JP2008245037A - Noise filter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To ensure a bypass path for a high-frequency components, while enhancing the damping characteristics for noise component which is in a band of a self-resonance frequency or higher of a common-mode reactor. <P>SOLUTION: A common-mode reactor CL11 is provided in a noise filter, and also series circuits in which capacitors C11 to C13 are respectively series-connected to reactors L14 to L16 are provided; and these series circuits are respectively connected to between a power supply line for supplying a three-phase voltage and the grounding. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a noise filter, and is particularly suitable for application to a noise filter used in a power conversion circuit.

In motor drive systems using inverters, a noise filter may be connected in front of the inverter to prevent noise associated with switching operations from flowing into the power supply and malfunctioning of electrical equipment connected to the same system. Has been done.
FIG. 11 is a circuit diagram showing a schematic configuration of a motor drive system using an inverter including a conventional noise filter.

In FIG. 11, the motor drive system is provided with a power supply G for supplying a three-phase voltage, an inverter IV, and a motor M. A noise filter F111 is connected to the front stage of the inverter IV and a power supply for supplying a three-phase voltage. Between the supply lines, delta-connected line capacitors C111 to C113 are respectively connected. Further, the inverter IV is provided with a rectifier 141 that rectifies the three-phase voltage, and a switching element 142 that performs a switching operation on the output from the rectifier 141 and converts it into an alternating voltage.
Here, the noise filter F111 is provided with capacitors C114 to C116 and a common mode reactor CL111 that respectively ground the power supply lines that supply the three-phase voltages.

The three-phase voltage supplied from the power supply G is supplied to the inverter IV via the noise filter F111, rectified by the rectifier 141, and then converted into a voltage having a desired frequency and amplitude by the switching element 142. And supplied to the motor M. In accordance with the switching operation of the switching element 142, the high-frequency current flows into the power supply line and the ground line AL that supply the three-phase voltage through the stray capacitance of each part.
Here, for the high-frequency current flowing into the power supply G side through the power supply line that supplies the three-phase voltage, a bypass path is formed by the line capacitors C111 to C113, and the power supply G is generated by the leakage inductance component of the common mode reactor CL111. By increasing the impedance on the side, the outflow to the power supply G side can be prevented.

For the high-frequency current flowing into the power supply G side through the ground wire AL, a bypass path is formed by the capacitors C114 to C116, and the impedance on the power supply G side is increased by the common mode reactor CL111. Can be prevented from flowing out.
In order to increase the attenuation amount of the noise filter, a multi-stage configuration of line capacitors C111 to C113 and a common mode reactor CL111 may be used (Patent Document 1).

FIG. 12 is a circuit diagram showing a three-stage configuration of the noise filter of FIG.
In FIG. 12, the noise filter is provided with three-phase input terminals T1 to T3 and three-phase output terminals T4 to T6, and is configured by three coils L1 to L3, L4 to L6, and L7 to L9, respectively. And the line capacitors C1 to C3, C4 to C6, and C7 to C9 constitute a noise filter. The power supply lines for supplying the three-phase voltage are grounded by capacitors C121 to C123.

For the high-frequency current flowing into the power supply side through the power supply line that supplies the three-phase voltage, a bypass path is formed by the line capacitors C1 to C3, C4 to C6, and C7 to C9, and the leakage inductance of the common mode reactor By increasing the impedance on the power supply side by the component, it is possible to prevent outflow to the power supply side.
As for the high-frequency current flowing into the power supply through the ground wire, a bypass path is formed by the capacitors C121 to C123, and the impedance on the power supply side is increased by the coils L1 to L3, L4 to L6, and L7 to L9. The outflow to the power source side can be prevented.

FIG. 13 is a circuit diagram showing another example of a conventional noise filter.
In FIG. 13, the noise filter is provided with a common mode reactor CL131, and the common mode reactor CL131 is provided with coils L131 to L133 connected in series to a power supply line for supplying a three-phase voltage. Further, star-connected line capacitors C131 to C133 are respectively connected to the power supply lines for supplying the three-phase voltage, and a grounding capacitor C134 is connected between the neutral point and the ground.

