JPH11220898A - Leakage current reduction device of electric apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a leakage current reduction device which has a sufficient leakage current reduction effect and, further, does not need the adjustment at site. SOLUTION: A full-wave rectifier circuit 2 is connected between the output terminals of an AC power supply 1 and the rectified power is smoothed by a capacitor 3 to provide a DC power supply for an inverter. The output voltages of the respective phases of a 3-phase inverter 4 to which the DC power supply is inputted are applied to the stator windings of the respective phases of a 3-phase motor 5. A deviation of the neutral potential of the stator windings of the 3-phase motor 5 from a housing potential is detected. In response to the deviation and by the input of the DC power supply for the inverter, a cancellation current which cancels a leakage current flowing through a housing 8 is generated by a cancellation current generator 9 and supplied to the housing 8.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for reducing leakage current of electric equipment, and more particularly, to driving a motor by connecting an electric equipment having an inverter circuit and a motor to a power supply. The present invention relates to a device for reducing a leakage current caused by a stray capacity between a conductive portion of a motor and an iron core portion and conductivity through a refrigerant, refrigerating machine oil, or the like.

[0002]

2. Description of the Related Art Hitherto, as a device for reducing leakage current of electric equipment, those having the configuration shown in FIG. 20, the configuration shown in FIG. 21, and the configuration shown in FIG. 22 have been proposed. In the configuration shown in FIG. 20, an AC voltage from an AC power supply 51 is applied to an inverter circuit 53 via a noise filter 52, and an output voltage from the inverter circuit 53 is applied to a load (motor) 54 included in an electric device. I have. And the AC power supply 51
A primary winding of a transformer 56 is connected between an AC power supply line between the power supply and the noise filter 52 via a capacitor 55, and a secondary winding of the transformer 56 is connected to a ground terminal 58 via a capacitor 57. ing. Note that one terminal of the AC power supply 51 is also grounded. Further, the housing of the electric device is also grounded.

When this configuration is adopted, an AC power supply 5
The harmonic current and the power supply frequency current leaking out of the noise filter 52 from 1 are applied to the primary winding of the transformer 56 via the capacitor 55, and the induced voltage of the secondary winding of the transformer 56 causes It seems that the leakage current (power frequency current component and harmonic current component) leaking to the housing can be offset.

In the configuration shown in FIG. 21, an AC voltage from an AC power supply 61 is supplied to an inverter circuit 63 via a noise filter 62, and an output voltage from the inverter circuit 63 is supplied to a load (motor) 64 included in electric equipment. Is being applied.
A resistor 66 u, 66 v, 66 w and a capacitor 67 are connected between the voltage terminal of each phase of the motor 64 and the capacitor 65 connected to the positive voltage supply terminal of the inverter circuit 63.
u, 67v, 67w and transformers 68u, 68v, 6
8w primary windings are connected in series, and the transformers 68u and 68u are connected between the capacitor 65 and the housing 69 of the electric device.
v, 68 w secondary winding and capacitors 70 u, 70
v and 70w are connected in series. Note that one terminal of the AC power supply 61 is grounded, and the housing 69 of the electric device is also grounded. The ground terminal of the noise filter 62 and the outer casing of the motor are connected to the housing 69 of the electric device.

When this configuration is adopted, the motor 64
The harmonic current and the power supply frequency current leaking to the voltage terminals of the respective phases are supplied to the transformer 68 via resistors 66u, 66v, 66w and capacitors 67u, 67v, 67w, respectively.
u, 68v, 68w on the primary winding, and the transformer 68
u, 68v, 68w by the induced voltage of the secondary winding,
It is thought that the leakage current (power supply frequency current component and harmonic current component) leaking to the housing of the electric device can be offset.

The configuration shown in FIG. 22 is disclosed in Japanese Patent Laid-Open No. 9-23383.
No. 7, which discloses a smoothing circuit between output terminals of a DC power supply (a DC power supply obtained by rectifying an AC power supply, or a DC power supply provided separately). A DC power supply smoothed by the capacitor 71 is supplied to the inverter circuit 72, and an output voltage from the inverter circuit 72 is applied to a load (motor) 73 included in the electric device. Then, a switching signal of the switching element of each phase of the inverter circuit 72 is supplied to the control circuit 74 to calculate a canceling current command for canceling the leakage current. The current is supplied to a generation circuit 75 to output a cancellation current for each phase, and the cancellation current for each phase is supplied to a housing 77 of the electric device through an equivalent circuit 76 in which resistors and the like are Y-connected.

When this configuration is adopted, a canceling current for canceling a leakage current from a switching signal of a switching element of each phase of the inverter circuit 72 is supplied to the housing of the electric device, so that the motor 73 generates electric power. It seems that the leakage current leaking into the housing of the device can be offset.

[0008]

The configuration shown in FIG. 20 is effective at an actual installation site because the ground potential of the power supply side which is originally grounded and the ground potential laid at the time of grounding are completely different. It is known that the leakage current reduction device does not operate in the configuration shown in FIG. 20 when the two ground potentials do not coincide with each other and when the two ground potentials coincide. But,
Since an actual installation site is not normally in a completely grounded state, a method of supplying a canceling current so as to directly act on a housing of an electric device as shown in FIG. 20 is effective. Further, the voltage condition required on the secondary side of the transformer 56 largely depends on the difference between the two ground potentials, that is, the ground state at the installation site. Further, the connection direction of the primary winding or the secondary winding of the transformer 56 must be correct.

