JP4158253B2 - Inverter device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an inverter device provided in a general household electrical apparatus.
[0002]
[Prior art]
  A conventional inverter device will be described.
[0003]
  Conventionally, there are two types of inverter devices of this type: those provided with a leakage relay separately from the inverter device, and inverter devices having a leakage detection circuit.
[0004]
  When a leakage current is generated in a load device such as an electric motor that constitutes the inverter device, the leakage relay provided separately from the inverter device leaks.
The leakage current is detected, and the power supply to the inverter device is immediately stopped regardless of the operation of the inverter device.
[0005]
  In addition, an inverter device having a leakage detection circuit, when the leakage detection circuit detects that a leakage current has occurred in a load device such as an electric motor, stops the operation of the inverter circuit and only stops the motor, When the leakage detection circuit detects that a leakage current has occurred in the motor, the operation of the inverter circuit is stopped and the power supply switching means is opened. The configuration will be described below with reference to FIG. FIG. 9 is an example of a block circuit diagram of a conventional inverter device.
[0006]
  As shown in FIG. 9, the zero-phase current transformer 3a normally outputs a voltage to the secondary side in accordance with the difference in current flowing through the two-pole windings on the primary side, as shown in FIG. The current difference and the output voltage are approximately proportional to each other. The output voltage at this time varies depending on the load resistance value connected in parallel to the secondary winding. The determination unit 3b is usually composed of a comparator, a one-shot multivibrator, etc., and outputs a high when the output voltage of the zero-phase current transformer 3a is lower than a predetermined value, and outputs a low for a certain period when the predetermined value is exceeded. Therefore, the zero-phase current transformer 3a and the determination unit 3b constitute the leakage detection circuit 3.
[0007]
  The rectifier circuit 2 is composed of a diode bridge 2a composed of four diodes, a coil 2b, and a capacitor 2c. The AC power source 1 is full-wave rectified, and a DC power source having almost no pulsation is supplied to the inverter circuit 4. The inverter circuit 4 is configured by six power switching means 4a to 4f in a three-phase six stone, and the control means 91 controls the power switching means 4a to 4f to turn on and off the three-phase full-wave AC power supply to the motor 5. And the electric motor 5 is rotationally driven.
[0008]
  The control means 91 is constituted by, for example, a microcomputer, an IC such as a comparator, a drive circuit for driving the power switching means 4a to 4f, and the like, and rotationally drives the electric motor 5 by controlling on / off of the power switching means 4a to 4f. When the leakage detection circuit 3 detects a leakage and outputs a signal, the power switching means 4a to 4f are turned off in response to the signal and the electric motor 9 is stopped.
[0009]
[Problems to be solved by the invention]
  As described above, in the conventional inverter device, when the leakage detection circuit 3 detects the leakage current of the electric motor 5, all the power switching means constituting the inverter circuit are turned off, the electric motor 5 is stopped, and the power supply opening / closing means is opened. The leakage current was cut off.
[0010]
  However, in such a conventional inverter device, when all of the power switching means 4a to 4f are turned off and the electric motor 5 is stopped, no leakage current flows even when the electric motor 5 is immersed in water. There has been a problem that the electric leakage of the electric motor 5 can be detected only while the electric motor 5 is rotationally driven. As a result, when the electric leakage of the electric motor 5 is detected during high-speed rotation driving of the electric motor 5, all of the power switching means 4a to 4f are turned off, and the power supply switching means is opened, the power switching means is caused by a leakage current or the like. There was also a problem that an overvoltage was applied between the input terminals of the inverter circuits constituted by 4a to 4f, causing the power switching means to fail.
[0011]
  SUMMARY OF THE INVENTION The present invention solves the above-described problems, and an object of the present invention is to detect whether the electric motor is leaking before the electric motor is rotationally driven. Another object of the present invention is to realize an inverter device that has few failures and is safe for the user.
[0012]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention provides an AC power source, a rectifier circuit that converts the AC power source into a DC power source, a leakage detection circuit that includes a zero-phase current transformer, and a DC power source that is output from the rectifier circuit. An inverter circuit configured by power switching means for converting to a power source; an electric motor connected to an output of the inverter circuit; and a control means for controlling on / off of the power switching means.,Three power switching means on the high potential side;A high-potential side drive circuit that is powered by a capacitor and a diode to drive the high-potential side power switching means;Three low potential power switching meansAnd havingThe three-phase full-wave configuration, the control means at the start of the motor,Before the electric motor is driven to rotate, the low potential sideIntermittently turning on or off at least one of the power switching means for a predetermined period;SaidDetermine the leakage of the electric motor according to the output of the leakage detection circuitAnd charging each capacitor from the DC power source through the diode.It is comprised as follows.
