JP2012015849A - Normal mode reactor and power converter equipped with same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a small noise filter capable of suppressing increase in noise current that leaks to the outside of a power converter.SOLUTION: A normal mode reactor installed on the input side or output side of a power converter is provided with an auxiliary winding. The auxiliary windings are connected in series so that an electromotive force caused by a normal mode current is canceled and that caused by a common mode current is added, with both ends being terminated with an impedance circuit. Consequently, the LC resonance generated between the normal mode reactor and a grounding capacitor is suppressed, to suppress increase in the common mode current that leaks to the outside of the power converter.

Description

  The present invention relates to a power converter that converts direct current or alternating current into another direct current or alternating current, and more particularly to a normal mode reactor having a function of suppressing a resonance frequency component of a common mode current.

  In power converters such as converters that convert AC power into DC power and inverters that convert DC power into AC power, power semiconductor elements that perform switching operations at high speed are used.

  In such a power converter, a high-frequency normal mode current flowing between AC lines is generated due to the switching operation of the power semiconductor element. In addition, a high-frequency common mode current flowing between the AC line and the ground is generated. These high-frequency currents cause noise that causes malfunction of the device. Conventionally, in order to remove these high-frequency currents, an AC reactor is inserted in the AC line of each phase of the converter and the inverter, and a normal mode noise filter is provided in which a capacitor is connected between the AC phase lines. .

  FIG. 9 is a conventional system configuration diagram when the normal mode noise filter is applied to a single-phase AC-DC converter. Converter 2 is an AC-DC converter that converts single-phase AC power into DC power, and its input terminal is connected to one end of each of reactors L3a and L3b. Reactor L3a and reactor L3b are normal mode reactors, and the other end of each is connected to AC power supply 1a, and capacitor C1 is connected between both terminals.

  Next, a capacitor Co for smoothing the output voltage Eo is connected between the output terminals of the converter 2. A load 4a is connected to both ends of the capacitor Co. A stray capacitance exists between the circuit components and wiring of the converter 2 and the ground 5. In FIG. 9, the stray capacitance Cs is shown as a representative between the output-side DC line of the converter 2 and the ground 5.

  Here, reactors L3a and L3b reduce high-frequency components of normal mode current flowing between AC power supply 1a and converter 2. Capacitor C1 absorbs a high-frequency component of normal mode current and constitutes a normal mode noise filter together with reactors L3a and L3b. By this normal mode noise filter, the high frequency component of the normal mode current leaking to the AC power supply 1a side is reduced.

  The converter 2 PWMs the built-in power semiconductor element so that the AC input current Iin is in phase with the AC input voltage Vin and has a sine wave shape, and so that the DC output voltage Eo, that is, the voltage across the capacitor Co becomes a predetermined value. Switching by control.

  Due to the switching operation of the power semiconductor element, potential fluctuations according to the AC power supply 1 a and the DC output voltage Eo occur between the circuit components and wiring of the converter 2 and the ground 5. Due to this potential fluctuation, a high-frequency common mode current flows between the converter 2 and the ground 5 via the stray capacitance Cs. In FIG. 9, the common mode current flows through the path of converter 2 → stray capacitance Cs → earth 5 → ground line (not shown) of AC power source 1 a → AC power source 1 a → parallel circuit of reactors L <b> 3 a and L <b> 3 b → converter 2.

  Here, since reactors L3a and L3b are normal mode reactors, their inductance is small and the common mode current cannot be sufficiently reduced. On the other hand, this common mode current causes a malfunction or noise failure of other devices connected to the system of the AC power supply 1a.

Therefore, a filter circuit that reduces a common mode current generated by a switching operation of a power semiconductor element has been proposed (see, for example, Patent Documents 1 to 6).
FIG. 10 is a circuit configuration diagram in which a conventional common mode noise filter including reactors L4a and L4b and capacitors C2a and C2b is added to the AC-DC converter of FIG.