Therefore, in the configuration shown in FIG. 20, the leakage current mitigation device cannot be set in advance at the time of shipment from the factory, and there is a disadvantage that adjustment at the installation site becomes indispensable. In the configuration shown in FIG. 20, the primary winding of the transformer 56 also detects external harmonics (noise). However, the noise filter 52 is provided to remove such external noise. Inverter circuit 53
Harmonics (noise) from the inside are also removed by the noise filter 52. Therefore, in the configuration shown in FIG. 20, the leakage current reducing device mainly cancels the fundamental wave component, and the harmonic filter (noise) from the inverter circuit or the like is removed by the noise filter 52. There is also the inconvenience that the effect can only be expected for the objects.

In the configuration shown in FIG. 21, the leakage current reducing device includes transformers 68u, 68v,
68w, resistors 66u, 66v, 66w, capacitor 67
Since u, 67v, 67w and the like are required, the configuration is significantly complicated, the cost is significantly increased, and the respective adjustments are required. Therefore, there is a disadvantage that the adjustment work becomes extremely complicated.

Further, when attention is paid to the negative pole of the DC power supply section of the inverter circuit 63, considering the AC power supply 61 in which one phase is grounded, if normal full-wave rectification is employed, + ,-. In the leakage current reducing device of FIG. 21, the leakage of the low-frequency current component (power frequency current component) is caused by the secondary windings of the transformers 68u, 68v, 68w, the capacitors 70u, 70v, There is an inconvenience that it is rather increased after 70 w or the like. This inconvenience also occurs when a three-phase AC power supply is employed, but does not occur when a single-phase three-wire configuration or a configuration that performs voltage doubler rectification is employed.

Of the configuration shown in FIG. 22, the leakage current reduction device requires a control circuit 74, a canceling current generation circuit 75, and an equivalent circuit 76, which complicates the configuration as a whole and increases the cost. There is a disadvantage that it goes. In addition, the back electromotive force is generated from the motor 73 according to the rotation state, and the switching signals of the switching elements of each phase of the inverter circuit 72 do not necessarily reflect the back electromotive force. There is also a disadvantage that the effect may not be achieved.

Both the leakage current reducing device shown in FIG. 20 and the leakage current reducing device shown in FIG. 21 detect the leakage current that has already been output, and try to cancel it later. On the other hand, the leakage current mitigation device of FIG. 22 has reduced the idea of detecting the leakage current that has already exited and canceling it afterwards. In recent years, with the use of high frequency for chopping due to the spread of inverter motors and the like, and in inverter air conditioners and the like, the coil portion is directly immersed in refrigerant or lubricating oil, so that leakage current increases. On the other hand, in order to prevent ozone layer destruction, refrigerants and lubricating oils having a higher dielectric constant than conventional refrigerants tend to be used. Therefore, reduction of leakage current is an urgent problem in electric appliances, particularly inverter air conditioners and the like, and it is expected to provide a leakage current reduction device having a sufficient leakage current reduction effect.

Further, in Japan, especially in household electric appliances, the grounding is not always perfect as compared with Europe and the United States, so from this aspect it is possible to sufficiently reduce the leakage current regardless of the grounding state. It is expected to provide a leakage current mitigation device.

[0015]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to provide a leakage current reducing device which has a sufficient leakage current reducing effect and does not require on-site adjustment.

[0016]

According to a first aspect of the present invention, there is provided a leakage current mitigation apparatus for an electric apparatus, wherein an electric apparatus having an inverter circuit and a motor is connected to a power supply, and a neutral point of a stator winding of the motor is determined. Potential fluctuation detecting means for detecting a fluctuation in the potential is provided, and in response to the detected fluctuation in the potential at the neutral point, a current flows in a direction to offset a leakage current flowing from the stator winding toward the stator core. The offset current supply means is provided.

According to a second aspect of the present invention, there is provided a leakage current mitigation apparatus for electric equipment, wherein a potential fluctuation detecting means continuously detects a neutral point potential in a neutral line drawn from a motor.
A motor that detects a change in the potential of the neutral point of the stator winding of the motor is employed. According to a third aspect of the present invention, there is provided the leakage current reducing device for electric equipment, wherein the other ends of the resistance means having one end connected to the stator winding terminal of each phase of the motor are connected to each other as potential fluctuation detection means. The method of detecting the fluctuation of the potential at the neutral point of the stator winding of the motor by continuously detecting the potential at the point is adopted. Here, the resistance means means not only a resistance but also a coil,
It is used as a concept that also includes the impedance of a capacitor and the like.

According to a fourth aspect of the present invention, there is provided a leakage current mitigation apparatus for electric equipment, wherein a potential fluctuation detecting means continuously predicts a potential of a neutral point from preset waveform data in synchronization with a switching command to an inverter circuit. , Which detects fluctuations in the potential at the neutral point of the stator winding of the motor. According to a fifth aspect of the present invention, there is provided a leakage current reducing apparatus for an electric device which employs a DC power supply of a DC power supply section of an inverter circuit as an input and supplies a current in a direction for canceling a leakage current.

According to a sixth aspect of the present invention, there is provided a leakage current reducing device for an electric device which employs, as a canceling current supply means, a device including a transformer in which a primary winding is connected to a DC power supply of an inverter circuit. According to a seventh aspect of the present invention, there is provided a leakage current reducing device for an electric device, wherein a relative relationship between a DC voltage of a DC power supply unit of an inverter circuit and a ground voltage is detected as a canceling current supply means, In addition to compensating for the relative relationship to the voltage, a device that allows a current to flow in a direction to offset the leakage current is employed.

