JP5877020B2 - Switch module for power converter - Google Patents

Description

  The present invention relates to a switch module of a power converter configured using a semiconductor switching element and a metal plate wiring.

2. Description of the Related Art Conventionally, there is a power conversion device such as an inverter in which a bridge circuit using a plurality of semiconductor switching elements is modularized.
For example, in the semiconductor device (switch module) disclosed in Patent Document 1, a bridge circuit of a three-phase inverter circuit is modularized using six semiconductor switching elements. Specifically, three bus bars are arranged in parallel at the center of the case, and three switching elements are arranged on both sides thereof. The output terminal of each switching element and the soldering terminal of each bus bar are connected to a printed circuit board mounted on the case, and the output terminal of each switching element is electrically connected to the corresponding bus bar via the printed circuit board pattern. Connected.

JP 2006-135170 A

  By the way, in the inverter circuit (bridge circuit), three switching elements are arranged on each of the upper arm and the lower arm, and a predetermined switching element of the upper arm and a predetermined switching element of the lower arm are provided for each set (each phase). And works in pairs. In this case, the switching element of the upper arm and the switching element of the lower arm that operate in pairs are connected to the same bus bar, but the wiring distance to the connection point (confluence) between the output terminal of each switching element and the bus bar If they are unequal, the parasitic inductance value differs for each group, and the output voltage of each group becomes unbalanced. This also causes the same problem not only in a three-phase inverter circuit but also in a single-phase inverter circuit.

  The present invention has been made to solve the above-described problems, and its purpose is to reduce the influence of parasitic inductance in the output path of each switching element, and to contribute to stabilization of output power. The object is to provide a switch module of the apparatus.

In order to solve the above problems, the invention according to claim 1 is constituted by a bridge circuit using a plurality of switching elements, and converts a DC power into a high-frequency AC power by a switching operation of each switching element. A switching module of a power conversion device configured by connecting a terminal of each switching element to a wiring structure composed of a plurality of plate wirings, the output of each switching element arranged on the upper and lower arms of the bridge circuit In the plate wiring of the wiring structure that connects between the terminal and the output node of the bridge circuit, the power transmission distance to the output node for each of the switching elements is set equal , and the wiring A control input plate is used as the plate wiring of the structure, and the control input plate A control signal is input to the control terminal of the switching element, and the switching element disposed in each arm of the bridge circuit is formed by connecting two switching elements in parallel. The control input plates for connecting the control terminals of the switching elements forming the above are provided for each of the arms, and the gist thereof is that they are formed in the same shape .

In the present invention, in the plate wiring of the wiring structure that connects between the output terminal of each switching element of the bridge circuit and the output node of the circuit, the power transmission distance to the output node for each switching element is made equal. The switch module is configured. As a result, since the inductance of the output path for each switching element is equal, the difference in output current / voltage transmission between each switching element is extremely small, and the high-frequency AC power output from the bridge circuit is stable with little distortion. Become.
Further, a control input plate for connecting the control terminals of each switching element paired for each arm is provided for each arm, and is formed in the same shape. As a result, the control input plate becomes one product number, which facilitates component management and assembly.

  According to a second aspect of the present invention, in the switch module of the power conversion device according to the first aspect, positive and negative power bus bars are used as the plate wiring of the wiring structure, and each power bus bar is connected to each other. The DC power is input to the bridge circuit, and each power bus bar is configured such that the directions of main currents flowing through the bridge circuit are opposite to each other.

  In the present invention, the plus side and minus side power supply bus bars used as the plate wiring of the wiring structure and for inputting DC power to the bridge circuit are configured so that the directions of the main currents flowing through them are opposite to each other. Is done. Thereby, the magnetic fields generated in the power bus bars act so as to cancel each other, and the radiation magnetic field can be reduced and the inductance of the power bus bar can be reduced.

  According to a third aspect of the present invention, in the switch module of the power conversion device according to the second aspect, the plus side and minus side power supply bus bars are provided with flat plate portions that face each other and form a parasitic capacitance. The gist of this is

  In the present invention, since the parasitic capacitance is formed in the flat plate portion provided in the plus side and minus side power supply bus bars, the capacitance effect can contribute to the reduction of the inductance of the power supply bus bar. Moreover, since the heat radiation area is enlarged at the flat plate portion, the heat radiation effect in the power bus bar is improved.