For the high-frequency current flowing into the power supply side through the power supply line for supplying the three-phase voltage, a bypass path is formed by the line capacitors C131 to C133, and the impedance on the power supply side is determined by the leakage inductance component of the common mode reactor CL131. Can be prevented from flowing out to the power source side.
In addition, a high-frequency current flowing into the power supply side through the ground wire is prevented from flowing out to the power supply side by forming a bypass path with the capacitor C134 and increasing the impedance on the power supply side with the common mode reactor CL131. Can do.

Then, by connecting the ground capacitor C134 between the neutral point of the star-connected line capacitors C131 to C133 and the ground, it is possible to prevent the capacitance of the ground capacitor C134 from varying and to supply power for supplying a three-phase voltage. It can function as a bypass path for the high-frequency current flowing into the power supply side through the line.
Here, as shown in FIG. 14, the self-resonant frequency of the common mode reactor used for measures against low frequencies (about 150 kHz to 1 MHz) is set to a lower band by the self-resonant frequency of the capacitor. For this reason, the attenuation characteristic as set in the noise filter is obtained in a region below the self-resonant frequency of the common mode reactor.
Japanese Patent No. 2585141

However, since the capacitor does not act as a capacitive component above the self-resonant frequency, the bypass effect is reduced at frequencies above that. On the other hand, since the common mode reactor also does not act as an inductive component above the self-resonant frequency, a high-frequency current flows out to the power source side at a frequency higher than that.
For this reason, in the method disclosed in Patent Document 1, when the resonance peak of the noise frequency spectrum is in a band equal to or higher than the self-resonance frequency of the common mode reactor, it is difficult to suppress the noise peak below the regulation value. There was a problem that there was.
Accordingly, an object of the present invention is to provide a noise filter capable of improving the attenuation characteristics for noise components in a band equal to or higher than the self-resonant frequency of the common mode reactor while ensuring a bypass path for high-frequency components. .

  In order to solve the above-described problem, according to the noise filter according to claim 1, at least one common mode reactor connected to the power supply line of the power conversion circuit, and connected between the power supply line and the ground. A series circuit including at least one set of capacitors and a reactor is provided, and a resonance frequency of the series circuit is set to be equal to or higher than a self-resonance frequency of the common mode reactor and in the vicinity of a noise peak.

  According to the noise filter of claim 2, at least one common mode reactor connected to the power supply line of the power conversion circuit, and at least one set of first capacitors connected between the power supply line and the ground. And a second capacitor connected in parallel to the series circuit, wherein the resonance frequency of the series circuit is set to be equal to or higher than the self-resonance frequency of the common mode reactor and near the noise peak. The second capacitor is a capacitor exhibiting capacitance at least in a noise regulation frequency band.

  According to the noise filter of claim 3, at least one common mode reactor connected to the power supply line of the power conversion circuit and at least one set connected to at least one phase between the power supply line and the ground. A series circuit comprising a first capacitor and a reactor, and a second capacitor connected to at least one remaining phase between the power supply line and the ground, wherein the resonance frequency of the series circuit is the self-mode of the common mode reactor. The second capacitor is set to a frequency equal to or higher than a resonance frequency and close to a noise peak, and the second capacitor is a capacitor exhibiting capacitance at least in a noise regulation frequency band.

  According to a fourth aspect of the present invention, the noise filter includes at least one common mode reactor connected to the power supply line of the power conversion circuit, and at least one capacitor connected between the power supply line and the ground. The self-resonant frequency of the capacitor is set to be equal to or higher than the self-resonant frequency of the common mode reactor.

  According to the noise filter of claim 5, at least one common mode reactor connected to the power supply line of the power conversion circuit, and at least one first capacitor connected between the power supply line and the ground, A second capacitor connected in parallel to the first capacitor, wherein the self-resonant frequency of the first capacitor is set to be equal to or higher than the self-resonant frequency of the common mode reactor and near the noise peak, The capacitor is characterized by using a capacitor exhibiting capacitance at least in a noise regulation frequency band.

  According to the noise filter of claim 6, at least one common mode reactor connected to the power supply line of the power conversion circuit, and at least one phase connected to at least one phase between the power supply line and the ground. A first capacitor and a second capacitor connected to at least one remaining phase between the power supply line and ground, wherein the self-resonant frequency of the first capacitor is equal to or higher than the self-resonant frequency of the common mode reactor; The second capacitor is set to a frequency in the vicinity of a noise peak, and a capacitor exhibiting a capacitive property is used at least in a noise regulation frequency band.

