WO2022201223A1 - Noise filter circuit and noise filter device - Google Patents

Abstract

A noise filter circuit (24) comprises: connection cables (16a, 16b) that join a load (13) and an internal noise filter circuit (23) that is connected to an inverter (21); a housing ground (25) that is provided to a housing that supports the inverter (21); capacitors (24a, 24b) that are connected to respective connection cables (16a, 16b); and a variable resistor (24c) that connects to the capacitors (24a, 24b). The variable resistor (24c) and the capacitors (24a, 24b) are connected in series between the connection cables (16a, 16b) and the housing ground (25).

Description

NOISE FILTER CIRCUIT AND NOISE FILTER DEVICE

The present disclosure relates to noise filter circuits and noise filter devices.

A cable is connected to the electronic device to connect it to an external device. When electromagnetic noise is generated from such electronic equipment, the electromagnetic noise may be radiated from the cable. In this case, the electromagnetic noise transmitted to the external device via the cable may affect the operation of the external device. In addition, external electromagnetic noise may enter from the cable and affect electronic equipment or external equipment. For this reason, some electronic devices are equipped with an internal noise filter circuit for suppressing the electromagnetic noise.

Patent Document 1 discloses a low-pass filter that serves as an internal noise filter circuit.

JP 2018-128270 A

Here, among the above electromagnetic noises, the noise induced between the cable and the reference potential surface such as the ground on which the electronic device is installed is called common mode noise. The current component of this common mode noise is transmitted from the electronic device to the external device via the cable, flows through the ground, and returns to the original electronic device. For this reason, the current component of common mode noise fluctuates significantly due to the effects of cables and external devices, and may cause resonance.

On the other hand, the low-pass filter disclosed in Patent Document 1 is connected between the three-phase output cables connecting the inverter and the motor. Therefore, the low-pass filter does not deal with common-mode noise induced between the cable and the ground, and cannot suppress resonance due to fluctuations in the current component.

The present disclosure has been made to solve the above problems, and an object of the present disclosure is to provide a noise filter circuit that can suppress resonance by reducing fluctuations in the current component of common mode noise. .

The noise filter circuit according to the present disclosure includes a cable connecting an internal noise filter circuit connected to the inverter and an external device, a housing ground provided in a housing that supports the inverter, a capacitor connected to each cable, and each A variable resistor connected to the capacitor, each capacitor and variable resistor being connected in series between the cable and chassis ground.

According to the present disclosure, since it is configured as described above, it is possible to reduce fluctuations in the current component of common mode noise and suppress resonance.

1 is a diagram showing a configuration of a power supply system equipped with a main circuit device having a noise filter circuit according to Embodiment 1; FIG. 1 is an external view showing the configuration of a terminal block provided with a noise filter circuit according to Embodiment 1; FIG. FIG. 2 is a partial cross-sectional view showing the configuration of a terminal block provided with a noise filter circuit according to Embodiment 1; 2 is a plan view showing the configuration of a terminal block provided with the noise filter circuit according to Embodiment 1; FIG. 1 is a diagram showing a configuration of a power supply system equipped with a conventional main circuit device; FIG.

Hereinafter, in order to describe the present disclosure in more detail, embodiments for carrying out the present disclosure will be described according to the attached drawings.

Embodiment 1.
The noise filter circuit 24 according to Embodiment 1 will be described with reference to FIGS. 1 to 5. FIG.

FIG. 1 is a diagram showing the configuration of a power supply system equipped with a main circuit device 12 having a noise filter circuit 24 according to the first embodiment. Note that FIG. 1 shows an example in which the noise filter circuit 24 is arranged on the output side of the main circuit device 12 .

As shown in FIG. 1, the power supply system includes an AC power supply 11, a main circuit device 12, a load 13, and a noise measurement device 14. The main circuit device 12 is, for example, an electronic device such as a power electronic device that is driven by power supply. Also, the load 13 is a motor or the like driven by electrical energy controlled by the main circuit device 12 . The AC power supply 11 and the load 13 constitute external equipment.