  Reactors L4a and L4b are common mode reactors in which a main winding is wound around a common iron core. Reactors L4a and L4b are connected in series between AC power supply 1a and reactors L3a and L3b, respectively. Further, a series circuit in which capacitors C2a and C2b are connected in series is connected between a connection point between reactor L3a and reactor L4a and a connection point between reactor L3b and reactor L4b. The series connection point of the capacitors C2a and C2b is connected to the ground 5, and constitutes a common mode noise filter together with the reactors L4a and L4b.

  Here, the first common mode current flows in the path of converter 2 → stray capacitance Cs → earth 5 → parallel circuit of capacitors C2a and C2b → parallel circuit of reactors L3a and L3b → converter 2. Capacitors C2a and C2b bypass the common mode current generated by the switching operation of the power semiconductor built in converter 2 to ground 5, and prevent the common mode current from leaking to the AC power supply 1a side. A path through which the first common mode current flows is defined as a first path.

  Next, a part of the common mode current generated by the switching operation of the power semiconductor built in converter 2 leaks to the AC power supply 1a side as the second common mode current. This second common mode current is generated by the converter 2 → the stray capacitance Cs → the ground 5 → the ground line (not shown) of the AC power source 1a → the AC power source 1a → the series circuit composed of the reactors L4a and L3a, and the reactors L4b and L3b. It flows in the path of the parallel circuit of the series circuit consisting of A path through which the second common mode current flows is defined as a second path.

  The second common mode current acts in the direction of mutually strengthening the magnetic flux generated in the common core of reactors L4a and L4b. As a result, a larger back electromotive force is generated in reactors L4a and L4b. Due to the increase in the back electromotive force due to the above action, the common mode current leaking to the AC power supply 1a side is reduced, and malfunctions and noise disturbances of other devices connected to the system of the AC power supply 1a can be prevented.

  The windings of reactors L4a and L4b are wound around a common iron core so as to cancel each other's magnetic flux with respect to the normal mode current. Therefore, reactors L4a and L4b do not function as a reactor with respect to the normal mode current and do not affect the control operation of converter 2.

  The second path forms an LC resonance circuit. In order to suppress the second common mode current that increases due to the LC resonance of the second path, a common mode reactor is proposed in which an auxiliary winding is added to the common core of the reactors L4a and L4b and both ends thereof are terminated with resistors. (For example, refer to Patent Document 2 and Patent Document 5).

JP-A-9-103078 JP 2002-57542 A JP 2005-204438 A JP 2006-136058 A JP 2007-181341 A JP 2009-194957 A

  However, in the conventional example shown in FIG. 10, the first path also forms an LC resonance circuit. When LC resonance occurs in the first path, the circuit impedance with respect to the common mode current is significantly reduced in the resonance frequency band. As a result, the resonance frequency band component of the first common mode current flowing through the first path is significantly increased. A part of the current component in the increased resonance frequency band is added to the above-described second common mode current and leaks to the AC power supply 1a side.

  That is, contrary to the purpose of providing the capacitors C2a and C2b, when LC resonance occurs in the first path, the second common mode current leaking to the AC power supply 1a side increases. An increase in the second common mode current leaking to the AC power supply 1a side may cause malfunction or noise failure of other devices connected to the system of the AC power supply 1a.

  However, in the above-described conventional example, the influence of the LC resonance by the first path on the AC power supply 1a side is not considered. In order to reduce the resonance frequency band component of the first common mode current out of the second common mode current leaking to the AC power supply 1a side, it is necessary to extremely increase the inductances of the reactors L4a and L4b. Will lead to larger size and higher price.

  On the other hand, if the capacitors C2a and C2b are not provided, the first path does not exist, and thus the problem due to the LC resonance does not occur. However, since the bypass function of the common mode current is also lost at the same time, it is necessary to extremely increase the inductances of reactors L4a and L4b in order to sufficiently suppress other frequency components of the second common mode current.