  As described above, according to the present invention, it is possible to form a bypass path for a noise component in a band equal to or higher than the self-resonance frequency of the common mode reactor, and in a band where the common mode reactor does not act as an inductive component. However, the noise component can be effectively attenuated.

Hereinafter, a noise filter according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a circuit diagram showing a schematic configuration of a noise filter according to the first embodiment of the present invention.
In FIG. 1, the noise filter is provided with a common mode reactor CL11. The common mode reactor CL11 is provided with coils L11 to L13 connected in series to power supply lines that supply three-phase voltages. The noise filter is provided with a series circuit in which capacitors C11 to C13 and reactors L14 to L16 are connected in series. These series circuits are respectively connected between a power supply line for supplying a three-phase voltage and the ground. ing.

  Here, the capacitance C of the capacitors C11 to C13 and the inductances of the reactors L14 to L16 are set so that the resonance frequency f = 1 / (2π√ (LC)) of these series circuits is equal to or higher than the self-resonance frequency of the common mode reactor CL11. L can be set, and it is preferable to set the resonance frequency f of these series circuits in the vicinity of the peak frequency of the noise spectrum in a band equal to or higher than the self-resonance frequency of the common mode reactor CL11.

  As a result, a bypass path can be formed for a noise peak component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL11, and the noise component is effective even in a band where the common mode reactor CL11 does not act as an inductive component. Can be attenuated. As a result, it becomes possible to attenuate the noise component accompanying the switching operation of the inverter over a wide band, the noise component accompanying the switching operation of the inverter flows into the power supply side, and the electric equipment connected to the same system malfunctions. Can be prevented.

  In the above-described embodiment, a method in which a series circuit in which capacitors C11 to C13 and reactors L14 to L16 are connected in series is provided at the subsequent stage of the common mode reactor CL11 is described. However, capacitors C11 to C13 and reactors L14 to L16 are provided. May be provided in the preceding stage of the common mode reactor CL11.

FIG. 2 is a circuit diagram showing a schematic configuration of a noise filter according to the second embodiment of the present invention.
In FIG. 2, the noise filter F21 is provided with a common mode reactor CL21, and the common mode reactor CL21 is provided with coils L21 to L23 connected in series to a power supply line for supplying a three-phase voltage. The noise filter F21 is provided with a series circuit in which a capacitor C24 and a reactor L24 are connected in series. This series circuit is connected between one phase of a power supply line for supplying a three-phase voltage and the ground. . Further, delta-connected line capacitors C21 to C23 are respectively connected between the power supply lines that supply the three-phase voltages.

Further, a diode bridge DB21 and a DC intermediate capacitor C25 for rectifying the three-phase voltage are provided at the subsequent stage of the noise filter F21, and diodes D21 to D26 are provided in the diode bridge DB21.
In the example of FIG. 2, the method of delta connection between the line capacitors C21 to C23 is shown, but the line capacitors C21 to C23 may be either delta connection or star connection. In the example of FIG. 2, the method of providing both the line capacitors C21 to C23 and the DC intermediate capacitor C25 has been described. However, any one of the line capacitors C21 to C23 and the DC intermediate capacitor C25 may be provided. In the above-described embodiment, the method of providing the series circuit in which the capacitor C24 and the reactor L24 are connected in series in the subsequent stage of the common mode reactor CL21 has been described. However, the series circuit in which the capacitor C24 and the reactor L24 are connected in series You may make it provide in the front | former stage of common mode reactor CL21.

  Here, the capacitance C of the capacitor C24 and the reactor L24 are set such that the resonance frequency f = 1 / (2π√ (LC)) of the series circuit including the capacitor C24 and the reactor L24 is equal to or higher than the self-resonance frequency of the common mode reactor CL21. It is preferable to set the resonance frequency f of this series circuit in the vicinity of the peak frequency of the noise spectrum in a band equal to or higher than the self-resonance frequency of the common mode reactor CL21. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL21, and the noise component can be effectively attenuated.

  Further, when the configuration between the power supply line and the ground is unbalanced by connecting a series circuit composed of the capacitor C24 and the reactor L24 between one phase of the power supply line for supplying the three-phase voltage and the ground. The current is distributed so that the three phases are balanced by the line capacitors C21 to C23 or the DC intermediate capacitor C25, and the same effect as the configuration of FIG. 1 can be obtained.