The AC power supply 11 is a single-phase two-wire power supply. Therefore, the AC power supply 11 and the main circuit device 12 are connected by power cables 15a and 15b. The main circuit device 12 and the load 13 are connected by connection cables 16a and 16b. The main circuit device 12 and the noise measuring device 14 are also connected to the reference ground 17 .

The main circuit device 12 includes an inverter 21 that serves as a noise source, internal noise filter circuits 22 and 23, a noise filter circuit 24, a housing ground 25, and a ground line 26.

The internal noise filter circuits 22 and 23 suppress fluctuations in the current component of electromagnetic noise generated due to driving of the inverter 21 . The current component of this electromagnetic noise is, for example, the main current component A1 of common mode noise. The internal noise filter circuits 22 and 23 suppress fluctuations in current components of external electromagnetic noise entering from the connection cables 16a and 16b.

The internal noise filter circuit 22 is provided on the input side within the main circuit device 12 . That is, the internal noise filter circuit 22 is connected to the input side of the inverter 21 . Power cables 15 a and 15 b are connected to the internal noise filter circuit 22 . The internal noise filter circuit 22 also has capacitors 22a and 22b and a ground line 22c. The capacitors 22a and 22b are connected in series between the power cables 15a and 15b. One end of the ground line 22c is connected between the capacitors 22a and 23b. On the other hand, the other end of the ground wire 22c is connected to the housing ground 25. As shown in FIG.

The internal noise filter circuit 23 is provided on the output side within the main circuit device 12 . That is, the internal noise filter circuit 23 is connected to the output side of the inverter 21 . Connection cables 16 a and 16 b are connected to the internal noise filter circuit 23 . The internal noise filter circuit 23 also has capacitors 23a and 23b and a ground line 23c. The capacitors 23a, 23b are connected in series between the connection cables 16a, 16b. One end of the ground line 23c is connected between the capacitors 23a and 23b. On the other hand, the other end of the ground wire 23c is connected to the chassis ground 25. As shown in FIG.

The noise filter circuit 24 suppresses fluctuations in the current component A2 of the common mode noise leaked from the internal noise filter circuit 22 or the internal noise filter circuit 23. The current component A2 of this common mode noise flows from the main circuit device 12 through the connection cables 16a and 16b, the load 13, and the reference ground 17 in order, and draws a loop path that returns to the original main circuit device 12. FIG. Therefore, the loop path of the current component A2 is affected by the load parasitic capacitance 13b and the cable parasitic capacitance 16c, and may cause complex LC resonance, standing wave resonance, and the like.

The noise filter circuit 24 is connected to the load side (outside) of the internal noise filter circuit 23 . Connection cables 16 a and 16 b are connected to the noise filter circuit 24 . The noise filter circuit 24 also has capacitors 24a and 24b and a variable resistor 24c. The capacitors 24a, 24b are connected in series between the connection cables 16a, 16b. One end of the variable resistor 24c is connected between the capacitors 24a and 24b. On the other hand, the other end of the variable resistor 24 c is connected to the chassis ground 25 .

The housing ground 25 is provided in the housing that supports the inverter 21 . Also, the chassis ground 25 is connected to the reference ground 17 via a ground line 26 .

The load impedance 13a is connected between the connection cables 16a and 16b. This load 13 has a load impedance 13a. A load parasitic capacitance 13 b is generated between the load 13 and the reference ground 17 . A cable parasitic capacitance 16 c is generated between the connection cables 16 a and 16 b and the reference ground 17 .

The noise measuring device 14 measures the current value of the current component A2 of common mode noise. The noise measuring device 14 is provided between the power cables 15a and 15b. That is, the noise measuring device 14 is connected between the AC power supply 11 and the main circuit device 12 . The noise measuring device 14 also has inductances 14a and 14d, capacitors 14b and 14e, and resistors 14c and 14f.