The present invention has been made to solve the above-described problems, and an object of the present invention is to suppress LC resonance of the first path without increasing the size and cost of the apparatus.
Another object of the present invention is to suppress an increase in the second common mode current leaking to the AC power supply 1a side by suppressing LC resonance of the first path. It is another object of the present invention to prevent malfunction or noise failure of other devices connected to the AC power supply 1a system.

  A first invention for achieving the above object relates to a normal mode reactor, and a first reactor formed by winding a first main winding and a first auxiliary winding around a first iron core; , A second reactor formed by winding a second main winding and a second auxiliary winding around a second iron core, and the first auxiliary winding and the second auxiliary winding are A series circuit is formed by connecting one end of each, and both ends of the series circuit are connected by an impedance circuit to form a set of normal mode reactors.

  The second invention is a set of normal mode reactors according to the first invention, wherein the first auxiliary winding and the second auxiliary winding are the first reactor and the second reactor. When an alternating current of an opposite phase (a current corresponding to a normal mode current) is passed through each main winding of each of the reactors, an electromotive force induced in each auxiliary winding is subtracted, and the first reactor and the first When an alternating current of the same phase (current corresponding to a common mode current) is passed through the main windings of the reactors of No. 2 reactors, they are connected in series in the direction in which the electromotive force induced in each auxiliary winding is added. A series circuit is a set of normal mode reactors in which both ends of the series circuit are connected by an impedance circuit.

  Further, the third invention relates to a normal mode reactor having another configuration, and a pair of normal mode reactor bodies each having a main winding wound independently around two independent annular cores, and It is a set of normal mode reactors having one auxiliary winding wound through the two annular cores and an impedance circuit connecting both ends of the auxiliary winding.

  Further, a fourth invention is a set of normal mode reactors according to the third invention, wherein the auxiliary winding is in anti-phase with each main winding of the first reactor and the second reactor. Current (corresponding to normal mode current) is caused to flow, the electromotive force induced in each auxiliary winding is subtracted, and the same is applied to each main winding of the first reactor and the second reactor. When a phase alternating current (current corresponding to a common mode current) is passed, a series circuit is formed that is connected in series in the direction in which the electromotive force induced in each auxiliary winding is added, and both ends of the series circuit Is a set of normal mode reactors connected by an impedance circuit.

  The fifth invention is a set of normal mode reactors according to any one of the first to fourth inventions, wherein an impedance circuit connected to both ends of the series circuit is constituted by resistors. It is a thing.

  The sixth invention is a set of normal mode reactors according to any one of the first to fourth inventions, wherein an impedance circuit connected to both ends of the series circuit is a resistor and a capacitor. And a circuit connected to each other.

  Further, according to a seventh aspect of the present invention, there is provided a power converter that obtains a DC output voltage from the AC power source by connecting each AC line to a power source via a normal mode reactor and controlling on / off of switching elements of a plurality of switching arms. The normal mode reactor is a set of normal mode reactors according to any one of the first to sixth inventions.

  Further, according to an eighth aspect of the present invention, each AC line is connected to a load via a normal mode reactor, and a DC input voltage is converted into an AC voltage by controlling on / off of switching elements of a plurality of switching arms, In the power converter that applies the AC voltage to the load, the normal mode reactor is a set of normal mode reactors according to any one of the first to sixth inventions.

  According to the present invention, a simple circuit configuration in which an auxiliary winding and an impedance circuit are added to a normal mode reactor suppresses LC resonance of the first path without increasing the size and cost of the power converter. can do.

  As a result, an increase in the second common mode current leaking to the AC power supply side 1a side can be suppressed. Furthermore, it is possible to prevent malfunctions and noise disturbances of other devices connected to the AC power supply side 1a system.

The system block diagram which shows an example of embodiment of the power converter device which concerns on this invention. The block diagram which shows one Example of the normal mode reactor which concerns on this invention. The block diagram which shows the other Example of the normal mode reactor which concerns on this invention. The figure which shows the path | route through which a normal mode electric current flows in embodiment which concerns on FIG. The figure which shows the path | route through which the 1st common mode electric current flows in embodiment which concerns on FIG. The system block diagram which shows an example of embodiment of the power converter device which concerns on this invention. The system block diagram which shows the other Example of the power converter device which concerns on this invention. The system block diagram which shows the further another Example of the power converter device which concerns on this invention. The system block diagram which shows an example of the power converter device to which the conventional normal mode noise filter is applied. The system block diagram which shows an example of the power converter device to which the conventional common mode noise filter is applied.

  Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. 1 to 8, elements that are the same as those shown in FIGS. 9 and 10, which are an example of an embodiment of a conventional power conversion device, are assigned the same reference numerals, and descriptions thereof are omitted.

FIG. 1 is a schematic circuit diagram showing a configuration of a converter system that converts AC power into DC power according to an embodiment of the present invention.
The difference from FIG. 10 which is the conventional embodiment is that reactors L3a and L3b connected to the input terminal of converter 2 are replaced with reactors L1a and L1b having auxiliary windings, respectively. Further, the auxiliary windings of reactors L1a and L1b constitute a series circuit connected in series, and impedance circuit 6 is connected to both ends of this series circuit.

  Here, a set of normal mode reactors according to the present invention is manufactured by winding a main winding and an auxiliary winding around each annular core. For example, in the reactors L1a and L1b in the embodiment shown in FIG. 1, main windings 11a and 11b and auxiliary windings 12a and 12b are wound around the iron cores 10a and 10b, respectively, as shown in FIG. . As shown in FIG. 2, the auxiliary windings 12a and 12b are connected in series with a polarity that cancels the electromotive force induced by the normal mode current Inom and adds the electromotive force induced by the common mode current. The The series circuit connecting the auxiliary windings 12a and 12b is terminated with an impedance 6.

  Moreover, even if a common auxiliary winding is wound around each of the annular cores of the reactors L1a and L1b, a set of normal mode reactors according to the present invention can be manufactured. FIG. 3 shows a pair of normal mode reactors made up of the reactors L1a and L1b thus manufactured.

  Similarly to the normal mode reactor shown in FIG. 2, main windings 11a and 11b are wound around the iron cores 10a and 10b of the reactors L1a and L1b, respectively. On the other hand, the auxiliary winding 12c is wound through the iron cores 10a and 10b so as to cancel the electromotive force induced by the normal mode current Inom and add the electromotive force induced by the common mode current. The auxiliary winding 12c is terminated with an impedance 6.

In the above embodiment, a circular annular iron core has been described as an example. However, as long as the main winding and the auxiliary winding can be wound, the shape of the iron core may be elliptical or rectangular.
Moreover, even if the reactors L1a and L1b are manufactured by any of the above methods, the terminals U1, U2, V1, and V2 of the main windings are connected to the converter 2 and the AC power source 1a as shown in FIG. Is done.

  Next, the operation of reactors L1a and L1b when the normal mode current and the first common mode current described in the conventional embodiment flow will be described in detail below. Note that the second common mode current flows through the second path in the same manner as in the conventional example.

  FIG. 4 is a diagram showing an electromotive force induced in the auxiliary windings of reactors L1a and L1b when a normal mode current flows in FIG. When the power semiconductor element incorporated in the converter 2 performs a switching operation, the normal mode current Inom flows through the path of the AC power source 1a → reactor L4a → reactor L1a → converter 2 → reactor L1b → reactor L4b → AC power source 1a.

  Due to this normal mode current Inom, electromotive forces VL1A and VL1B of the same magnitude are induced in reactors L1a and L1b. Since the electromotive forces VL1A and VL1B are induced to cancel each other, no current flows in the closed circuit formed by the auxiliary windings of the reactors L1a and L1b and the impedance circuit 6. Therefore, reactors L1a and L1b work only as normal mode reactors and do not affect the control operation of converter 2.

  On the other hand, FIG. 5 is a diagram showing an electromotive force induced in the auxiliary windings of reactors L1a and L1b when the first common mode current flows. The first common mode current Icom flows through a path of converter 2 → stray capacitance Cs → earth 5 → parallel circuit of capacitor C2a and reactor L1a and parallel circuit of capacitor C2b and reactor L1b → converter 2. This route is the same as the first route shown in the conventional example, although there is a difference between the reactors L1a and L1b and the reactors L3a and L3b.