According to a fourth aspect of the invention, the switch module of the power conversion device according to claim 2 or 3, before Symbol control input plate, the signal transmission path itself within the flow of the main current of each power bus bar The gist is that it is configured to cross each other.

  In this invention, the control input plate that is used as the plate wiring of the wiring structure and inputs the control signal to the control terminal of the switching element has its own signal transmission path with respect to the main current flow of each power bus bar. Configured to intersect. As a result, the influence of the radiation magnetic field on the control signal side in the power supply bus bar, which can be relatively large, is reduced, and problems such as malfunctions are prevented.

Invention according to claim 5, between the switch modules of a power conversion device according to any one of claims 1 to 4, and the output terminal and the output node of the switching elements forming a pair for each of the arms The gist is that the power transmission distances are set equal to each other.

  In the present invention, the switching elements arranged in each arm of the bridge circuit are configured by connecting two switching elements in parallel, and the power between the output terminal and the output node of each switching element paired for each arm. The transmission distance is set equal. As a result, the inductance of the output path is equal between the switching elements connected in parallel for each arm, so that the difference in output current / voltage transmission between the switching elements is extremely small, and the output power from the bridge circuit is reduced. Can contribute to stabilization.

The invention according to claim 6 is the switch module of the power conversion device according to any one of claims 1 to 5 , wherein each switching element paired for each arm has both sides sandwiching the wiring structure. The gist is that they were installed side by side.

  In the present invention, each switching element that forms a pair for each arm is disposed on both sides of the wiring structure, and is arranged in parallel so as to face each other. Therefore, the plate wiring of the wiring structure is called the same shape or symmetrical shape. Such a simple shape can be formed, which can contribute to compactness.

The gist of the invention according to claim 7 is the switch module of the power conversion device according to any one of claims 1 to 6 , wherein the control input plate is formed in a point-symmetric shape. .
In this invention, since the control input plate is formed in a point-symmetric shape, it can be assembled even if it is rotated 180 degrees, and the complexity of the assembly is reduced.

The invention according to claim 8 is the switch module of the power conversion device according to any one of claims 1 to 7 , wherein an output plate having the output node is used as the plate wiring of the wiring structure, Output terminals of the switching elements of the upper and lower arms are connected to output the high-frequency AC power from the output node, and the output plate is provided for each of the upper and lower arms and has the same shape. The gist of this was formed.

  In the present invention, an output plate that is used as a plate wiring of a wiring structure and outputs high-frequency AC power from an output node is provided for each of the upper and lower arms and is formed in the same shape. As a result, the output plate becomes one product number, and parts management and assembly are easy to perform.

  ADVANTAGE OF THE INVENTION According to this invention, the switch module of the power converter device which can reduce the influence of the parasitic inductance in the output path | route for every switching element, and can contribute to stabilization of output electric power can be provided.

It is a circuit diagram of the DC-DC converter in this embodiment. It is a circuit diagram of the switch module used for an inverter circuit. It is a perspective view for demonstrating the structure of a switch module. It is a disassembled perspective view for demonstrating the structure of the wiring structure used for a switch module.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment of the invention will be described with reference to the drawings.
A DC-DC converter 10 according to this embodiment shown in FIG. 1 includes a smoothing capacitor Ca, an inverter circuit 11, an insulating transformer 12, a resonant capacitor Cx, a rectifier circuit 13, and a filter circuit 14.

  An inverter circuit 11 is provided on the primary side of the insulating transformer 12. In the present embodiment, the inverter circuit 11 is configured by a full bridge circuit using four sets of semiconductor switching elements SW1 to SW4 made of IGBT. As each switching element SW1 to SW4 (each switching element SW1a, SW1b to SW4a, SW4b described later), a diode having reverse connection diodes D1 to D4 and capacitors C1 to C4 is used. The inverter circuit 11 converts the DC power input through the smoothing capacitor Ca into high-frequency AC power by switching operations of the switching elements SW1 to SW4 based on the control of the control circuit 15, and converts the converted high-frequency AC power. The insulation transformer 12 is supplied to the primary coil 12a. The insulating transformer 12 converts the high-frequency AC power supplied to the primary side coil 12a into a predetermined voltage by the secondary side coil 12b.