One end of the inductance 14 a is connected to one end of the AC power supply 11 . On the other hand, the other end of the inductance 14a is connected to the power cable 15a. Capacitor 14 b and resistor 14 c are connected in series between inductance 14 a and reference ground 17 .

Also, one end of the inductance 14 d is connected to the other end of the AC power supply 11 . On the other hand, the other end of the inductance 14d is connected to the power cable 15b. Capacitor 14 e and resistor 14 f are connected in series between inductance 14 d and reference ground 17 .

Next, application examples of the noise filter circuit 24 will be described with reference to FIGS. 2 to 4. FIG.

FIG. 2 is an external view showing the configuration of the terminal block 40 including the noise filter circuit 24 according to Embodiment 1. FIG. FIG. 3 is a partial cross-sectional view showing the configuration of the terminal block 40 including the noise filter circuit 24 according to Embodiment 1. As shown in FIG. FIG. 4 is a plan view showing the configuration of the terminal block 40 including the noise filter circuit 24 according to the first embodiment. Note that FIG. 4 is a diagram in which the partition plates 42, 43a to 43d are omitted.

2 to 4, the terminal block 40, for example, is assumed as the noise filter device including the noise filter circuit 24. FIG. Further, as shown in FIGS. 2 and 4, in the terminal block 40, the outside of the main circuit device 12 is denoted as "OS" with the center line C at the center in the width direction as a boundary. The inside is indicated as "IS".

As shown in FIG. 4, the terminal block 40 connects the outer wirings 61, 62 of the main circuit device 12 and the inner wirings 71, 72 of the main circuit device 12, respectively. Also, the terminal block 40 connects the outer ground wire 63 and the inner ground wire 73 . The outer wires 61, 62 are connected to the connection cables 16a, 16b, respectively.

As shown in FIGS. 2 to 4, the terminal block 40 includes a pedestal 41, partition plates 42, 43a, 43b, 43c and 43d, terminal electrodes 44A, 44B and 44C, screws 45, internal connection wires 46a, 46b and 46c, It has capacitors 24 a and 24 b , a variable resistor 24 c and a dial 47 .

The pedestal 41 is arranged below the terminal block 40 . Terminal electrodes 44A, 44B, and 44C are provided on base 41 so as to extend in the width direction of terminal block 40 .

The terminal electrode 44A connects the outer wiring 61 and the inner wiring 71 . The terminal electrode 44A has terminals 44Aa and 44Ab.

The terminal 44Aa is formed at the outer end of the terminal electrode 44A. This terminal 44Aa is connected to the outer wiring 61 using a screw 45 . The screw 45 passes through the terminal 44Aa and is tightened into the screw hole 41a of the base 41. As shown in FIG. A terminal 44Ab is formed at the inner end of the terminal electrode 44A. This terminal 44Ab is connected to the inner wiring 71 using a screw 45. As shown in FIG. The screw 45 passes through the terminal 44Ab and is tightened into the screw hole 41a of the base 41. As shown in FIG.

The terminal electrode 44B connects the outer wiring 62 and the inner wiring 72 . The terminal electrode 44B has terminals 44Ba and 44Bb.

The terminal 44Ba is formed at the outer end of the terminal electrode 44B. This terminal 44Ba is connected to the outer wiring 62 using a screw 45. As shown in FIG. The screw 45 passes through the terminal 44Ba and is tightened into the screw hole 41a of the base 41. As shown in FIG. A terminal 44Bb is formed at the inner end of the terminal electrode 44B. This terminal 44Bb is connected to the inner wiring 72 using a screw 45 . The screw 45 passes through the terminal 44Bb and is tightened into the screw hole 41a of the base 41. As shown in FIG.

The terminal electrode 44C connects the outer ground wire 63 and the inner ground wire 73. This terminal electrode 44C has terminals 44Ca and 44Cb.