According to an eighth aspect of the present invention, there is provided a leakage current reducing apparatus for an electric appliance which includes a commercial AC power supply and a rectifier circuit as a power supply, and uses a commercial AC power supply unit and a rectifier circuit output side as offset current supply means. Continuity to detect conduction / non-conduction between
The present invention employs a device including a non-conduction detecting means and a current control means for controlling a current flowing in a direction to cancel a leakage current in response to a detection result of conduction / non-conduction.

According to a ninth aspect of the present invention, there is provided a leakage current mitigation apparatus for an electric device, wherein a neutral point of a capacitor connected to flow an unbalanced portion generated between wires to a ground terminal among noise currents generated from a motor; The current output terminals of the supply means are connected to each other and connected to a ground terminal.

[0022]

According to the first aspect of the present invention, when the electric device having the inverter circuit and the motor is connected to the power supply to operate the electric device, the stator winding of the motor is reduced. The fluctuation of the potential at the neutral point of the wire is detected by the potential fluctuation detecting means, and in response to the detected fluctuation of the potential at the neutral point, the canceling current supply means moves the stator from the stator winding toward the stator core. A current can be made to flow in a direction to offset the flowing leakage current. Therefore, leakage current flowing from the stator winding of the motor toward the stator core can be effectively reduced. Also, since the grounding voltage is not detected and a canceling current is applied, only the factory setting is required, and no on-site adjustment is required. In addition, regardless of the grounding conditions at the installation site (the grounding of electrical appliances) Leakage current can be effectively reduced.

According to a second aspect of the present invention, there is provided a leakage current reducing apparatus for an electric device, wherein a potential fluctuation detecting means continuously detects a neutral point potential in a neutral line drawn from the motor, thereby obtaining a stator winding of the motor. Since a device that detects a fluctuation in the potential at the neutral point is adopted, the same operation as in claim 1 can be achieved by applying the present invention to an electric device having a motor from which a neutral wire is drawn. .

According to a third aspect of the present invention, as a leakage current mitigation device for electric equipment, the other end of the resistance means having one end connected to the stator winding terminal of each phase of the motor is connected to each other as potential fluctuation detecting means. A motor that detects potential fluctuations at the neutral point of the stator winding of the motor by continuously detecting the potential at the connection point between the resistance means is adopted. The present invention can be applied to an electric device having the same, and can achieve the same operation as the first aspect.

According to a fourth aspect of the present invention, a potential fluctuation detecting means predicts a potential at a neutral point from preset waveform data in synchronization with a switching command to an inverter circuit. By continuing, the one that detects the fluctuation of the potential of the neutral point of the stator winding of the motor is adopted, so that the fluctuation of the potential of the neutral point of the stator winding of the motor is not actually detected. The same operation as the first aspect can be achieved.

In the leakage current reducing device for an electric device according to the present invention, a device for supplying a current in a direction to cancel a leakage current by using a DC power supply of a DC power supply unit of an inverter circuit as an input is adopted as a canceling current supply means. Therefore, the same operation as in claim 1 can be achieved without using a special power supply for supplying a canceling current. According to the leakage current reducing device for an electric device of the present invention, a device including a transformer having a primary winding connected to a DC power supply unit of an inverter circuit is adopted as a canceling current supply unit. The same operation as in claim 5 can be achieved only by employing a transformer without using a special power supply for supplying current.

According to a seventh aspect of the present invention, as the offset current supply device, the relative relationship (coupling state) of the DC voltage of the DC power supply unit to the ground voltage is detected as the canceling current supply means. Compensating the relative relationship of the DC voltage of the DC power supply to the ground voltage,
Since the current flowing in the direction to cancel the leakage current is employed, the leakage current can be further reduced in addition to the effect of the fifth aspect.

In the leakage current reducing apparatus for an electric device according to the present invention, a power supply including a commercial AC power supply and a rectifier circuit is adopted as a power supply, and a commercial AC power supply unit and a rectifier circuit output side are used as offset current supply means. A conduction / non-conduction detection means for detecting conduction / non-conduction between the control means and a current control means for controlling a current flowing in a direction to offset a leakage current in response to a detection result of conduction / non-conduction. Since this is adopted, in addition to the function of any one of claims 5 to 7, it is possible to prevent the occurrence of the disadvantage that a current flows more than necessary during a period in which the rectifying circuit element is non-conductive, and to reduce the leakage current. Can be reduced.

In the leakage current reducing device for an electric device according to the ninth aspect, of the noise current generated from the motor, a neutral point of a capacitor connected to flow an unbalanced portion generated between lines to a ground terminal; Since the current output terminals of the canceling current supply means are connected to each other and connected to the ground terminal,
In addition to the function of any one of claims 1 to 8, even when the ground of the ground terminal is incomplete, the connection line to the neutral point of the capacitor functions as a pseudo ground line, and the leakage current Can be effectively reduced.

This will be described in more detail with reference to the schematic diagram shown in FIG. Between the winding of the motor and the stator core, a voltage of + or-applied to each phase (neutral point potential) V ±,
Fluctuation of the ground voltage of the positive and negative electrodes (DC pole potential)
It takes the sum of Ve. Therefore, the leakage current between the winding of the motor and the stator core occurs in proportion to this sum voltage.