[0013]
  Thereby, even if the motor is stopped, it is possible to detect whether the motor is leaking, and it is possible to realize a safe inverter device that detects a leak when the motor is started and prevents an electric shock of the user. In addition, since leakage of the motor is determined before the motor is driven to rotate, overvoltage is not generated between the input terminals of the inverter circuit 4 due to leakage current or the like.TheCan be reduced.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
  The invention according to claim 1 is an AC power source, a rectifier circuit that converts the AC power source into a DC power source, a leakage detection circuit having a zero-phase current transformer, and a DC power source that is output from the rectifier circuit is converted into an AC power source. An inverter circuit composed of power switching means, an electric motor connected to the output of the inverter circuit, and control means for controlling on / off of the power switching means, wherein the inverter circuit includes three high potential side power switching means, ,A high-potential side drive circuit that is powered by a capacitor and a diode to drive the high-potential side power switching means;Three low potential power switching meansAnd havingA three-phase full-wave configuration, the control means,When starting the motor,Before the electric motor is driven to rotate, the low potential sideIntermittently turning on or off at least one of the power switching means for a predetermined period;SaidDetermine the leakage of the electric motor according to the output of the leakage detection circuitAnd charging each capacitor from the DC power source through the diode.With this configuration, it is possible to detect electric leakage of the electric motor even when the electric motor is stopped, and it is possible to prevent electric shock of the user. In addition, since leakage of the motor is determined before the motor is driven to rotate, overvoltage is not generated between the input terminals of the inverter circuit 4 due to leakage current or the like.TheCan be reduced.
[0015]
  In addition, when the motor stops, it is possible to simultaneously determine the leakage of the motor and the power supply voltage of the drive circuit on the high potential side, and to reliably detect the leakage of the motor by performing the leakage determination of the motor when the motor is started. When the electric motor is not leaking, the power source voltage of the drive circuit on the high potential side is already secured after the detection of the electric leakage, so that the electric motor can be reliably started.
[0016]
  According to a second aspect of the present invention, in the inverter device according to the first aspect of the present invention, the inverter unit includes a power source switching unit that connects the AC power source and the rectifier circuit, and the power source switching unit is at least turned off by the control unit. Means when starting the motorBefore the motor is driven to rotateSince the operation of the inverter circuit is stopped according to the output of the leakage detection circuit and the power supply switching means is opened, the leakage of the motor can be detected with the motor stopped. It is possible to determine the leakage of the motor at the start-up of the motor, and even though the leakage has already occurred when the motor is stopped, the leakage current is detected when the power supply switching means is opened when the leakage is determined when the motor is driven to rotate. It is possible to prevent the inverter circuit from being damaged due to the wraparound. In addition, since the leakage current path is blocked by the power switching means, the user's electric shock can be prevented.
[0017]
【Example】
  Embodiments of the present invention will be described below with reference to the drawings.
[0018]
  Example 1
  As shown in FIG. 1, the AC power source 1 is a 100 V 60 Hz power source and is connected to the rectifier circuit 2.
[0019]
  In this embodiment, the rectifier circuit 2 is configured to perform full-wave rectification by a diode bridge 2a composed of four diodes, a coil 2b, and a capacitor 2c, and the AC power source 1 is changed to a DC power source of about 141 V with almost no pulsation. It has been converted. The configuration of the rectifier circuit 2 is not limited to this, and a double voltage rectifier circuit configuration is formed using two capacitors connected in series with a diode bridge so that the AC power source 1 is changed to a DC power source of about 283V. It may be.
[0020]
  The leakage detection circuit 3 is composed of a zero-phase current transformer 3a and a determination unit 3b. The zero-phase current transformer 3a normally has a difference between currents flowing through two primary windings as shown in FIG. Accordingly, a voltage is output to the secondary side, and the current difference and the output voltage are approximately proportional to each other. Note that the output voltage at this time varies depending on the load resistance value connected in parallel to the secondary winding. The determination unit 3b is configured by a comparator, a one-shot multivibrator, and the like, and outputs high when the output voltage of the zero-phase current transformer 1 is lower than a predetermined value, and outputs low for a certain period when it exceeds the predetermined value.
[0021]
  The inverter circuit 4 has a three-phase hexagonal structure composed of the high-potential side power switching means 4a to 4c and the low-potential side power switching means 4d to 4f. The AC power supply is supplied to the electric motor 5.
[0022]
  The power switching means 4a to 4f are each composed of an IGBT and a reversely connected diode. However, the power switching means 4a to 4f are not particularly limited to this. For example, a MOSFET or a power transistor corresponding to a large current may be used instead of the IGBT.
[0023]
  Although not particularly shown in the present embodiment, the electric motor 5 has a DC brushless motor configuration in which an 8-pole permanent magnet is provided in the rotor and a three-phase winding constituted by an armature winding is provided in the stator. ing. In this embodiment, high efficiency and high torque output are realized by using a DC brushless motor. However, the present invention is not particularly limited to a DC brushless motor, and may be configured as an induction motor or a switched reluctance motor. .
[0024]
  The control means 6 includes a microcomputer 6a and a drive circuit 6b, a CMOS logic IC (not shown), a switching power supply for supplying power to the microcomputer 6a and the drive circuit 6b, and the like.