The terminal 44Ca is formed at the outer end of the terminal electrode 44C. This terminal 44Ca is connected to the outer ground wire 63 using a screw 45. As shown in FIG. The screw 45 penetrates the terminal 44Ca and is tightened into the screw hole 41a of the base 41. As shown in FIG. A terminal 44Cb is formed at the inner end of the terminal electrode 44C. This terminal 44Cb is connected to the inner ground wire 73 using a screw 45 . The screw 45 passes through the terminal 44Cb and is tightened into the screw hole 41a of the base 41. As shown in FIG.

The partition plate 42 and partition plates 43 a to 43 d are arranged above the terminal block 40 . The partition plate 42 and the partition plates 43a to 43d are provided on the upper surface of the base 41 so as to partition the terminals 44Aa, 44Ab to 44Ca, 44Cb and the screws 45 for fixing them to the base 41 by screws. Partition plate 42 extends along center line C of terminal block 40 . The partition plates 43a-43d extend in the width direction of the terminal block 40. As shown in FIG. In this manner, the terminal block 40 is provided with the partition plate 42 and the partition plates 43a to 43d to prevent short circuits between terminals.

In addition, as shown in FIG. 3, the terminals 44Aa, 44Ba, 44Ca located outside the terminal block 40 are built in the pedestal 41. As shown in FIG. Further, the terminals 44Aa, 44Ba, 44Ca built in the base 41 are electrically connected to the screw hole 41a. Correspondingly, the capacitors 24a, 24b, the variable resistor 24c, and the internal connection lines 46a, 46b, 46c are also built into the base 41. As shown in FIG. Note that the terminals 44Aa, 44Ba, and 44Ca may not be built into the base 41. FIG.

As shown in FIGS. 3 and 4, the terminal 44Aa and the variable resistor 24c are connected by an internal connection line 46a. The capacitor 24a is provided on its internal connection line 46a. The terminal 44Ba and the variable resistor 24c are connected by an internal connection line 46b. The capacitor 24b is provided on its internal connection line 46b. The terminal 44Ca and the variable resistor 24c are connected by an internal connection line 46c.

Here, as shown in FIGS. 2 to 4, the dial 47 is a dial for adjusting the resistance value of the variable resistor 24c. The dial 47 is exposed on the side surface of the pedestal 41 and is rotatably supported by the pedestal 41 . Further, the dial 47 has a rotating shaft 47a. The rotating shaft 47a passes through the pedestal 41 and is connected to the variable resistor 24c. On the other hand, the variable resistor 24c is configured such that the resistance value changes according to the amount of rotation of the dial 47. As shown in FIG.

Therefore, as shown in FIG. 4, when applying the terminal block 40 to the main circuit device 12, first, the outer wiring 61 is sandwiched between the screw 45 and the terminal 44Aa, and is fastened and fixed to the pedestal 41 by the screw 45. be done. Further, the outer wiring 62 is sandwiched between the screw 45 and the terminal 44Ba, and is fastened and fixed to the pedestal 41 by the screw 45. As shown in FIG. At this time, when the outer ground wire 63 is provided, the outer ground wire 63 is sandwiched between the screw 45 and the terminal 44Ca, and is fastened and fixed to the pedestal 41 by the screw 45 .

Next, the inner wiring 71 is sandwiched between the screw 45 and the terminal 44Ab, and is tightened and fixed to the pedestal 41 by the screw 45. Also, the inner wiring 72 is sandwiched between the screw 45 and the terminal 44Bb, and is fastened and fixed to the pedestal 41 by the screw 45 . At this time, when the inner ground wire 73 is provided, the inner ground wire 73 is sandwiched between the screw 45 and the terminal 44</b>Cb, and is fastened and fixed to the base 41 by the screw 45 .

Then, the outer ground wire 63 or the inner ground wire 73 is connected to the housing ground 25 . At this time, since the outer ground wire 63 and the inner ground wire 73 are connected by the terminal electrode 44C, it is not necessary to connect both the outer ground wire 63 and the inner ground wire 73 to the housing ground 25 .