Of these, the current of each phase is neutralized in the stator core, and thus apparently approximates a so-called neutral point voltage. Further, the voltage fluctuation of each pole of the DC power supply occurs during the rectification of the AC power supply and is determined during the conduction time period, but is undefined during the non-conduction time period, and this time period is rather an absorption impedance of the voltage V ±. Works. This is clear from the actual leakage current waveform shown in FIG. In FIG. 23, the portion where the current amplitude is reduced is a period during which the rectifying element is non-conductive. During the non-conductive period, the relative relationship between the rectifying element and the grounding portion behaves as if an impedance is inserted in the middle. That is, it is considered that these voltages leak to the housing via the impedance of the motor.
Therefore, a means for predicting or detecting the neutral point potential is provided, and the current flowing through the diode at the time of AC-DC conversion is predicted, and if an appropriate conversion is applied thereto, the current that should cancel the leakage current can be obtained. Can occur. Further, in the case where the outer skin of the motor or the device driven by the motor is made of a conductor, a leakage current can be reduced by applying a canceling current to the outer skin. FIG. 18 is a diagram showing an example of the neutral point potential, and it can be seen that the envelope is a sine wave representing the back electromotive force of the motor. FIG. 19A is a diagram showing an example of a change in voltage (potential difference) between the negative side of the output of the rectifier circuit and one line of the input of the rectifier circuit, and FIG. It is a figure showing an example of change of the voltage (potential difference) between the minus side of the output of a rectifier circuit, and the other input line of a rectifier circuit. In FIGS. 19A and 19B, a portion having no potential difference is a period during which the rectifying element is conductive, and a portion having a potential difference is a period during which the rectifying element is non-conductive. In the latter period, the neutral point voltage applied to the inverter motor has a form in which one of the poles is partially insulated. During this period, the generation of leakage current of low frequency components is particularly small. Therefore, based on this situation, it is necessary to perform control during this time to reduce the canceling current. As can be seen from FIGS. 19A and 19B, the non-conducting period of the rectifying element accounts for a large proportion of the whole, and in FIG. 19 it is about one third or more of the whole. Also, it becomes larger as the number of rotations of the motor becomes lower. By the way, in the case of an air conditioner, etc., the leakage current is higher at low rotation,
It is important to control the canceling current as described above.

The present invention has been made in view of the above points. In the case of an inverter motor, a program for generating a chopping waveform is stored in a microcomputer in advance in order to make a waveform appear. The waveform of the neutral point potential and the conduction waveform at the time of rectification are also stored in the microcomputer, and when the waveform information is output to the waveform generating unit (inverter), the canceling current information is output to the canceling current generating unit to cancel the current. Is adopted. Further, when a motor having a neutral wire is employed, an output from the neutral wire is supplied as an information source to a canceling current generator to generate a canceling current. Further, when any of the above configurations cannot be realized or is difficult to realize, for example, one terminal of a high impedance element is connected to each phase of the input line from the inverter to the motor, and the other is connected. Are connected to each other to create a pseudo-neutral point, an output from the pseudo-neutral point is supplied as an information source to a canceling current generating unit, and a canceling current can be generated. . Here, regarding the pseudo neutral point, by adjusting the impedance in response to the voltage fluctuation of the neutral point and the ratio of the frequency component, the pseudo neutral point approximating the neutral point potential related to the actual leakage current is obtained. It can be a neutral point potential.

However, regarding the latter two, the DC electrode (+
It is preferable to detect the fluctuation of the voltage of (pole or -pole) by a separate method and reflect it in the canceling current. Also, regarding the generation of the canceling current, the + pole of the DC power supply of the inverter or the-
The potential from the poles is not neutralized at the neutral point of the motor,
Considering that a leakage current is generated due to an instantaneous fluctuation, a canceling current may be created using this DC power supply as a source. Specifically, the magnitude and the waveform of the leakage current are reproduced based on the above-described detection method, and the phase is reversed to generate a canceling current.

By doing so, a canceling current is generated, and the leaking current can be canceled by flowing the canceling current through the stator core of the motor or the outer skin that comes into contact with the stator iron core, and thus the floating capacitance can be eliminated. In addition, it is possible to sufficiently reduce leakage current through conductivity via a refrigerant, a refrigerating machine oil, or the like. Further, since the present invention does not detect the ground voltage and generate the canceling current, even if the grounding for the appliance is not always perfect, for example, as in the current situation in Japan, the leakage current may be reduced. The danger caused by the current can be sufficiently reduced.

[0035]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is an electric circuit diagram showing an electric equipment control system incorporating one embodiment of the leakage current reduction device of the present invention.

This electric equipment control system includes an AC power supply 1
Full-wave rectifier circuit 2 is connected between output terminals of
To create a DC power supply for the inverter. Then, the output voltage of each phase of the three-phase inverter 4 to which the DC power is input is applied to the stator winding of each phase of the three-phase motor 5. Further, a displacement of the neutral point potential with respect to the housing potential obtained by the neutral point potential lead wire 7a drawn from the neutral point of the stator winding of the three-phase motor 5 is detected, and the displacement is responded to this displacement. Using a DC power supply for an inverter as an input, a canceling current generating device 9 generates a canceling current to cancel a leakage current flowing into the case 8 and supplies the canceling current to the case 8.

FIG. 2 is an electric circuit diagram showing an electric equipment control system incorporating another embodiment of the leakage current reducing device of the present invention. In this electric equipment control system, a full-wave rectifier circuit 2 is connected between output terminals of an AC power supply 1 and smoothed by a capacitor 3 to create a DC power supply for an inverter. Then, the output voltage of each phase of the three-phase inverter 4 to which the DC power is input is applied to the stator winding of each phase of the three-phase motor 5. Further, the terminal voltage of the stator winding of the three-phase motor 5 is supplied to the pseudo neutral point potential detecting device 7 to detect the displacement of the pseudo neutral point potential with respect to the casing potential, and respond to this displacement. And a DC power supply for the inverter as an input,
A canceling current generating device 9 generates a canceling current for canceling the leakage current flowing to the housing 8 and supplies the canceling current to the housing 8.

