load stops, but no failure signal is output from the second drive section of the power module (IPM5). Therefore, for example, even if the driving condition of the first load is temporarily insufficient, it is possible not to issue a failure signal. Thus, the first load can be stopped without issuing a fault signal. In this case, if the temporary inadequate drive condition is resolved, a quick restart is possible.

The switch 10 is opened when the inverter device 1 receives a stop signal for the second load (fan 120), which is the drive condition for the first load. In this case, the switch 10 is opened, the power supply to the first driving section is stopped, and the gate signal is also stopped. It should be noted that the power supply to the second driving section can be maintained as long as the failure signal is not issued.

The inverter device 1 includes a control unit 11 that controls the power module (IPM 5) and the second load (fan 120). Stop the first load and the second load.
When the failure signal is issued, both the first load and the second load are stopped under the control of the control section 11 via the power module.

The interlock circuit 13 of the inverter device 1 opens the switch 10 based on the operating state of the fan 120, which is the second load. By opening the switch 10, the control power supply voltage (voltage VP1) is lowered to stop the drive unit 5H and the heater 121 can be stopped. In this case, since no failure signal is issued, the heater 121 can be restarted by closing the switch 10 .

The blower device 101b includes the inverter device 1 as described above, the heater 121 as the first load, and the fan (humidification fan or ventilation fan) 120 as the second load. In such a blower 101b, even if the heater 121 is temporarily unsatisfactory in driving conditions, the heater 121 can be stopped without issuing a failure signal. In this case, the heater 121 can be quickly restarted if the temporary inadequate drive condition is resolved.

《Supplement》
Although embodiments have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims.

1: inverter device, 2: AC power supply, 3: rectifier circuit, 4: smoothing capacitor, 5: IPM (power module), 5H: drive section, 5L: drive section, 6: DC circuit, 7: DC power supply, 8, 9: capacitor, 10: switch, 11: control unit, 12: fan drive circuit, 13: interlock circuit, 51: HVIC, 52: LVIC, 53, 54: boot capacitor, 100: air conditioner, 101: outdoor unit , 101a: main unit, 101b: air blower, 101c: housing, 102: indoor unit, 103: refrigerant pipe, 103L: liquid refrigerant pipe, 103G: gas refrigerant pipe, 104: air pipe, 105: liquid closing valve, 106 : filter, 107: expansion valve, 108: heat exchanger, 109: four-way switching valve, 110: compressor, 111: accumulator, 112: gas closing valve, 113: fan, 114: heat exchanger, 115: expansion valve , 116: Fan, 120: Fan (second load), 121: Heater (first load), 122: Humidification rotor, 123: Adsorption blower, L1: First DC electric line, L2: Second DC electric line, Pux, Pwz: interconnection point, Qu, Qv, Qw, Qx, Qy, Qz: switching element

Claims (5)

One of the upper arm drive section (5H) and the lower arm drive section (5L) is defined as a first drive section and the other as a second drive section, and the first drive section and the second drive section are configured as a first load. a power module (5) connected to (121) and having a function of outputting a failure signal from the second driving unit when the input control power supply voltage drops below an allowable value;
a first DC electric line (L1) that supplies power from a DC power supply (7) to the first drive unit through a switch (10);
a second DC electric line (L2) for supplying power from the DC power supply (7) to the second driving unit;
An inverter device (1) comprising: The inverter device (1) according to claim 1, wherein the switch (10) is opened when receiving a stop signal of the second load (120) which is the driving condition of the first load (121). A control unit (11) that controls the power module (5) and the second load (120),
When the failure signal is input to the control section (11), the control section (11) controls the first load (121) and the second load (120) through the power module (5). 3. The inverter device (1) according to claim 2, which stops the An interlock circuit (13) that controls opening and closing of the switch (10) based on the operating state of the fan (120) that is the second load,
The interlock circuit (13) opens the switch (10) when the rotation speed of the second load (120) is less than a predetermined rotation speed. 4. The inverter device (1) according to 3. the inverter device (1);
a heater (121) as the first load;
a humidification fan or ventilation fan (120) as the second load;
The blower device according to claim 3 or 4, comprising:

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