FIG. 3 is a circuit diagram showing a schematic configuration of a noise filter according to the third embodiment of the present invention.
In FIG. 3, the noise filter is provided with a common mode reactor CL31, and the common mode reactor CL31 is provided with coils L31 to L33 connected in series to power supply lines for supplying a three-phase voltage. The noise filter is provided with a series circuit in which capacitors C31, C33, C35 and reactors L34 to L36 are connected in series, and these series circuits are respectively connected between a power supply line for supplying a three-phase voltage and the ground. The capacitors C32, C34, and C36 are connected in parallel to these series circuits.

Here, the capacitance C of the capacitors C31, C33, and C35 and the reactors L34 to L36 are set so that the resonance frequency f = 1 / (2π√ (LC)) of these series circuits is equal to or higher than the self-resonance frequency of the common mode reactor CL31. It is preferable to set the resonance frequency f of these series circuits in the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL31. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL31, and the noise component can be effectively attenuated.
Further, the capacitors C32, C34, and C36 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.

  In the above-described embodiment, the common mode reactor CL31 includes the series circuit in which the capacitors C31, C33, and C35 and the reactors L34 to L36 are connected in series, and the capacitors C32, C34, and C36 that are connected in parallel to these series circuits. Although the method of providing in the latter stage was shown, a series circuit in which capacitors C31, C33, C35 and reactors L34-L36 are connected in series and capacitors C32, C34, C36 connected in parallel to capacitors C31, C33, C35, respectively. You may make it provide in the front | former stage of common mode reactor CL31.

FIG. 4 is a circuit diagram showing a schematic configuration of a noise filter according to the fourth embodiment of the present invention.
4, the noise filter is provided with a common mode reactor CL41, and the common mode reactor CL41 is provided with coils L41 to L43 connected in series to a power supply line for supplying a three-phase voltage. In addition, star-connected line capacitors C41 to C43 are connected to the power supply line for supplying the three-phase voltage, and a capacitor C44 and a reactor L44 are connected in series between the neutral point and the ground. A series circuit is provided, and a capacitor C45 is connected in parallel to the series circuit.

  Here, the capacitance C of the capacitor C44 and the inductance L of the reactor L44 are set so that the resonance frequency f = 1 / (2π√ (LC)) of these series circuits is equal to or higher than the self-resonance frequency of the common mode reactor CL41. It is preferable to set the resonance frequency f of this series circuit in the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL41. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL41, and the noise component can be effectively attenuated.

Further, the capacitor C45 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.
Furthermore, by providing a series circuit in which the capacitor C44 and the reactor L44 are connected in series between the neutral point of the star-connected line capacitors C41 to C43 and the ground, the number of parts of the capacitor and the reactor can be reduced. Thus, cost reduction and reduction in size and weight can be achieved.

  In the above-described embodiment, the common-mode reactor CL41 includes the star-connected line capacitors C41 to C43, the series circuit in which the capacitor C44 and the reactor L44 are connected in series, and the capacitor C45 that is connected in parallel to each of these series circuits. Although the method of providing in the latter stage has been shown, the line connection capacitors C41 to C43 that are star-connected, the series circuit in which the capacitor C44 and the reactor L44 are connected in series, and the capacitor C45 that is connected in parallel to each of these series circuits are connected to the common mode. You may make it provide in the front | former stage of reactor CL41.

FIG. 5 is a circuit diagram showing a schematic configuration of a noise filter according to the fifth embodiment of the present invention.
In FIG. 5, the noise filter F51 is provided with a common mode reactor CL51, and the common mode reactor CL51 is provided with coils L51 to L53 connected in series to a power supply line for supplying a three-phase voltage. The noise filter F51 is provided with a series circuit in which a capacitor C54 and a reactor L54 are connected in series. This series circuit is connected between one phase of a power supply line for supplying a three-phase voltage and the ground. . Further, a capacitor C55 connected between the other one phase of the power supply line for supplying the three-phase voltage and the ground is connected to the noise filter F51. Further, line capacitors C51 to C53 that are delta-connected are connected between power supply lines that supply three-phase voltages.
Further, a diode bridge DB51 and a DC intermediate capacitor C56 for rectifying the three-phase voltage are provided after the noise filter F51, and diodes D51 to D56 are provided in the diode bridge DB51.