[0025]
  Although not specifically shown in FIG. 1, the microcomputer 6a has a predetermined power according to an output signal of a position detection circuit constituted by a Hall IC that detects the position of a permanent magnet included in the rotor of the electric motor 5. An on / off signal is output to the drive circuit 6b so that the switching means is turned on and off, and the conduction ratio of the power switching means 4a to 4f is controlled so that the electric motor 5 is driven at a predetermined rotational speed. Further, the microcomputer 6a detects that the output of the determination unit 3b is low, determines that leakage current is flowing in the motor 5 (leakage), and turns off the power switching means 4a to 4f to the drive circuit 6b. Is output and the electric motor 5 is stopped.
[0026]
  The drive circuit 6b is provided with a push-pull circuit composed of an NPN transistor and a PNP transistor in each of the power switching means 4a to 4f, and the push-pull circuit changes the power switching means 4a to 4f according to the output signal of the microcomputer 6a. The power switching means 4a to 4f are turned on / off by supplying power to the gate terminal of the IGBT to be configured. The configuration of the drive circuit 6b is not limited to an example, and high integration may be performed using, for example, an integrated power module (IPM) in which the drive circuit and the power switching unit are contained in one package. .
[0027]
  With regard to the above configuration, the operation of leakage detection control at the time of starting the electric motor 5 will be described with reference to FIG. FIG. 3 is a time chart for determining leakage when the electric motor 5 is started, and shows waveforms of respective parts when leakage determination is made. FIG. 3A shows a difference between currents flowing through the two-pole windings on the primary side of the zero-phase current transformer 3a, that is, leakage current. Note that the leakage current does not necessarily have the waveform as shown in FIG. 3A, but has various waveforms depending on the configuration of the rectifier circuit 2 and the configuration of the electric motor 5. In this embodiment, the inverter shown in FIG. A description will be given using a leakage current waveform in the apparatus. 3B is an output voltage waveform of the zero-phase current transformer 3a, FIG. 3C is an output voltage waveform of the determination unit 2, FIG. 3D is an on / off state of the power switching means 4a, and FIG. Is an on / off state of the power switching means 4b, FIG. 3 (f) is an on / off state of the power switching means 4c, FIG. 3 (g) is an on / off state of the power switching means 4d, and FIG. 3 (h) is an on / off state of the power switching means 4e. FIG. 3 (i) shows the on / off state of the power switching means 4f.
[0028]
  When the electric motor 5 is leaked and the three-phase winding of the electric motor 5 is grounded, it is connected to the AC power source 1 through this grounding point, and the potential of the AC power source 1, the resistance of water, and the impedance of the inverter device are connected. Accordingly, a leakage current flows. However, at t1 in FIG. 3, the power switching means 4a to 4f are all turned off, and the capacitor 2c is sufficiently charged, and the charging current to the capacitor 2c hardly flows and the potential does not fluctuate, so the leakage current is almost not. Not flowing. Next, at t2, the control means 6 turns the power switching means 4d on and off a predetermined number of times with a predetermined period as shown in FIG. In this embodiment, it is turned on and off 16 times with a conduction ratio of 50% in a cycle of 2 ms. Then, when the power switching unit 4d is in an on state, a leakage current flows through the following path. When the grounded ground side of the AC power supply 1 is at a high potential, the three-phase winding flows from the high potential side of the AC power supply 1 via the ground grounding point, flows through the IGBT of the power switching means 4d, and the diode bridge 2a. Leakage current flows in a path that flows through the AC power source 1 and reaches the low potential side of the AC power supply 1. When the pole-grounded side of the AC power supply 1 is at a low potential, no leakage current flows when the capacitor 2c is sufficiently charged. However, when the capacitor 2c is not charged and the charging current to the capacitor 2c flows, the coil 2b flows from the high potential side of the AC power source 1 via the diode bridge, flows through the capacitor 2c, and the power on the low potential side. It flows through the three-phase winding of the electric motor 5 via the reverse connection diodes of the switching means 4d to 4f, and flows along a path reaching the low potential side of the AC power supply 1 via the ground ground point of the three-phase winding. In the present embodiment, the charging current that temporarily flows through the capacitor 2c when the power is turned on becomes large. However, when the inverter circuit 4 is in a stopped state, the charging current hardly flows and the leakage current becomes very small. I can't feel it.
[0029]
  Therefore, in the present embodiment, when the electric motor 5 is leaked, when the electric motor 5 is started, the power switching means 4d is turned on / off as shown in FIG. 3 (g) to cause a leakage current as shown in FIG. 3 (a). As a result, a current difference occurs between the two primary windings of the zero-phase current transformer 3a, and the secondary winding corresponds to the waveform of FIG. 3A as shown in FIG. 3B. Output voltage waveform. As shown in FIG. 3C, the determination unit 3b outputs low for a predetermined period Ts1 at a time t3 when the output voltage waveform of the secondary winding exceeds the predetermined value Vs or −Vs. At this time, the current difference between the two poles on the primary side is Is or -Is. When the control means 6 detects the low output of the determination section 3b, it immediately holds all the power switching means 4a to 4f in the off state, and if the determination section 3b outputs low even after a predetermined time from t3, the motor 3 is determined to be a leak.