In any of the embodiments, the displacement of the neutral point potential with respect to the housing potential may be actually detected. However, the waveform of the neutral point potential and the rectification time during rectification are supplied to a control microcomputer or the like. A conduction waveform or the like may be stored, and the displacement of the neutral point potential with respect to the housing potential may be detected by performing prediction or the like from the stored data. FIG. 3 is a block diagram illustrating an example of a specific configuration of the canceling current generation device 9.

The canceling current generator 9 includes a microcomputer 9a in which not only the data for the chopping waveform but also the data for the canceling current waveform optimized in advance is set, and the canceling current waveform output from the microcomputer 9a. And a pair of digital-analog converters (hereinafter abbreviated as D / A converters) 9b and 9c for converting data for use into analog data.
An inverting amplifier 9d for amplifying the analog data output from the / A converter 9b and inverting the polarity, and a D / A
An amplifier 9e for amplifying analog data output from the converter 9c, a photocoupler 9f controlled by an output signal from the inverting amplifier 9d, a photocoupler 9g controlled by an output signal from the amplifier 9e, and a photocoupler 9g.
f, an impedance element (for example, a resistor or a capacitor) 9h having one terminal connected to each of the + and-poles of the DC power supply via the photocoupler 9g and the other terminal connected to the housing 8; Have.

When this configuration is adopted, when outputting the data for the chopping waveform, the data for the canceling current waveform is output from the microcomputer 9a, converted into analog data, and connected to the negative pole of the DC power supply. The photocoupler 9g is controlled by the analog data, and the photocoupler 9f connected to the + pole of the DC power supply is controlled by the inverted analog data. Therefore, the leakage current flowing through the housing 8 is transferred to the photocoupler 9f and the photocoupler 9f.
g, the offset is canceled by the offset current flowing through the impedance element 9h, and the leakage current can be sufficiently reduced.

In addition, since this configuration does not detect the ground voltage and supply the offset current, it is possible to achieve a good leakage current reduction effect without being affected by the grounding state of the electric device. FIG. 4 is an electric circuit diagram showing an electric device control system in which another example of the specific configuration of the canceling current generator 9 is incorporated.

The canceling current generator 9 includes a three-phase motor 5
The neutral point potential of the stator winding is directly supplied as a control signal to one terminal of the light emitting portion of the photocoupler 9f and the photocoupler 9g. While being connected to the housing 8 via the impedance element 9h, the other terminals of the light receiving portions of the photocouplers 9f and 9g are connected to the positive and negative poles of the DC power supply, respectively. And the photo coupler 9
f, the other terminal of the light emitting portion of the photocoupler 9g is connected to the positive and negative poles of the DC power supply via the resistors 9i and 9j, respectively. Further, the input current of the full-wave rectifier circuit 2 is detected by the current detector 10, and the impedance of the impedance element 9h is controlled.

When this configuration is employed, the offset current can be generated by directly controlling the photocouplers 9f and 9g by the neutral point potential which is a source of the leakage current. Since the input current of the full-wave rectifier circuit 2 is detected by the current detector 10 and the impedance of the impedance element 9h is controlled, the magnitude of the canceling current can be controlled, and the leakage current can be sufficiently reduced. The effect can be achieved.

Of course, this configuration does not detect the ground voltage and supply a canceling current, so that a good leakage current reduction effect can be achieved without being affected by the grounding state of the electric equipment. FIG. 5 is an electric circuit diagram showing an electric equipment control system in which still another example of the specific configuration of the canceling current generator 9 is incorporated.

The canceling current generator 9 includes a three-phase motor 5
A resistor 9k having one terminal connected to the stator winding terminal of
The other terminals of 9l and 9m are connected to each other to obtain a pseudo neutral point potential, and this pseudo neutral point potential is directly supplied as a control signal to one terminal of the light emitting portions of the photocouplers 9f and 9g. Then, photo coupler 9f, photo coupler 9g
The other terminal of the light emitting unit is connected to the connection point between the resistors 9i and 9j connected in series between the + pole and the-pole of the DC power supply, and is connected to the housing 8 via the impedance element 9h. Connected. Also, the photo coupler 9f,
Resistors 9n and 9o connected in parallel to the light receiving portion of the photocoupler 9g are connected in series between the + and-poles of the DC power supply, and a capacitor is provided between the connection point of the resistors 9n and 9o and the housing 8. 9p is connected.

When this configuration is employed, the photocouplers 9f and 9g are directly controlled by a pseudo-neutral potential which can be approximated to a neutral potential which is a source of a leakage current to generate a canceling current. be able to. Since the values of the positive and negative voltages of the DC power supply with respect to the voltage of the housing 8 are reflected on the control conditions of the light emitting units of the photocouplers 9f and 9g by the impedance element 9h, the magnitude of the canceling current is large. Can be controlled, and a sufficient leakage current reduction effect can be achieved.

Of course, this configuration does not detect the ground voltage and supply a canceling current, so that a good leakage current reducing effect can be achieved without being affected by the grounding state of the electric equipment. FIG. 6 is an electric circuit diagram showing still another example of the specific configuration of the canceling current generation device 9.