  In the example of FIG. 5, the method of delta connection between the line capacitors C51 to C53 is shown, but the line capacitors C51 to C53 may be either delta connection or star connection. In the example of FIG. 5, the method of providing both the line capacitors C51 to C53 and the DC intermediate capacitor C56 has been described. However, any one of the line capacitors C51 to C53 and the DC intermediate capacitor C56 may be provided. In the above-described embodiment, the series circuit in which the capacitor C54 and the reactor L54 are connected in series and the method of providing the capacitor C55 in the subsequent stage of the common mode reactor CL51 have been described. However, the capacitor C54 and the reactor L54 are connected in series. The series circuit and the capacitor C55 may be provided in front of the common mode reactor CL51.

  Here, the capacitance C of the capacitor C54 and the reactor L54 are set such that the resonance frequency f = 1 / (2π√ (LC)) of the series circuit including the capacitor C54 and the reactor L54 is equal to or higher than the self-resonance frequency of the common mode reactor CL51. It is preferable to set the resonance frequency f of this series circuit in the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL51. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL51, and the noise component can be effectively attenuated.

Further, when the configuration between the power supply line and the ground is unbalanced by connecting a series circuit composed of the capacitor C54 and the reactor L54 between one phase of the power supply line for supplying the three-phase voltage and the ground. The current is distributed so that the three phases are balanced by the line capacitors C51 to C53 or the DC intermediate capacitor C56, and the same effect as that of the configuration of FIG. 1 can be obtained.
Further, the capacitor C55 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.

FIG. 6 is a circuit diagram showing a schematic configuration of a noise filter according to the sixth embodiment of the present invention.
In FIG. 6, the noise filter is provided with a common mode reactor CL61, and the common mode reactor CL61 is provided with coils L61 to L63 respectively connected in series to a power supply line for supplying a three-phase voltage. Further, the noise filter is provided with capacitors C61 to C63 respectively connected between a power supply line for supplying a three-phase voltage and the ground.

  Here, the self-resonance frequencies of the capacitors C61 to C63 can be set to be equal to or higher than the self-resonance frequency of the common mode reactor CL61, and the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL61. It is preferable to set the self-resonant frequencies of the capacitors C61 to C63 in the vicinity of As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL61, and the noise component can be effectively attenuated.

  Note that the connection between the common mode reactor CL61 and the capacitors C61 to C63 may be reversed. The self-resonance frequency of the capacitor can also be adjusted by the lead wire length or the print pattern length, and the self-resonance frequency of the capacitor is set so as to include the influence of the lead wire length or the print pattern length. Also good.

FIG. 7 is a circuit diagram showing a schematic configuration of a noise filter according to a seventh embodiment of the present invention.
In FIG. 7, the noise filter F71 is provided with a common mode reactor CL71, and the common mode reactor CL71 is provided with coils L71 to L73 connected in series to a power supply line for supplying a three-phase voltage. The noise filter F71 is provided with a capacitor C74 connected between one phase of a power supply line for supplying a three-phase voltage and the ground. Further, delta-connected line capacitors C71 to C73 are connected between the power supply lines that supply the three-phase voltages.

Further, a diode bridge DB 71 and a DC intermediate capacitor C75 for rectifying the three-phase voltage are provided at the subsequent stage of the noise filter F71, and diodes D71 to D76 are provided in the diode bridge DB71.
In the example of FIG. 7, the delta connection of the line capacitors C71 to C73 is shown, but the line capacitors C71 to C73 may be either delta connection or star connection. In the example of FIG. 7, the method of providing both the line capacitors C71 to C73 and the DC intermediate capacitor C75 has been described, but any one of the line capacitors C71 to C73 and the DC intermediate capacitor C75 may be provided.

Here, the self-resonance frequency of the capacitor C74 can be set so as to be equal to or higher than the self-resonance frequency of the common mode reactor CL71, and the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL71. In addition, it is preferable to set the self-resonant frequency of the capacitor C74. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL71, and the noise component can be effectively attenuated.
Note that the connection between the common mode reactor CL71 and the capacitor C74 may be reversed. The self-resonance frequency of the capacitor can also be adjusted by the lead wire length or the print pattern length, and the self-resonance frequency of the capacitor is set so as to include the influence of the lead wire length or the print pattern length. Also good.