  On the secondary side of the insulation transformer 12, a resonance capacitor Cx is connected in series to the secondary coil 12b, and a rectifier circuit 13 is provided at the subsequent stage. The rectifier circuit 13 is configured by a full bridge circuit using four diodes D5 to D8. A filter circuit 14 is provided following the rectifier circuit 13. The filter circuit 14 includes a smoothing reactor Lb and a smoothing capacitor Cb. The filter circuit 14 smoothes the DC power that has passed through the rectifier circuit 13 using the smoothing reactor Lb and the smoothing capacitor Cb, and outputs the smoothed DC power to the load side.

Next, a specific configuration of the inverter circuit 11 of the present embodiment will be described.
The inverter circuit 11 of this embodiment is a single-phase inverter circuit, and two pieces are connected in parallel for each pair of switching elements SW1 to SW4 (each arm) as shown in FIG. A total of eight switching elements SW1a, SW1b to SW4a, SW4b are configured as a bridge circuit. Each of the switching elements SW1a, SW1b to SW4a, SW4b is configured as a switch module 20 together with a wiring structure 21 that makes these electrical connections.

  As shown in FIGS. 3 and 4, the wiring structure 21 constituting the switch module 20 includes a substrate 22, two power bus bars 23 and 24, two output plates 25 and 26, and four control input plates. 27-30 are used. In the wiring structure 21, a plus power bus bar 23 is placed on the upper surface of the substrate 22, and a minus power bus bar 24 is placed on the upper surface in order. Two output plates 25 are placed on the upper surface of the minus power bus bar 24. , 26 are placed side by side, and two control input plates 27-30 are placed on the upper surfaces of the output plates 25, 26, respectively.

  The plus-side power supply bus bar 23 is a straight wiring portion having an elongated rectangular shape that is slightly longer than the length in the longitudinal direction of the substantially rectangular plate-like substrate 22 and about 1/3 of the width (length in the short direction) of the substrate 22. 23a, and a flat plate portion 23b that extends from the side of the straight wiring portion 23a and has a rectangular shape that is slightly shorter than the length in the longitudinal direction of the substrate 22 and has the same degree as the width of the substrate 22. Connection terminal portions 23c and 23d are provided upright at both ends in the longitudinal direction of the straight wiring portion 23a. The connection terminal portions 23c and 23d are constituted by male screws.

  Two connection terminals 23e and 23f are extended from one long side (front side in FIG. 4) of the flat plate portion 23b in a direction perpendicular to the extending direction of the straight wiring portion 23a. Two connection terminals 23g and 23h are extended from the other long side (the back side in FIG. 4) in a direction orthogonal to the direction in which the straight wiring portion 23a extends. The plus-side power supply bus bar 23 is provided with a total of four connection terminals 23e to 23h. The plus-side power supply bus bar 23 is arranged so that the straight wiring portion 23 a is brought close to one long side of the substrate 22, and the flat plate portion 23 b is overlapped with the substrate 22 in most part. The connection terminals 23e to 23h protrude from the substrate 22 outward in the width direction.

  The minus-side power supply bus bar 24 is formed in a line-symmetric shape with the plus-side power supply bus bar 23 except for its own connection terminals 24e to 24h described later. Specifically, the minus-side power supply bus bar 24 includes a straight wiring portion 24a that is a little longer than the length of the substrate 22 in the longitudinal direction and has an elongated rectangular shape that is about 1/3 of the width of the substrate 22, and the straight wiring portion. A flat plate portion 24b extending from the side of 24a and slightly shorter than the length in the longitudinal direction of the substrate 22 and having a rectangular shape similar to the width of the substrate 22 is provided. Connection terminal portions 24c and 24d are provided upright at both ends in the longitudinal direction of the straight wiring portion 24a. The connection terminal portions 24c and 24d are constituted by male screws.

  Two connection terminals 24e and 24f are extended from a long side on one side of the straight wiring portion 24a (front side in FIG. 4) in a direction orthogonal to the extending direction of the straight wiring portion 24a, and the flat plate portion 24b Two connection terminals 24g and 24h extend from the other long side (the back side in FIG. 4) in a direction orthogonal to the direction in which the straight wiring portion 24a extends. The minus-side power bus bar 24 is also provided with a total of four connection terminals 24e to 24h. The minus-side power supply bus bar 24 is arranged such that the straight wiring portion 24 a is brought close to the other long side of the substrate 22, and the flat plate portion 24 b is overlapped with the flat plate portion 23 b of the plus-side power supply bus bar 23. The connection terminals 24e to 24h protrude from the substrate 22 to the outside in the width direction, and are arranged at a predetermined interval from the connection terminals 23e to 23h of the plus-side power supply bus bar 23.