The canceling current generator 9 is a three-phase motor 5
A resistor 9k having one terminal connected to the stator winding terminal of
The other terminals of 9l and 9m are connected to each other to obtain a pseudo neutral point potential, and this pseudo neutral point potential is directly supplied as a control signal to one terminal of the light emitting portions of the photocouplers 9f and 9g. At the same time, the other terminals of the light emitting portions of the photocouplers 9f and 9g are both connected to the +
It is connected to a connection point between the resistors 9i and 9j connected in series between the pole and the minus pole. Also, the photo coupler 9f,
One terminal of the light emitting portion of the photocoupler 9g is connected to the housing 8 via the impedance element 9h, and the other terminal is connected to the positive and negative poles of the DC power supply, respectively. Further, the input current of the full-wave rectifier circuit is detected by a current detector, and the impedance of the impedance element 9h is controlled.

When this configuration is adopted, a canceling current is generated by directly controlling the photocouplers 9f and 9g by a pseudo neutral point potential which can be approximated to a neutral point potential which is a source of a leakage current. be able to. Since the input current of the full-wave rectifier circuit is reflected by the impedance element 9h on the control conditions of the light emitting portions of the photocouplers 9f and 9g, the magnitude of the canceling current can be controlled, and sufficient leakage can be achieved. A current reduction effect can be achieved.

Of course, this configuration does not detect the ground voltage and supply a canceling current, so that a good leakage current reduction effect can be achieved without being affected by the grounding state of the electric equipment. FIG. 7 is an electric circuit diagram showing an example of a configuration for supplying a canceling current to the housing.

In this configuration, the canceling current is supplied to the housing 8 via the capacitor 9q. Therefore,
By supplying a canceling current excluding low frequency components to the housing 8, a sufficient leakage current reducing effect can be achieved. FIG. 8 is an electric circuit diagram showing another example of the configuration for supplying the canceling current to the housing.

In this configuration, the canceling current is supplied from the negative pole of the DC power supply to the housing 8 via the secondary winding of the transformer 9r and the capacitor 9q in series. In addition,
The primary winding of the transformer 9r is connected to, for example, a neutral point, a pseudo neutral point, or the like. Therefore, a change in neutral point potential, pseudo neutral point potential, or the like with respect to the negative electrode voltage of the DC power supply is supplied to the housing 8 to reduce leakage current.

FIG. 9 is an electric circuit diagram showing still another example of a configuration for supplying a canceling current to the housing. In this configuration, a primary winding of a transformer 10a is provided to detect a charging current to a DC power supply unit including a full-wave rectifier circuit 2 and a capacitor 3, and a full-wave is connected between terminals of a secondary winding of the transformer 10a. The rectifier circuit 10b is connected, and the full-wave rectifier circuit 10b
The light emitting part of the photocoupler 10c is connected between the output terminals of
The light receiving section of the photocoupler 10c is connected in series to the final stage of the current output from the neutral point of the three-phase motor 5.

Therefore, when this configuration is employed, the charging current to the DC power supply is detected and the photocoupler 1 is detected.
0c, and thus the current output from the neutral point can be controlled to achieve good leakage current reduction. FIG.
FIG. 9 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

This electric equipment control system is different from the electric equipment control system of FIG.
A pair of resistors 16 are connected in series, and a primary winding of a transformer 17 is connected between an output terminal of the pseudo-neutral potential detecting device 7 and a connection point between the resistors 16. The only difference is that the winding is connected between the housing 8 and the ground terminal.

When this configuration is employed, for example, a current flowing from the output terminal of the pseudo-neutral potential detecting device 7 to the connection point between the resistors 16 flows through the primary winding of the transformer 17. A voltage is generated in the secondary winding of the transformer 17, and a current determined by the generated voltage flows between the housing 8 and the ground terminal. Then, the leakage current is canceled by the current flowing between the housing 8 and the ground terminal by the secondary winding of the transformer 17, and a sufficient leakage current reduction effect can be achieved.

FIG. 11 is a current waveform diagram showing an example of the effect of reducing the leakage current due to the provision of the transformer 17. 11A shows the output current I1 caused by the current flowing through the primary winding of the transformer 17, FIG. 11B shows the leakage current I2, and FIG. The leakage current after the operation is shown. As is apparent from FIG. 11B, a considerably large leakage current I2 originally flowed. However, the provision of the transformer 17 allows the output current I1 between the housing 8 and the ground terminal.
, The leakage current can be sufficiently reduced, and a sufficient leakage current reduction effect can be achieved as shown in FIG.

FIGS. 12 and 13 are electric circuit diagrams showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention. The difference between these electric device control systems and the electric device control systems shown in FIGS.
The point that a detection circuit 11 for detecting conduction / non-conduction between the pole and both input terminals of the full-wave rectifier circuit 2 is provided, and the conduction / non-conduction detection result is also inputted as the canceling current generator 9 as an input. The only difference is that a device that generates a current is employed.

FIGS. 14 and 15 are electric circuit diagrams showing equivalent circuits of the main circuit of the electric equipment control system corresponding to the conducting state and the non-conducting state of the full-wave rectifier circuit 2. FIG. In the conductive state, the connection between the three-phase motor 5 and the housing 8 is connected via the stray capacity and the conductivity (resistance) via the refrigerant, the refrigerating machine oil and the like, and also connected to the three-phase motor 5. The neutral potential generating circuit (inverter circuit 4) and the ground terminal on the AC power supply side are directly connected.

Conversely, in the non-conducting state, the three-phase motor 5 and the housing 8 are connected via the stray capacity and the conductivity (resistance) via the refrigerant, the refrigerating machine oil, etc. The neutral potential generating circuit (inverter circuit 4) connected to the phase motor 5 and the ground terminal on the AC power supply side are connected via a capacitance which is considered to be caused by a depletion layer of a rectifying diode.