Next, the operation of the main circuit device 12 provided with the noise filter circuit 24 according to Embodiment 1 will be explained using FIGS. 1 and 5 while comparing it with the operation of the conventional main circuit device 12A.

FIG. 5 is a diagram showing the configuration of a power supply system equipped with a conventional main circuit device 12A.

The conventional main circuit device 12A includes an inverter 21, internal noise filter circuits 22 and 23, a housing ground 25, and a ground line 26, which are noise sources. This conventional main circuit device 12A does not include the noise filter circuit 24. FIG.

As shown in FIG. 5, in the conventional power supply system, electromagnetic noise generated due to driving of the inverter 21 of the main circuit device 12A is transmitted from the main circuit device 12A to the AC power supply 11 via the power cables 15a and 15b. or to the load 13 from the main circuit device 12A via the connection cables 16a and 16b.

The current component A3 of the common mode noise of the electromagnetic noise flows from the main circuit device 12A through the power cables 15a and 15b, the AC power supply 11, and the reference ground 17 in order, and returns to the original main circuit device 12A. Drawing Path FIG. 5 shows the loop path of the connecting cables 16a and 16b in the current component A3.

Therefore, the current component A3 of the common mode noise may fluctuate greatly due to the influence of the load 13 and the connection cables 16a and 16b located outside the main circuit device 12A, causing resonance.

For example, in the case of the power supply system shown in FIG. 5, the loop path of the current component A3 of the common mode noise includes the inductance component (L) of the connection cables 16a and 16b, parasitic load capacitance 13b and cable parasitic capacitance 16c. It is affected by the capacitive component (C) and may cause complex LC resonance or standing wave resonance. Correspondingly, in the noise measuring device 14, the frequency at which the peak of the current component A3 of common mode noise appears and the level of that frequency fluctuate greatly.

Therefore, the internal noise filter circuits 22 and 23 connected to the input side and the output side of the main circuit device 12A preliminarily assume the mounting environment of the main circuit device 12A, and based on the conditions derived from the mounting environment, The circuit constant is designed so that the current component A3 of the common mode noise does not cause the resonance. However, there is a limit to the conditions of the mounting environment that can be assumed, and it is very difficult to extract all the conditions of the mounting environment. In addition, if the conditions of the actual installation environment deviate from the predicted values assumed in advance, unexpected voltage fluctuations occur, and it is necessary to replace the internal noise filter circuits 22 and 23 with different circuit constants each time. be.

Therefore, as shown in FIG. 1, the main circuit device 12 according to the first embodiment includes a noise filter circuit 24 in addition to the internal noise filter circuits 22 and 23. Therefore, in the main circuit device 12 , the main current component A1 of the common mode noise flows from the inverter 21 to the internal noise filter circuit 23 and returns to the inverter 21 . At this time, when the current principal component A1 passes through the internal noise filter circuit 23, its large fluctuation is suppressed.

In addition, the current component A2 of common mode noise leaked from the internal noise filter circuit 23 flows from the inverter 21 to the noise filter circuit 24, and further to the connection cables 16a and 16b, the reference ground 17, and the housing ground 25 in this order. flow and return to the inverter 21 . At this time, when the current component A2 passes through the noise filter circuit 24, its large fluctuation is suppressed.

Specifically, the variation of the current component A2 of the common mode noise is suppressed by adjusting the resistance value of the resistance component of the variable resistor 24c according to the current value of the current component A2. That is, the noise filter circuit 24 suppresses large fluctuations in the current component A2 by the resistance component of the variable resistor 24c. For example, the resistance value of the resistance component of the variable resistor 24c increases as the current value of the current component A2 increases. Correspondingly, in the noise measuring device 14, the peak of the current component A2 of common mode noise is low. As a result, the noise filter circuit 24 can suppress resonance that occurs in the power supply system.