  The output plates 25 and 26 have the same main body portions as the width of the substrate 22 except for their connection terminals 25a to 25d and 26a to 26d and protrusions 25f and 26f having connection terminal portions 25e and 26e. The flat plate portion 24b of the minus-side power supply bus bar 24 (the flat plate portion 23b of the plus-side power supply bus bar 23) is formed in a substantially square shape slightly smaller than the half area. The output plates 25 and 26 have the same shape except for the protruding portions 25f and 26f having the connection terminal portions 25e and 26e.

  In the output plates 25 and 26, connection terminals 25 a to 25 d and 26 a to 26 d extend from the vicinity of the four corners on a pair of opposing sides. The output plates 25 and 26 are arranged on the flat plate portion 24b of the minus-side power supply bus bar 24 so as to be close to the end portions in the longitudinal direction, and the connection terminals 25a to 25d and 26a to 26d are disposed outward from the substrate 22 in the width direction. Protruding. The connection terminals 25a to 25d and 26a to 26d are close to the corresponding connection terminals 23e to 23h and 24e to 24h of the plus-side power supply bus bar 23 and the minus-side power supply bus bar 24, but do not overlap each other with a predetermined interval. Are arranged as follows.

  Output terminal portions 25g and 26g are erected at the center portions of the output plates 25 and 26, respectively. The output terminal portions 25g and 26g are constituted by male screws. Further, when the output plates 25 and 26 are arranged with respect to the minus-side power supply bus bar 24, the projecting portions 25f and 26f projecting outward from the center of the opposite sides of the output plates 25 and 26 opposite to each other. Is formed. Connection terminal portions 25e and 26e are provided upright on the projecting portions 25f and 26f, respectively. The connection terminal portions 25e and 26e are constituted by male screws.

  The control input plates 27 to 30 are formed in a horizontally long shape, except for the connection terminals 27a, 27b to 30a, and 30b of the control input plates, which is substantially the same as the width of the substrate 22 and slightly smaller than the half area of the output plates 25 and 26. Has been. The connection terminals 27a, 27b to 30a, 30b protrude outward in the width direction from the substrate 22, and correspond to the connection terminals 23e to 23h of the plus power bus bar 23, the minus power bus bar 24, and the output plates 25 and 26. , 24e to 24h, 25a to 25d, and 26a to 26d, they are arranged so as not to overlap with a predetermined interval. These control input plates 27 to 30 sandwich the output terminal portions 25g and 26g of each of the plates 25 and 26 in a non-contact manner on the output plates 25 and 26, respectively. Arranged along the width direction. Input terminal portions 27c to 30c are provided upright at the central portions of the control input plates 27 to 30, respectively. The input terminal portions 27c to 30c are constituted by male faston (flat type) terminals. Such control input plates 27 to 30 are formed in the same shape. That is, the control input plates 27 to 30 are composed of one product number. Moreover, since the control input plates 27 to 30 have a point-symmetric shape, they can be assembled even if they are rotated by 180 degrees, and the complexity of the assembly is reduced.

  Incidentally, in the present embodiment, the substrate 22, the plus power bus bar 23, the minus power bus bar 24, the output plates 25 and 26, and the control input plates 27 to 30 are adjacent to each other in the stacking direction. The wiring structure 21 is assembled by being fixed by a double-sided adhesive sheet (not shown). Further, the power bus bars 23 and 24, the output plates 25 and 26, and the control input plates 27 to 30 are coated with an insulating resin, so that the insulating properties are secured when stacked.

  Here, the eight switching elements SW1a, SW1b to SW4a, SW4b constituting the switch module 20 are replaced with a first switching element SW1a, SW1b, a second switching element SW2a, SW2b, a third switching element SW3a, SW3b, a fourth switching element. Elements SW4a and SW4b are used. The first switching elements SW1a and SW1b and the second switching elements SW2a and SW2b are provided in the upper arm of the inverter circuit 11 (bridge circuit), and the third switching elements SW3a and SW3b and the fourth switching are provided in the lower arm. It is assumed that elements SW4a and SW4b are arranged. In this case, the first switching elements SW1a and SW1b and the fourth switching elements SW4a and SW4b operate in pairs, and the second switching elements SW2a and SW2b and the third switching elements SW3a and SW3b operate in pairs.