By alternately realizing the equivalent circuits shown in FIGS. 14 and 15 in this manner, as shown in FIG. 23, a leakage current having an extremely small amplitude is actually generated corresponding to the non-conductive state. When the detection circuit 11 detects the potential difference between the negative electrode of the output terminals of the full-wave rectification circuit 2 and the two input terminals of the full-wave rectification circuit 2, the detection circuit 11 becomes as shown in FIGS. The detection results shown.
A non-conductive state and a conductive state can be detected by the presence or absence of a potential difference. Since it is known that the amplitude of the leakage current is significantly reduced in response to the non-conducting state, the canceling current generator 9 cancels the leakage current in response to the detection result by the detection circuit 11. By controlling the magnitude of the canceling current, the leakage current can be canceled accurately.

However, instead of providing a circuit for actually detecting the conduction state and the non-conduction state, the microcomputer stores the conduction state and the non-conduction state in a memory, and controls the canceling current based on the memory contents of the microcomputer. It may be. This will be described in more detail. When the configuration shown in FIG. 22 is employed, a canceling current command is generated by extracting and processing the switching signals for three phases. Further, the DC power supply section starts, and generates a canceling current irrespective of the relative relationship between each pole of the DC power supply and the ground voltage. However, since the actual leakage current occurs due to the relationship between the neutral point voltage applied to the load and the ground voltage, FIG.
When the configuration shown in (1) is adopted, more than necessary canceling current flows during a period when the rectifying element is non-conductive (see a period during which the leakage current amplitude is small in FIG. 23). Further, Japanese Unexamined Patent Publication No.
Japanese Patent No. 233837 also proposes to detect a leakage current as a cancellation result and feed back the detection result. However, since the detection of the leakage current is achieved by detecting a high-frequency component flowing between the motor frame and one of the poles of the DC power supply, for example, a motor frame such as a general air conditioner is used. If it is connected to ground, it is monitoring the current flowing between one pole of the DC power supply and ground, and is only applicable when there is no ground and the ground is incomplete. Will be. Therefore, the detection amount varies depending on the grounding state, the leak current detection function is incomplete, and a sufficient feedback effect cannot be expected. As a result, the leakage current cannot be sufficiently offset.

On the other hand, if the configurations shown in FIGS. 12 and 13 are adopted, the conduction / non-conduction of the rectifying element of the full-wave rectifier circuit 2 is detected to control the canceling current. Can be prevented, and the leakage current can be sufficiently canceled. FIG. 16 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

This electric equipment control system is different from the electric equipment control system of FIG. 2 in that an AC power supply line is connected to output terminals of each phase of an AC power supply via a common mode choke 12 so that an AC power supply is provided. Between the lines, an X capacitor 13 that absorbs the balance of the noise current generated between the lines together with the common mode choke 12 is connected, and the X capacitor 13 is connected between the AC power supply line of each phase and the ground terminal 15 and is not connected. It is only the point where the Y capacitor 14 for flowing the equilibrium component is connected, and the point where the output terminal of the canceling current generator 9 and the connection point between the Y capacitors 14 are directly connected.

When this embodiment is adopted, even when the grounding of the grounding terminal 15 is incomplete, the line connecting the connection point between the Y capacitors 14 and the output terminal of the canceling current generator 9 is not required. It functions as a substitute for the ground wire, and can achieve a sufficient leakage current reduction effect. Of course, when the grounding of the ground terminal 15 is perfect, a sufficient leakage current reduction effect can be achieved by flowing a canceling current through the ground terminal 15.

This configuration can be similarly applied to the other embodiments described above.

[0067]

According to the first aspect of the present invention, the leakage current flowing from the stator winding of the motor toward the stator core can be effectively reduced, and the canceling current flows by detecting the ground voltage. This is not the case, so only the settings at the factory need not be adjusted at the site, and the unique effect that the leakage current can be effectively reduced regardless of the grounding conditions at the installation site is exhibited. .

The second aspect of the invention has the same effect as the first aspect by being applied to an electric apparatus having a motor from which a neutral wire is drawn. The invention of claim 3 can be applied to an electric device having a motor from which a neutral wire is not drawn, and has the same effect as that of claim 1. Claim 4
The present invention has the same effect as that of the first aspect without actually detecting the fluctuation of the potential at the neutral point of the stator winding of the motor.

According to the fifth aspect of the invention, the same effects as those of the first aspect can be obtained without using a special power supply for supplying a canceling current. The invention of claim 6 has the same effect as that of claim 5 only by employing a transformer without using a special power supply for supplying a canceling current. The invention of claim 7 has a unique effect that the leakage current can be further reduced in addition to the effect of claim 5.

The invention according to claim 8 is the invention according to claims 5 to 7.
In addition to the effect of any one of the above, it is possible to prevent a disadvantage that a current flows more than necessary during a period in which the rectifying circuit element is non-conductive, and to achieve a unique effect that a leakage current can be effectively reduced. . According to the ninth aspect of the present invention, in addition to the effect of any one of the first to eighth aspects, even when the ground of the ground terminal is incomplete, the connection line to the neutral point of the Y capacitor is pseudo. It functions as a ground line, and has a unique effect that leakage current can be effectively reduced.

[Brief description of the drawings]

FIG. 1 is an electric circuit diagram showing an electric equipment control system incorporating one embodiment of a leakage current reduction device of the present invention.

FIG. 2 is an electric circuit diagram showing an electric equipment control system incorporating another embodiment of the leakage current reducing device of the present invention.