In addition, even if the mounting conditions of the main circuit device 12 deviate from the predicted values assumed in advance, the noise filter circuit 24 has the magnitude of the inductance component (L) of the connection cables 16a, 16b, etc., the load parasitic The circuit constant can be changed by adjusting the magnitude of the resistance component of the variable resistor 24c according to the magnitude of the parasitic capacitance component (C) such as the capacitance 13b and the cable parasitic capacitance 16c.

As described above, the noise filter circuit 24 according to the first embodiment includes connection cables 16a and 16b that connect the internal noise filter circuit 23 connected to the inverter 21 and the load 13, and a chassis ground provided in the chassis that supports the inverter 21. 25, capacitors 24a and 24b connected to each of the connection cables 16a and 16b, and a variable resistor 24c connected to each of the capacitors 24a and 24b. 16b and chassis ground 25 are connected in series. Therefore, the noise filter circuit 24 can suppress the resonance by reducing the fluctuation of the current component A2 of the common mode noise.

Further, the noise filter device according to Embodiment 1 includes an inverter 21 connected to an AC power supply 11 and a load 13 which are external devices, an input side where the inverter 21 is connected to the AC power supply 11, and an inverter 21 connected to the load 13. Between the internal noise filter circuits 22 and 23 arranged on the connected output side, between the AC power supply 11 and the internal noise filter circuit 22 on the input side, and between the load 13 and the internal noise filter circuit 23 on the output side and a noise filter circuit 24 arranged between any one of them. Therefore, the noise filter device can suppress the resonance by reducing the fluctuation of the current component A2 of the common mode noise.

It should be noted that, within the scope of this disclosure, any component of the embodiment can be modified or any component of the embodiment can be omitted.

The noise filter circuit according to the present disclosure reduces the fluctuation of the current component of common mode noise and suppresses resonance by connecting the capacitor and the variable resistor in series between the cable and the chassis ground. It is suitable for use in noise filter circuits and the like.

11 AC power supply, 12, 12A Main circuit device, 13 Load, 13a Load impedance, 13b Load parasitic capacitance, 14 Noise measuring device, 14a, 14d Inductance, 14b, 14e Capacitor, 14c, 14f Resistance, 15a, 15b Power supply cable, 16a , 16b connection cable, 16c cable parasitic capacitance, 17 reference ground, 21 inverter, 22 internal noise filter circuit, 22a, 22b capacitors, 22c ground line, 23 internal noise filter circuit, 23a, 23b capacitors, 23c ground line, 24 noise filter Circuit, 24a, 24b capacitor, 24c variable resistor, 25 chassis ground, 26 ground wire, 40 terminal block, 41 pedestal, 41a screw hole, 42, 43a, 43b, 43c, 43d partition plate, 44A, 44B, 44C terminal electrode , 44Aa, 44Ab, 44Ba, 44Bb, 44Ca, 44Cb, terminals, 45 screws, 46a, 46b, 46c internal connection lines, 47 dials, 47a rotary shafts, 61, 62 outside wiring, 63 outside grounding lines, 71, 72 inside wiring , 73 Inside ground wire, A1 Current main component of common mode noise, A2, A3 Current components of common mode noise.

Claims (2)

1. a cable connecting an internal noise filter circuit connected to the inverter and an external device;
   a housing ground provided in a housing that supports the inverter;
   a capacitor connected to each cable;
   and a variable resistor connected to each capacitor,
   A noise filter circuit, wherein each capacitor and the variable resistor are connected in series between the cable and the chassis ground.
2. the inverter connected to the power source and the load serving as the external device;
   the internal noise filter circuit arranged on an input side where the inverter is connected to the power supply and on an output side where the inverter is connected to the load;
   2. The noise filter circuit according to claim 1, arranged between either one of said power supply and an internal noise filter circuit on the input side and between said load and an internal noise filter circuit on the output side. A noise filter device comprising:

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