[0030]
  If the leakage detection circuit 3 does not output low even after the power switching means 4d is turned on for a predetermined number of times, the microcomputer 6a determines that the electric motor 5 is not leaking and drives the electric motor 5 to rotate. ing. In this embodiment, even if the switch is turned on 16 times, if the leakage detection circuit 3 does not output low, it is determined that the electric motor 5 is not leaking. Therefore, the leakage detection control of the first embodiment is performed in a maximum period of 32 ms.
[0031]
  In general, in order to prevent malfunction due to lightning surge, the leakage detection is provided with a counter or the like in the determination unit 3b, and the leakage is determined when the voltage of the secondary winding exceeds a predetermined value several times. However, in addition to the leakage detection circuit that can also be applied to the inverter device as in this embodiment, the input terminal of the determination unit 3b is low-passed to prevent malfunction caused by noise generated during the operation of the inverter circuit. A filter is often provided. However, the configuration is not particularly limited. In the present embodiment, when the output voltage waveform of the secondary winding exceeds a predetermined value twice, the determination unit 3b determines that there is a leakage as shown in FIG. Is output.
[0032]
  In this embodiment, only the low-potential side power switching means 4d is turned on / off. However, the present invention is not limited to this, and all of the low-potential side power switching means 4d to 4f may be turned on / off simultaneously. Further, as described above, leakage current flows even if only the high potential side power switching means is turned on. Therefore, the high potential side power switching means may be turned on and off instead of the low potential side power switching means. . Here, the path of the leakage current when turning on / off the power switching means on the high potential side will be described.
[0033]
  Next, in the inverter apparatus of FIG. 1, the control means 5 turns on and off only the high-potential side power switching means 4a at a predetermined period when the electric motor 5 is started. Other configurations are the same as those in FIG. In this inverter device, the path of the leakage current when the power switching means 4a is on when the electric motor 5 is leaking at the time of startup will be described. When the pole-grounded side of the AC power supply 1 is at a high potential, almost no leakage current flows because the capacitor 2c is almost charged. When the grounded pole side of the AC power supply 1 is at a low potential, it flows through the diode bridge 2a from the high potential pole of the AC power supply 1, flows through the IGBT of the power switching means 4a, and flows through the three-phase winding of the motor 5. A leakage current flows through a path reaching the low potential side pole of the AC power supply 1 via the grounding point of the three-phase winding.
[0034]
  As described above, the leakage of the electric motor 5 can be reliably detected by turning on / off at least one of the power switching means on the high potential side or the low potential side when the electric motor 5 is started. When the power switching means is turned on / off with a conduction ratio of 50% in a longer period than the pulse width of the surge voltage generated when the power switching means 4a to 4f is turned on / off of 2 ms as in the present embodiment, the determination unit 3b has a low pass. Even in the case where a filter is provided, it is possible to determine whether or not the leakage current exceeds a predetermined value, and it is possible to shorten the time until the number of times the predetermined value exceeds the predetermined value. In particular, when the power switching means is turned on / off before driving the electric motor 5 as in the present embodiment, it becomes possible to make it shorter than the cycle of the electric leakage current at the start-up of the electric motor 5, and the leakage current is detected earlier. The user's electric shock can be prevented.
[0035]
  In the present embodiment, the leakage detection control before the electric motor 5 is rotationally driven has been described. However, depending on the electric equipment provided with the inverter device, electric leakage may occur during the rotational driving of the electric motor 5. Even in this case, since the leakage detection circuit 3 always detects whether a leakage current has occurred, even if a leakage occurs during the rotation of the motor 5, the leakage detection circuit 3 detects this leakage and outputs a low output immediately. The control means 5 turns off the power switching means 4a to 4f as shown in FIG.
[0036]
  Therefore, even if the electric motor 5 is rotating or not rotating, it is possible to reliably detect whether the electric motor 5 is leaking electric current, so that a safe inverter device can be realized.
[0037]
  (Example 2)
  As shown in FIG. 4, the power supply switching means 11 connects the AC power supply 1 and the rectifier circuit 2, and can be turned off by an output signal of the microcomputer 13 constituting the control means 12. Yes. Other configurations are the same as those of the first embodiment, and the same reference numerals are given and the description thereof is omitted.
[0038]
  In this embodiment, the power supply opening / closing means 11 is constituted by a mechanical latch type switch, but is not particularly limited, and may be constituted by a relay or triac that can be controlled on and off. The mechanical latch type switch closes the contact point when a user pushes the button, and the microcomputer 13 outputs an electrical signal to generate an electromagnetic force inside the switch, which is in a latched state. Is restored and the contact is opened. In this embodiment, when the control means 12 controls the power supply switching means 11 to be turned off, the power supply switching means 11 opens both poles of the AC power supply 1 to cut off the current path and stop the power supply to the rectifier circuit 2. Like to do. However, the configuration of the power supply opening / closing means 11 is not limited to this. For example, one of the poles of the AC power supply 1 may be opened and closed using one relay.