  Here, when the common mode current Icom flows through the first path, the electromotive forces VL1a and VL1b are induced in the auxiliary windings of the reactors L1a and L1b. The electromotive forces VL1a and VL1b are induced in the adding direction and applied to the impedance circuit 6. The first path constitutes an LC resonance circuit as in the conventional example, but the LC resonance is suppressed by the impedance circuit 6 connected to the auxiliary winding. As a result, the resonance frequency band component of the first common mode current Icom does not increase.

  Therefore, the second common mode current leaking to the AC power supply 1a side is sufficiently reduced by the common mode noise filter as in the conventional example. As a result, it is possible to prevent malfunctions and noise disturbances of other devices connected to the AC power supply 1a system.

  FIG. 6 is a configuration diagram of a converter system showing an embodiment when the impedance circuit 6 is configured by a resistor R. Other circuit components are the same as those in FIG. Even with such a circuit configuration, the LC resonance of the first path can be suppressed.

  FIG. 7 shows an embodiment in which the impedance circuit 6 is a series circuit of a resistor R and a capacitor C. Even with the impedance circuit as shown in FIG. 7, the LC resonance of the first path can be suppressed.

As described above, also in the embodiment of FIG. 6 or FIG. 7, since the LC resonance of the first path is suppressed, the component of the resonance frequency band of the first common mode current Icom does not increase.
Therefore, the second common mode current leaking to the AC power supply 1a side is sufficiently reduced by the common mode noise filter. As a result, it is possible to prevent malfunctions and noise disturbances of other devices connected to the AC power supply 1a system.

  FIG. 8 is a system configuration diagram when the normal mode reactor according to the present invention is applied to an output circuit of a single-phase inverter. The inverter 3 is an inverter that converts DC power into single-phase AC power, and a DC power source 1b is connected to its input terminal. Here, stray capacitance exists between the circuit components and wiring of the inverter 3 and the ground 5. As a representative example, a stray capacitance Cs is described between the input side DC line of the inverter 3 and the ground 5.

  Next, the output terminal of inverter 3 is connected to one end of each of reactors L2a and L2b. The other ends of reactor L2a and reactor L2b are connected to one ends of reactors L4a and L4b. A series circuit composed of capacitors C4a and C4b is connected between the connection point of reactors L2a and L4a and the connection point of reactors L2b and L4b, and the series connection point is connected to ground 5. Furthermore, a capacitor C3 is connected to the other ends of the reactors L4a and L4b, and a load 4b is connected.

  Here, reactors L2a and L2b and capacitor C3 constitute a normal mode noise filter. The normal mode noise filter reduces high frequency components of normal mode current flowing between the inverter 3 and the load 4b.

  On the other hand, reactors L4a and L4b and capacitors C4a and C4b constitute a common mode noise filter. This common mode noise filter reduces the common mode current leaking to the load 4b side.

  In FIG. 8, the normal mode current flows through the path of inverter 3 → reactor L2a → reactor L4a → parallel circuit of load 4b and capacitor C3 → reactor L4b → reactor L2b → inverter 3. Electromotive forces VL2A and VL2B (not shown) that are induced in the auxiliary windings of reactors L2a and L2b by the normal mode current are induced in the direction of canceling each other. As a result, no current flows through the closed circuit constituted by the auxiliary windings of the reactors L2a and L2b and the impedance circuit 6. Therefore, reactors L2a and L2b work only as normal mode reactors and do not affect the control operation of inverter 3.

  On the other hand, the current corresponding to the first common mode current described in FIG. 1 is the parallel circuit of the inverter 3 → the series circuit composed of the reactor L2a and the capacitor C4a and the series circuit composed of the reactor L2b and the capacitor C4b → the ground 5 → Floating capacitance Cs → Inverter 3 flows. This path is the third path, and the current flowing through this path is the third common mode current.