FIG. 8 is a circuit diagram showing a schematic configuration of a noise filter according to the eighth embodiment of the present invention.
In FIG. 8, the noise filter is provided with a common mode reactor CL81, and the common mode reactor CL81 is provided with coils L81 to L83 respectively connected in series to a power supply line for supplying a three-phase voltage. Further, the noise filter is provided with capacitors C81, C83, C85 respectively connected between a power supply line for supplying a three-phase voltage and the ground, and these capacitors C81, C83, C85 include capacitors C82, C84, C86 are connected in parallel.

  Here, the self-resonance frequencies of the capacitors C81, C83, and C85 can be set so as to be equal to or higher than the self-resonance frequency of the common-mode reactor CL81. It is preferable to set the self-resonant frequencies of the capacitors C81, C83, and C85 in the vicinity of the peak frequency. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of common mode reactor CL81, and the noise component can be effectively attenuated.

Further, the capacitors C82, C84, and C86 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.
Note that the common mode reactor CL81 and the capacitors C81 to C86 may be connected to each other. The self-resonance frequency of the capacitor can also be adjusted by the lead wire length or the print pattern length, and the self-resonance frequency of the capacitor is set so as to include the influence of the lead wire length or the print pattern length. Also good.

FIG. 9 is a circuit diagram showing a schematic configuration of a noise filter according to the ninth embodiment of the present invention.
In FIG. 9, the noise filter is provided with a common mode reactor CL91, and the common mode reactor CL91 is provided with coils L91 to L93 connected in series to a power supply line for supplying a three-phase voltage. In addition, star-connected line capacitors C91 to C93 are respectively connected to the power supply lines for supplying the three-phase voltage, and a capacitor C94 is connected between the neutral point and the ground, and the capacitor C94. Is connected in parallel with a capacitor C95.

  Here, the self-resonance frequency of the capacitor C94 can be set to be equal to or higher than the self-resonance frequency of the common mode reactor CL91, and the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL91. Further, it is preferable to set the self-resonant frequency of the capacitor C94. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL91, and the noise component can be effectively attenuated.

Further, the capacitor C95 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.
Note that the connection between the common mode reactor CL91 and the capacitors C91 to C95 may be reversed. The self-resonance frequency of the capacitor can also be adjusted by the lead wire length or the print pattern length, and the self-resonance frequency of the capacitor is set so as to include the influence of the lead wire length or the print pattern length. Also good.

FIG. 10 is a circuit diagram showing a schematic configuration of a noise filter according to the tenth embodiment of the present invention.
In FIG. 10, the noise filter F101 is provided with a common mode reactor CL101, and the common mode reactor CL101 is provided with coils L101 to L103 connected in series to a power supply line for supplying a three-phase voltage. Further, the noise filter F101 is provided with a capacitor C104 connected between one phase of a power supply line for supplying a three-phase voltage and the ground. Furthermore, a capacitor C105 connected between the other one phase of the power supply line for supplying the three-phase voltage and the ground is connected to the noise filter F101. Further, delta-connected line capacitors C101 to C103 are respectively connected between power supply lines for supplying three-phase voltages.

Further, a diode bridge DB101 and a DC intermediate capacitor C106 for rectifying the three-phase voltage are provided at the subsequent stage of the noise filter F101, and diodes D101 to D106 are provided in the diode bridge DB101.
In the example of FIG. 10, the method of delta connection between the line capacitors C101 to C103 is shown, but the line capacitors C101 to C103 may be either delta connection or star connection. In the example of FIG. 10, the method of providing both the line capacitors C101 to C103 and the DC intermediate capacitor C106 has been described, but any one of the line capacitors C101 to C103 and the DC intermediate capacitor C106 may be provided.

  Here, the self-resonance frequency of the capacitor C104 can be set so as to be equal to or higher than the self-resonance frequency of the common mode reactor CL101, and the vicinity of the peak frequency of the noise spectrum in the band equal to or higher than the self-resonance frequency of the common mode reactor CL101. Further, it is preferable to set the self-resonant frequency of the capacitor C104. As a result, a bypass path can be formed for a noise component in a band equal to or higher than the self-resonant frequency of the common mode reactor CL101, and the noise component can be effectively attenuated.

Even when the configuration between the power supply line and the ground is unbalanced by connecting the capacitor C104 between one phase of the power supply line for supplying the three-phase voltage and the ground, the line capacitors C101- The current is distributed so that the three phases are balanced by C103 or the DC intermediate capacitor C106, and the same effect as the configuration of FIG. 1 can be obtained.
Further, the capacitor C105 can set frequency characteristics so as to have a capacitance component even in a high frequency band. Thereby, the attenuation effect of the noise filter can be maintained even in the high frequency band, and the noise spectrum flowing out to the power source side can be suppressed within the standard.