[0039]
  An example of leakage detection control at the time of starting the electric motor 5 of the inverter device shown in FIG. 4 will be described with reference to FIGS. 3 and 4.
[0040]
  When the operation of the electric motor 5 is started, as shown in FIG. 3, the control means 12 turns on and off the power switching means 4d with a conduction ratio of 50% in a cycle of 2 ms, and leakage occurs when the electric motor 5 is leaking. Allow current to flow. When the leakage current detection circuit 3 detects this leakage current and outputs low, the microcomputer 13 detects this, and immediately outputs a signal that turns off all the power switching means 4a to 4f to the driving circuit 6c. To turn off all the power switching means 4a to 4f. Thereafter, if the output is low for a predetermined period Ts2, it is determined that there is a leakage, and a signal for turning off the power supply switching means 11 is output. Upon receipt of the signal, the power supply switching means 11 is opened.
[0041]
  As described above, the power supply switching means 11 is provided, and when the leakage detection is made during the leakage detection control, the control means 12 turns off the power switching means 4a to 4f and opens the power supply switching means 11. Therefore, leakage current can be cut off and leakage can be prevented. Further, by providing this leakage detection control at the time of starting the electric motor 5, when the electric motor 5 is leaking, the power supply switching means 11 can be opened before the electric motor 5 is rotationally driven. As a result, when the electric motor 5 is rotationally driven, the leakage determination is made and the power supply switching means 11 is opened, so that a leakage current flows into the inverter circuit 4 and a surge voltage is generated between the input terminals of the inverter circuit 5, It is possible to prevent the inverter circuit from failing.
[0042]
  (Example 3)
  Next, the present inventionNoAn example of the circuit configuration of the inverter device will be described with reference to FIG. In addition, the same structure as Example 2 of this invention attaches | subjects the same code | symbol, and abbreviate | omits description.
[0043]
  As shown in FIG. 5, the control means 21 includes a DC power source 22, a microcomputer 23, drive circuits 24a to 24f, diodes 25a to 25c, and capacitors 26a to 26c. The operation unit 27 includes a plurality of momentary switches, and the operation conditions of the inverter device are set by pressing the momentary switches. The notification means 28 is composed of a display element such as an LED and a buzzer. The notification means 28 is configured to display the number of rotations of the electric motor 5 and to notify the abnormality when an abnormality occurs in the inverter device.
[0044]
  The DC power source 22 is constituted by a switching power source in this embodiment, receives DC power from the rectifier circuit 2, converts it to 5V and 15V DC power, supplies the 5V power to the microcomputer 23, and drives the 15V power. The circuits 24a to 24f are supplied.
[0045]
  The microcomputer 22 performs charge control for charging the capacitors 26a to 26c when the electric motor 5 is started. The charge control will be described later. Others are the same as in the second embodiment.
[0046]
  The drive circuits 24a to 24f are constituted by push-pull circuits composed of NPN transistors and PNP transistors, and turn on / off the IGBTs constituting the power switching means in response to the output signal of the microcomputer 22.
[0047]
  The output terminals of the high potential side drive circuits 24a to 24c are connected between the respective gate terminals and emitter terminals of the IGBTs constituting the high potential side power switching means 4a to 4c, and the outputs of the low potential side drive circuits 24d to 24f. The terminal is connected to the gate terminal of the IGBT constituting the power switching means 4d to 4f on the high potential side.
[0048]
  The power sources of the high-potential side drive circuits 24a to 24c are diodes 25a to 25c from the DC power source 22 while the low-potential side power switching means 4d to 4f are in the on state for each of the three phases. Although not shown, capacitors 26a to 26c are charged through charging resistors connected in series to diodes 25a to 25c provided to limit the charging current, and these capacitors 26a to 26c are connected to a high-potential side drive circuit. It is set as the structure used as a power supply of 24a-24c.
[0049]
  In the present embodiment, the IGBT is used for the power switching means 4a to 4f, so that the power required for driving the so-called MOS gate is reduced, and even if the capacitances of the capacitors 26a to 26c are small, it is sufficient. Switching drive is possible.
[0050]
  Next, charging control of the capacitors 26a to 26c at the time of starting the electric motor 5 of the inverter device shown in FIG. 5 will be described with reference to FIG. FIG. 6 is a time chart of the charging control.
[0051]
  6A shows the on / off state of the power switching means 4a, FIG. 6B shows the on / off state of the power switching means 4b, FIG. 6C shows the on / off state of the power switching means 4c, and FIG. 6D shows the power switching. The on / off state of the means 4d, FIG. 6 (e) shows the on / off state of the power switching means 4e, and FIG. 6 (f) shows the on / off state of the power switching means 4f.