  When the third common mode current flows, electromotive forces VL2a and VL2b (not shown) are induced in the auxiliary windings of reactors L2a and L2b. The electromotive forces VL2a and VL2b are induced in the adding direction and applied to the impedance circuit 6.

  Although the third path constitutes an LC resonance circuit, the LC resonance is suppressed by the impedance circuit 6 connected to the auxiliary winding. Therefore, the resonance frequency band component of the third common mode current does not increase.

As a result, the common mode current leaking to the load 4b side is sufficiently reduced by the common mode noise filter.
As described above, according to the present invention, even if LC resonance occurs in the third path, the common mode current leaked to the load 4b side by the simple circuit configuration in which the auxiliary winding and the impedance circuit are added to the normal mode reactor. Can be suppressed. As a result, malfunction of the load 4b, noise disturbance, etc. can be prevented.

  The impedance circuit in FIG. 8 may be composed of the resistor R or the resistor R and the capacitor C as shown in FIGS.

1a AC power supply 1b DC power supply 2 Converter 3 Inverter 4a, 4b Load 5 Ground 6 Impedance circuit 10a, 10b Iron core 11a, 11b Main winding 12a-11c Auxiliary winding C capacitor C1 capacitor C2a, C2b capacitor C3 capacitor C4a, C4b capacitor Co Capacitor Cs Stray capacitance L1a, L1b Reactor L2a, L2b Reactor L3a, L3b Reactor L4a, L4b Reactor φ1, φ2 Magnetic flux

Claims (8)

A first reactor formed by winding a first main winding and a first auxiliary winding on a first iron core, and a second main winding and a second auxiliary winding on a second iron core. It consists of a second reactor that is wound,
The first auxiliary winding and the second auxiliary winding constitute a series circuit formed by connecting one end of each,
A set of reactors, wherein both ends of the series circuit are connected by an impedance circuit. A set of reactors according to claim 1,
The first auxiliary winding and the second auxiliary winding are respectively provided when an alternating current of opposite phase is passed through the main windings of the first reactor and the second reactor. The electromotive force induced in is subtracted,
A series connected in series in the direction in which the electromotive force induced in each auxiliary winding is added when an alternating current having the same phase is passed through the main winding of each of the first reactor and the second reactor. Configure the circuit,
A set of reactors, wherein both ends of the series circuit are connected by an impedance circuit. A pair of reactor main bodies each having a main winding wound independently on two independent annular cores;
One auxiliary winding wound through the two annular cores;
A set of reactors having an impedance circuit connecting both ends of the auxiliary winding. A set of reactors according to claim 3,
The auxiliary winding is subtracted from the electromotive force induced in each auxiliary winding when an alternating current of opposite phase is passed through each main winding of the first reactor and the second reactor.
A series connected in series in the direction in which the electromotive force induced in each auxiliary winding is added when an alternating current having the same phase is passed through the main winding of each of the first reactor and the second reactor. Configure the circuit,
A set of reactors, wherein both ends of the series circuit are connected by an impedance circuit. A set of reactors according to any one of claims 1 to 4,
A set of reactors, wherein an impedance circuit connected to both ends of the series circuit is composed of resistors. A set of reactors according to any one of claims 1 to 4,
A set of reactors, wherein an impedance circuit connected to both ends of the series circuit is constituted by a circuit in which a resistor and a capacitor are connected. In the power converter that obtains a DC output voltage from the AC power source by connecting each AC line to a power source via a reactor and controlling on / off switching elements of a plurality of switching arms,
The said reactor is a set of reactor of any one of Claim 1 thru | or 6, The power converter device characterized by the above-mentioned. Power conversion in which each AC line is connected to a load via a reactor, and a DC input voltage is converted to an AC voltage by applying on / off control of switching elements of a plurality of switching arms, and the AC voltage is applied to the load. In the device
The said reactor is a set of reactor of any one of Claim 1 thru | or 6, The power converter device characterized by the above-mentioned.

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