  The first switching elements SW1a, SW1b, the third switching elements SW3a, SW3b, the second switching elements SW2a, SW2b, the fourth switching elements SW4a, SW4b are arranged in this order from one side in the longitudinal direction of the wiring structure 21, and this wiring structure The first switching elements SW1a and SW1b are separately arranged on both sides of the body 21, and the third switching elements SW3a and SW3b, the second switching elements SW2a and SW2b, and the fourth switching elements SW4a and SW4b are similarly arranged separately. Is done. The gate terminals tg, collector terminals tc, and emitter terminals te included in the first to fourth switching elements SW1a, SW1b to SW4a, SW4b correspond to the corresponding connection terminals 23e to 23h, 24e to 24h of the wiring structure 21, respectively. Connected to 25a-25d, 26a-26d, 27a, 27b-30a, 30b, respectively.

  The first to fourth switching elements SW1a, SW1b to SW4a, SW4b are composed of the same element (IGBT). Each of the first to fourth switching elements SW1a, SW1b to SW4a, SW4b has a substantially square plate shape, and a gate terminal tg, a collector terminal tc, and an emitter terminal te are arranged in this order from one side on one side. It has been. The first to fourth switching elements SW <b> 1 a, SW <b> 1 b to SW <b> 4 a, SW <b> 4 b are arranged along the plane direction of the substrate 22 and the like of the wiring structure 21. The first to fourth switching elements SW1a to SW4a and the first to fourth switching elements SW1b to SW4b arranged separately on both sides in the width direction of the substrate 22 are arranged so that the terminals tg, tc, and te sides face each other. Are inserted into the corresponding connection terminals 23e to 23h, 24e to 24h, 25a to 25d, 26a to 26d, 27a, 27b to 30a, and 30b of the wiring structure 21 from the lower side to the upper side by solder or the like. Be joined.

  Regarding the specific terminal connection mode, the first switching element SW1a has a collector terminal tc connected to the connection terminal 23e of the plus-side power supply bus bar 23, an emitter terminal te connected to the connection terminal 25a of the output plate 25, The gate terminal tg is connected to the connection terminal 27 a of the control input plate 27. The first switching element SW1b has a collector terminal tc connected to the connection terminal 23g of the positive power supply bus bar 23, an emitter terminal te connected to the connection terminal 25c of the output plate 25, and a gate terminal tg for control input. It is connected to the connection terminal 27 b of the plate 27.

  In the third switching element SW3a, the collector terminal tc is connected to the connection terminal 25b of the output plate 25, the emitter terminal te is connected to the connection terminal 24e of the minus power bus bar 24, and the gate terminal tg is the control input plate 28. To the connection terminal 28a. The third switching element SW3b has a collector terminal tc connected to the connection terminal 25d of the output plate 25, an emitter terminal te connected to the connection terminal 24g of the minus-side power supply bus bar 24, and a gate terminal tg for control input. The connection terminal 28 b of the plate 28 is connected.

  In the second switching element SW2a, the collector terminal tc is connected to the connection terminal 23f of the plus-side power supply bus bar 23, the emitter terminal te is connected to the connection terminal 26a of the output plate 26, and the gate terminal tg is the control input plate 29. To the connection terminal 29a. The second switching element SW2b has a collector terminal tc connected to the connection terminal 23h of the positive power supply bus bar 23, an emitter terminal te connected to the connection terminal 26c of the output plate 26, and a gate terminal tg for control input. The connection terminal 29 b of the plate 29 is connected.

  In the fourth switching element SW4a, the collector terminal tc is connected to the connection terminal 26b of the output plate 26, the emitter terminal te is connected to the connection terminal 24f of the minus power bus bar 24, and the gate terminal tg is the control input plate 30. To the connection terminal 30a. The fourth switching element SW4b has a collector terminal tc connected to the connection terminal 26d of the output plate 26, an emitter terminal te connected to the connection terminal 24h of the negative power bus bar 24, and a gate terminal tg for control input. Connected to the connection terminal 30 b of the plate 30.

  The connection terminal portion 23 c of the plus-side power supply bus bar 23 is connected to a plus-side power supply line (not shown) of the inverter circuit 11 (primary side of the insulating transformer 12), and the connection terminal portion 24 c of the minus-side power supply bus bar 24. Is connected to the negative power line (not shown). The output terminal portions 25g and 26g of the output plates 25 and 26 are connected to the primary coil 12a of the insulating transformer 12. Input terminal portions 27 c to 30 c of the control input plates 27 to 30 are connected to the control circuit 15. The connection terminal portions 23d and 24d of the power supply bus bars 23 and 24 and the connection terminal portions 25e and 26e of the output plates 25 and 26 are used for connection with optional elements and the like. In this embodiment, the power supply bus bar 23 is used. 24, the smoothing capacitor Ca is connected between the connection terminal portions 23d and 24d, and the connection terminal portions 25e and 26e of the output plates 25 and 26 are not used.