[0052]
  In this embodiment, when the operation of the electric motor 5 is started, first, a period for turning off all the power switching means 4a to 4f is provided, and charging control is performed from T1 in FIG.
[0053]
  In the charge control, the microcomputer 22 outputs an ON / OFF signal with a conduction ratio of 50% to the low potential side drive circuits 24d to 24f in a cycle of 2 ms. Upon receiving this signal, the low-potential side drive circuits 24d to 24f operate the low-potential side power switching means 4d to 4f 16 times with a 50% conduction ratio in a cycle of 2 ms as shown in FIGS. Turn on and off. Therefore, the charging control of this embodiment takes 32 ms.
[0054]
  Generally, when charging a capacitor through a resistor, the voltage is almost the same as the voltage of the DC power supply that supplies power by charging over a time longer than the time constant determined by the product of the capacitance of the capacitor and the resistance value of the resistor. Can charge up to value.
[0055]
  In this embodiment, the capacitors 24a to 24c are intermittently charged by turning on and off the power switching means 4d to 4f on the low potential side. In this case, the power switching on the low potential side is performed during the time when the charge control is performed. Since the time multiplied by the conduction ratio of the means 4d to 4f is the net charging time of the capacitors 26a to 26c, the charging time of the capacitors 26a to 26c in this embodiment is 16 ms.
[0056]
  In this embodiment, the charging time is set to be about 8 times the time constant, and even if the initial charges of the capacitors 26a to 26c are zero, the output voltage of the switching power supply 6a is 99%. Since the voltage corresponding to% can be charged, the power switching means 4a to 4c on the high potential side can be reliably turned on when the electric motor 5 is started.
[0057]
  In FIG. 6, after the charge control is performed, all the power switching means 4a to 4f are turned off for a predetermined period from T2, and the position of the permanent magnet included in the rotor of the electric motor 5 is detected from T3 as in the first embodiment. The power switching means 4a to 4f are on / off controlled in accordance with the output signal of the position detection circuit to rotate the electric motor 5. By turning off all the power switching means 4a to 4f from T2 to T3, the power switching means 4a to 4c on the high potential side and the power switching on the low potential side are switched when switching from the charge control to the rotational drive of the electric motor 5. Generation of a short-circuit current due to simultaneous ON of the means 4d to 4f is prevented, and failure of the power switching means due to this short-circuit current is prevented.
[0058]
  Next, the case where the electric motor 5 is leaking will be described. When the charging control shown in FIG. 6 is performed when the electric motor 5 is started, a leakage current flows through the following path when the power switching means 4d to 4f are turned on. When the grounded ground side of the AC power supply 1 is at a high potential, it flows through the three-phase winding 5a from the high potential pole side of the AC power supply 1 via the ground grounding point, and the power switching means 4d on the low potential side. It flows through the IGBT that constitutes 4f, flows through the diode bridge 2a, and reaches the low potential side pole of the AC power supply 1. The leakage detection circuit 3 detects this leakage current and outputs a low to the microcomputer 22 so that the microcomputer 52 determines the leakage of the electric motor 5 and turns off all the power switching means 4a to 4f and the power switching means 41. To prevent leakage current by blocking the leakage current path.
[0059]
  The leakage current path is the same as that when the low potential side power switching means 4d of the first embodiment of the present invention is turned on, except that the power switching means 4e and 4f are simultaneously turned on. Leakage current flows through the path. Therefore, even when the pole-grounded side of the AC power supply 1 is at a low potential, almost no leakage current flows as in the first embodiment of the present invention.
[0060]
  As described above, when the power sources of the high potential side drive circuits 24a to 24c are constituted by the capacitors 26a to 26c, the power supply voltage of the capacitors 26a to 26c is obtained by performing the above-described charging control when the motor 5 is started. It is possible to detect whether or not the electric motor 5 is leaking electric current, to reliably detect and prevent electric leakage when the electric motor 5 is started up, and reliably when the electric motor 5 is not leaking electric current. An inverter device capable of starting the electric motor 5 can be realized.
[0061]
  Next, FIG. 7 shows a structural diagram of an electric washing machine provided with the inverter device of FIG. As shown in FIG. 7, the water receiving tub 31 is provided with a washing and dewatering tub 33 having a stirring blade 32 rotatably provided at the inner bottom thereof, and is suspended from a washing machine body 35 by a support bar 34. The speed reduction mechanism 36 is provided at the bottom of the water receiving tub 31 and transmits power to the stirring blade 32 and the washing and dewatering tub 33. The electric motor 5 is provided below the speed reduction mechanism 36.
[0062]
  The water supply valve 37 supplies water into the washing / dehydrating tank 33, and the drain valve 38 drains the washing water in the washing / dehydrating tank 33.