  Note that the common mode reactor CL101 and the capacitors C104 and C105 may be connected back and forth. The self-resonance frequency of the capacitor can also be adjusted by the lead wire length or the print pattern length, and the self-resonance frequency of the capacitor is set so as to include the influence of the lead wire length or the print pattern length. Also good.

It is a circuit diagram showing a schematic structure of a noise filter concerning a 1st embodiment of the present invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 2nd Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 3rd Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 4th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 5th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 6th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 7th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 8th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 9th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the noise filter which concerns on 10th Embodiment of this invention. It is a circuit diagram which shows schematic structure of the motor drive system using the inverter containing the conventional noise filter. FIG. 12 is a circuit diagram illustrating a three-stage configuration of the noise filter of FIG. 11. It is a circuit diagram which shows the other example of the conventional noise filter. It is a figure which shows the attenuation characteristic of a noise filter.

Explanation of symbols

CL1, CL21, CL31, CL41, CL51, CL61, CL71, CL81, CL91, CL101 Common mode reactors L11-L13, L21-L23, L31-L33, L41-L43, L51-L53, L61-L63, L71-L73, L91 to L93, L101 to L103 Coils C11 to C13, C24, C31 to C36, C44, C45, C54, C55, C61 to C63, C74, C81 to C86, C94, C95, C104, C105 Capacitors L14 to L16, L24, L34-L36, L44, L54 Reactor F21, F51, F71, F101 Noise filter DB21, DB51, DB71, DB101 Diode bridge C21-C23, C41-C43, C51-C53, C71-C73 C91~C93, C101~C103 line between capacitor D21~D26, D51~D56, D71~D76, D101~D106 diode C25, C56, C75, C106 DC intermediate capacitor

Claims (6)

At least one common mode reactor connected to the power supply line of the power conversion circuit;
A series circuit comprising at least one set of capacitors and a reactor connected between the power supply line and the ground;
The resonance frequency of the series circuit is set to a frequency equal to or higher than the self-resonance frequency of the common mode reactor and in the vicinity of a noise peak. At least one common mode reactor connected to the power supply line of the power conversion circuit;
A series circuit comprising at least one first capacitor and a reactor connected between the power supply line and ground;
A second capacitor connected in parallel to the series circuit,
The resonance frequency of the series circuit is set to a frequency that is equal to or higher than the self-resonance frequency of the common mode reactor and close to a noise peak, and the second capacitor is a capacitor that exhibits capacitance at least in a noise regulation frequency band. A characteristic noise filter. At least one common mode reactor connected to the power supply line of the power conversion circuit;
A series circuit composed of at least one first capacitor and a reactor connected in at least one phase between the power supply line and the ground;
A second capacitor connected to the remaining at least one phase between the power supply line and ground;
The resonance frequency of the series circuit is set to a frequency that is equal to or higher than the self-resonance frequency of the common mode reactor and close to a noise peak, and the second capacitor is a capacitor that exhibits capacitance at least in a noise regulation frequency band. A characteristic noise filter. At least one common mode reactor connected to the power supply line of the power conversion circuit;
And at least one capacitor connected between the power supply line and ground,
The self-resonant frequency of the capacitor is set to be equal to or higher than the self-resonant frequency of the common mode reactor and in the vicinity of a noise peak. At least one common mode reactor connected to the power supply line of the power conversion circuit;
At least one first capacitor connected between the power supply line and ground;
A second capacitor connected in parallel to the first capacitor;
The self-resonant frequency of the first capacitor is set to a frequency that is equal to or higher than the self-resonant frequency of the common mode reactor and near the noise peak, and the second capacitor uses a capacitor that exhibits capacitance at least in a noise regulation frequency band. A noise filter characterized by that. At least one common mode reactor connected to the power supply line of the power conversion circuit;
At least one first capacitor connected in at least one phase between the power supply line and ground;
A second capacitor connected to the remaining at least one phase between the power supply line and ground;
The self-resonant frequency of the first capacitor is set to a frequency that is equal to or higher than the self-resonant frequency of the common mode reactor and near the noise peak, and the second capacitor uses a capacitor that exhibits capacitance at least in a noise regulation frequency band. A noise filter characterized by that.

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