FIG. 3 is a block diagram illustrating an example of a specific configuration of the canceling current generation device.

FIG. 4 is an electric circuit diagram showing an electric device control system incorporating another example of the specific configuration of the canceling current generation device.

FIG. 5 is an electric circuit diagram showing an electric device control system in which still another example of the specific configuration of the canceling current generation device is incorporated.

FIG. 6 is an electric circuit diagram showing still another example of a specific configuration of the canceling current generator.

FIG. 7 is an electric circuit diagram showing an example of a configuration for supplying a canceling current to a housing.

FIG. 8 is an electric circuit diagram showing another example of a configuration for supplying a canceling current to a housing.

FIG. 9 is an electric circuit diagram showing still another example of the configuration for supplying the canceling current to the housing.

FIG. 10 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

FIG. 11 is a current waveform diagram showing an example of a leakage current reduction effect provided by providing a transformer.

FIG. 12 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

FIG. 13 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

FIG. 14 is an electric circuit diagram showing an equivalent circuit of a main circuit of the electric device control system corresponding to a conduction state of the full-wave rectifier circuit.

FIG. 15 is an electric circuit diagram showing an equivalent circuit of a main circuit of the electric device control system corresponding to a non-conductive state of the full-wave rectifier circuit.

FIG. 16 is an electric circuit diagram showing an electric equipment control system incorporating a further embodiment of the leakage current reducing device of the present invention.

FIG. 17 is a schematic diagram illustrating generation of a leakage current.

FIG. 18 is a diagram illustrating an example of a neutral point potential.

FIG. 19 is a diagram illustrating an example of a detection result of a potential difference between a negative pole among output terminals of the full-wave rectifier circuit and both input terminals of the full-wave rectifier circuit.

FIG. 20 is an electric circuit diagram showing an example of a conventional leakage current reduction device for electric equipment.

FIG. 21 is an electric circuit diagram showing another example of the conventional leakage current reduction device for electric equipment.

FIG. 22 is an electric circuit diagram showing still another example of the conventional leakage current reduction device for electric equipment.

FIG. 23 is a diagram showing an example of an actual leakage current waveform.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 AC power supply 4 Three-phase inverter circuit 5 Three-phase motor 7 Pseudo neutral point potential detection device 8 Housing 9 Cancellation current generation device 9a Microcomputer 9k, 9l, 9m Resistance 10a Transformer 11 Detection circuit 14 Y capacitor 15 Ground terminal

Claims (9)

[Claims] An electric device having an inverter circuit (4) and a motor (5) is connected to a power source (1) (2), and a potential of a neutral point of a stator winding of the motor (5) is measured. Potential fluctuation detecting means (7), (7a), (9a) for detecting fluctuation are provided, and a leakage current flowing from the stator winding toward the stator core in response to the detected fluctuation of the potential at the neutral point is provided. A leakage current reduction device for electric equipment, comprising a canceling current supply means (9) for flowing a current in a canceling direction. 2. A potential fluctuation detecting means (7a) continuously detects a neutral point potential in a neutral line drawn from the motor (5), thereby detecting a neutral point of a stator winding of the motor (5). 2. The leakage current reducing device for an electric device according to claim 1, wherein the device detects a fluctuation in the potential of the electric device. 3. The potential fluctuation detecting means (7) connects the other ends of the resistance means (9k), (91) and (9m) each having one end connected to a stator winding terminal of each phase of the motor (5). And
2. The method according to claim 1, further comprising: detecting a potential change at a neutral point of a stator winding of the motor (5) by continuously detecting a potential at a connection point between the resistance means (9k), (91) and (9m). 3. The leakage current reducing device for an electric device according to claim 1. 4. The potential fluctuation detecting means (9a) continuously predicts the potential of the neutral point from preset waveform data in synchronization with a switching command to the inverter circuit (4), so that the motor (5) 2. The leakage current mitigation apparatus for electric equipment according to claim 1, wherein the fluctuation of the potential at the neutral point of the stator winding is detected. 5. The electric apparatus according to claim 1, wherein the canceling current supply means (9) receives a DC power supply of a DC power supply section of the inverter circuit (4) as an input and flows a current in a direction to cancel a leakage current. Leakage current reduction device. 6. The canceling current supply means (9) includes a transformer (10a) having a primary winding connected to a power supply of a DC power supply section of the inverter circuit (4).
3. The leakage current reducing device for an electric device according to claim 1. 7. The canceling current supply means (9) also detects a relative relationship between the DC voltage of the DC power supply of the inverter circuit (4) and the ground voltage, and detects the relative relationship of the DC voltage of the DC power supply of the inverter circuit (4). 6. The leakage current reduction device for an electric device according to claim 5, wherein a current is caused to flow in a direction to cancel a leakage current while compensating a relative relationship with respect to a ground voltage. 8. A power supply (1) (2) includes a commercial AC power supply (1) and a rectifier circuit (2), and a canceling current supply means (9) is provided between a commercial AC power supply unit and a rectifier circuit output side. Conduction / non-conduction detection means (11) for detecting conduction / non-conduction between
The electric device according to any one of claims 5 to 7, further comprising current control means (9) for controlling a current flowing in a direction to cancel a leakage current in response to a detection result of conduction / non-conduction. Leakage current reduction device. 9. A neutral point of a capacitor (14) connected to allow an unbalanced portion generated between lines to flow to a ground terminal among noise currents generated from a motor (5), and a canceling current supply means (9). 9. The leakage current mitigation device for an electric device according to claim 1, wherein the current output terminals are connected to each other and connected to a ground terminal.