[0063]
  Here, the speed reduction mechanism 36 has a planetary gear, and when the stirring blade 32 is rotationally driven, the sun gear is driven by the rotation shaft of the electric motor 5 and the rotation of the planetary gear is transmitted to the stirring blade 32. The speed is reduced to 1/6 and the output torque of the electric motor 5 is converted to 6 times. When the washing and dewatering tub 33 is rotated in a dehydration process or the like, although not particularly illustrated, the speed reduction mechanism 36 is separated from the output shaft of the electric motor 5 by a clutch mechanism, and the washing and dehydrating tub 33 is directly driven by the electric motor 5. .
[0064]
  As described above, in the electric washing machine shown in FIG. 7, since the electric motor 5 is disposed at the center of the water receiving tank 31, the weight balance of the water receiving tank 31 becomes good, The weight of the electric washing machine can be reduced by the effect that it is not necessary to increase the load and the effect that the components such as the ball bearing are shared with the components of the speed reduction mechanism 36.
[0065]
  However, the configuration of the electric motor 5 is not particularly limited. For example, a configuration in which the power of the electric motor 5 is transmitted to the speed reduction mechanism 36 by a belt, or even in a washing process without providing the speed reduction mechanism 36 is used. May be transmitted to the stirring blade 32.
[0066]
  In the above configuration, the control means 21 performs the charging control described with reference to FIG. 6 when the electric motor 5 is started up, and detects the electric leakage of the electric motor 5 by detecting the output of the electric leakage detection circuit 3 at this time. Stops the subsequent operation of the inverter circuit 4 and opens the power supply switching means 11, and when there is no electric leakage, the subsequent operation of the inverter device is continued. Further, when the leakage detection circuit 3 detects a leakage current and outputs a low output even during the rotation of the electric motor 5, the operation of the inverter circuit 4 is stopped and the power supply switching means 11 is opened.
[0067]
  In general, in the electric washing machine, when the washing water is drained from the drain valve 28 when the dehydration process is started, if the waste is collected in the drain port, the water overflows and the electric motor 5 is often immersed in the water. However, even in such a case, by performing the charging control shown in FIG. 6 when the electric motor 5 is started up, it is possible to easily detect the electric leakage and cut off the leakage current before the electric motor 5 is rotationally driven. As a result, it is possible to prevent the user from receiving an electric shock or to prevent the inverter circuit 4 from being broken due to a leakage current caused by opening the power supply switching means 11 while the electric motor 5 is being rotated. Therefore, a safe and less trouble electric washing machine can be realized. Note that this effect is the same for all electrical devices including the inverter device of this embodiment.
[0068]
  Example 4
  When the control unit 21 shown in FIG. 5 is set to notify the leakage abnormality in the operation unit 27, the leakage detection circuit 3 stops the inverter circuit 4 when the leakage current is detected, and the notification unit 28 notifies the abnormality. Like to do. Other configurations are the same as those of the third embodiment.
[0069]
  The operation of the above configuration will be described with reference to FIG. FIG. 8 is an example of a time chart of leakage detection when leakage abnormality notification is set.
[0070]
  When the operation of the inverter device is started in step 41, the control means 21 performs the charging control described in FIG. Here, when the motor 5 is in contact with water and the three-phase winding 5b is grounded, a leakage current flows and the output voltage of the secondary winding of the zero-phase current transformer 3b reaches a predetermined value twice. When it exceeds, the determination unit 2 outputs low for a predetermined period Ts1. At the same time as leakage detection circuit 3 outputs low, at step 43, control means 21 detects this low output, and at step 44, all power switching means 4a-4f are turned off. If there is no low output from the leakage detection circuit 3 during the charge control, it is determined in step 45 that the electric motor 5 is not leaking, and the rotation drive of the electric motor 5 is started in step 46.
[0071]
  After the control means 21 turns off all the power switching means 4a to 4f in step 44, it is checked in step 47 whether the low output of the leakage detection circuit 3 continues for Ts2, and if not, in step 45. It is determined that noise is present, and it is determined that the electric motor 5 is not leaking. In step 46, the rotation drive of the electric motor 5 is started. In step 47, when it is confirmed that the low output of the leakage detection circuit 3 continues for the predetermined period Ts2, it is confirmed in step 48 whether or not the leakage abnormality notification is set by the operation unit 27.
[0072]
  If the leakage abnormality notification is set by the operation unit 27, the leakage abnormality is notified by the notification means 28 in step 49. In step 48, if the leakage abnormality notification is not set, in step 50, the power source switching means 11 is opened when the predetermined time Ts3 has elapsed from the leakage determination, and the leakage current path is blocked.
[0073]
  As described above, it is possible to confirm that the electric motor 5 is leaking by setting the leakage abnormality notification by the operation unit 27.
[0074]
  Normally, in order to prevent the user's electric shock, when the leakage current flows, the current switching means 11 is immediately cut off and the path of the leakage current is cut off. However, the control means as in this embodiment is used. In the case where eleven power sources are supplied from the capacitor 2c via the DC power source 22, abnormality notification cannot be performed. Therefore, it cannot be confirmed from the user which abnormality is present.
[0075]
  However, a special engineer such as a service person can perform a specific setting that a general user does not know in order to notify the abnormality of leakage in the operation unit 57, so that the leakage of the motor 5 can be confirmed. In addition to preventing this, it is possible to notify abnormality of electric leakage.
[0076]
  In addition, the inverter device, the leakage detection control, and the start control shown in the above embodiments are examples, and the present invention is not limited thereto.
[0077]
【The invention's effect】
  As described above, according to the first aspect of the present invention, an AC power supply, a rectifier circuit that converts the AC power supply into a DC power supply, a leakage detection circuit having a zero-phase current transformer, and an output of the rectifier circuit are output. An inverter circuit for converting a DC power source into an AC power source, an electric motor connected to the output of the inverter circuit, and a control means for controlling on / off of power switching means constituting the inverter circuit, the inverter circuit having three high potential sides Power switching means,A high-potential side drive circuit that is powered by a capacitor and a diode to drive the high-potential side power switching means;Three low potential power switching meansAnd havingA three-phase full-wave configuration, the control means,When starting the motorBefore the electric motor is driven to rotate.Intermittently turning on or off at least one of the power switching means for a predetermined period;SaidDetermine the leakage of the electric motor according to the output of the leakage detection circuitAnd charging each capacitor from the DC power source through the diode.With this configuration, it is possible to detect electric leakage of the electric motor even when the electric motor is stopped, and it is possible to prevent electric shock of the user. In addition, since leakage of the motor is determined before the motor is driven to rotate, overvoltage is not generated between the input terminals of the inverter circuit 4 due to leakage current or the like.TheCan be reduced.
[0078]
  In addition, when the motor is stopped, the motor leakage check and the supply voltage of the drive circuit on the high potential side are ensured.
It is possible to detect the leakage of the motor by making a determination of the leakage of the motor at the time of starting the motor. If the motor is not leaking, the drive circuit on the high potential side has already been detected after the leakage detection. Since the power supply voltage is ensured, the electric motor can be reliably started.
[0079]
  According to a second aspect of the present invention, the power supply switching means for connecting the AC power supply and the rectifier circuit is provided, the power supply switching means is at least turned off by the control means, and the control means is activated when the motor is started.Before the motor is driven to rotateSince the operation of the inverter circuit is stopped according to the output of the leakage detection circuit and the power supply switching means is opened, it is possible to detect the leakage of the motor while the motor is stopped. It is possible to determine the leakage of the motor at startup, and the leakage current wraps around when the leakage is determined and the power switching means is opened when the motor is driven to rotate, even though the leakage has already occurred when the motor is stopped. Thus, it is possible to prevent the inverter circuit from failing. In addition, since the leakage current path is blocked by the power switching means, the user's electric shock can be prevented.
[Brief description of the drawings]
FIG. 1 is a block circuit diagram of an inverter device according to a first embodiment of the present invention.
Fig. 2 Input / output characteristics diagram of zero-phase current transformer of leakage detection circuit provided in the inverter device
FIG. 3 is a time chart of leakage detection control when starting up the electric motor of the inverter device.
FIG. 4 is a block circuit diagram of an inverter device according to a second embodiment of the present invention.
FIG. 5 is a block circuit diagram of an inverter device according to a third embodiment of the present invention.
FIG. 6 is a time chart of the inverter circuit when starting the electric motor of the inverter device.
FIG. 7 is a cross-sectional view of an electric washing machine equipped with the inverter device
FIG. 8 is an operational flowchart of leakage detection control at the time of setting a leakage abnormality notification of the inverter device according to the fourth embodiment of the present invention;
FIG. 9 is a block circuit diagram of a conventional inverter device.
[Explanation of symbols]
  1 AC power supply
  2 Rectifier circuit
  3 Earth leakage detection circuit
  3a Zero-phase current transformer
  4 Inverter circuit
  4a-4f Power switching means
  5 Electric motor
  6 Control means

Claims (2)

An AC power source, a rectifier circuit that converts the AC power source into a DC power source, a leakage detection circuit that has a zero-phase current transformer, and a power switching means that converts the DC power source output from the rectifier circuit into an AC power source. An inverter circuit; an electric motor connected to the output of the inverter circuit; and a control means for controlling on / off of the power switching means. The inverter circuit is supplied with power from three high-potential side power switching means, a capacitor and a diode. And a three-phase full-wave configuration comprising a high-potential side drive circuit for driving the high-potential side power switching means and three low-potential side power switching means, and the control means starts the motor sometimes, intermittently at least one of the low-potential-side power switching means before the electric motor is driven to rotate A predetermined time period off, the inverter device in which the charging via the diode of each capacitor from said DC power supply with determining the leakage of the electric motor in accordance with the output of the earth leakage detection circuit. Power supply switching means for connecting an AC power supply and a rectifier circuit is provided, and the power supply switching means is at least turned off by the control means, and the control means outputs the leakage detection circuit before starting to rotate the motor when the motor is started. The inverter device according to claim 1, wherein the operation of the inverter circuit is stopped in response and the power supply switching means is opened.

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