Next, the operation of the inverter circuit 11 using the switch module 20 having the above configuration will be described.
The input of DC power to the inverter circuit 11 is performed through the connection terminal portions 23c and 24c of the power supply bus bars 23 and 24. When DC power is input, the collector terminals tc of the first and second switching elements SW1a, SW1b, SW2a, and SW2b of the upper arm are set to a positive potential via the plus power bus bar 23, and the minus power bus bar. 24, the emitter terminals te of the third and fourth switching elements SW3a, SW3b, SW4a, SW4b of the lower arm are set to a negative potential (ground potential).

  A control signal from the control circuit 15 is input from the input terminal portions 27c to 30c of the control input plates 27 to 30, and is input to the gate terminals tg of the first to fourth switching elements SW1a, SW1b to SW4a, SW4b. Based on the control signal, the first and fourth switching elements SW1a, SW1b, SW4a, SW4b and the second and third switching elements SW2a, SW2b, SW3a, SW3b are alternately switched, and the input DC power is Converted to high frequency AC power.

  The converted high-frequency AC power is output to the output plate 25 to which the emitter terminals te of the first switching elements SW1a and SW1b and the collector terminals tc of the third switching elements SW3a and SW3b are connected, and to the second switching elements SW2a, Through the output plate 26 to which the emitter terminal te of SW2b and the collector terminals tc of the fourth switching elements SW4a, SW4b are connected, the output terminal portions 25g, 26g output to the subsequent circuit. Yes.

  In such a switching operation of the inverter circuit 11, in the power bus bars 23 and 24, the straight wiring portions 23 a and 24 a of the power bus bars 23 and 24 are parallel to each other, so that the direction of the main current flowing through them is reversed. The magnetic fields generated in the power bus bars 23 and 24 act so as to cancel each other. Therefore, the inductance of the power supply bus bars 23 and 24 is reduced along with the reduction of the radiation magnetic field.

  Further, since the flat plate portions 23b and 24b of the power bus bars 23 and 24 face each other with a predetermined distance between the planes, a parasitic capacitance is formed and a capacitance effect can be expected, and the inductance of the power bus bars 23 and 24 can be increased. Will contribute to the reduction. Further, by providing such flat plate portions 23b and 24b, the heat dissipation effect of the power bus bars 23 and 24 is improved. In this case, since heat is mainly radiated in a direction orthogonal to the plane of the flat plate portions 23b and 24b, a heat sink (not shown) is efficiently attached to the substrate 22 facing the flat surface (lower surface) of the flat plate portion 23b. It is possible to dissipate heat. The through holes 22a formed at the four corners of the substrate 22 are used for attachment to the heat sink and other members.

  In the control input plates 27 to 30, the control input plates 27 to 24 correspond to the main current flow of the power supply bus bars 23 and 24 (straight wiring portions 23 a and 24 a) through which a large current flows, that is, the power supply bus bars 23 and 24. Since the 30 signal transmission paths are configured to intersect substantially vertically, the influence of the radiated magnetic field on the control signal side at the power bus bars 23 and 24, which can be relatively large, is reduced, and problems such as malfunctions occur. It is prevented beforehand.

  In the output plates 25 and 26, as shown in FIG. 3, the distances L1 from the emitter terminals te to the output terminal portions 25g of the switching elements SW1a and SW1b connected in parallel in each arm are set to be equal distances. . In FIG. 3, the distance L1 is shown linearly to prevent the figure from becoming complicated, but the distance L1 is an actual power transmission path (output path) between two points. Similarly, the distances L2 from the emitter terminals te to the output terminal portions 26g of the switching elements SW2a and SW2b are equal, the distances L3 from the collector terminals tc of the switching elements SW3a and SW3b to the output terminal portions 25g are also equal, and the switching elements SW4a. , SW4b, the distances L4 from the collector terminal tc to the output terminal portion 26g are also set equal. Furthermore, distances L1 to L4 to the output terminal portions 25g and 26g among the first to fourth switching elements SW1a, SW1b to SW4a, and SW4b are set to be equal. That is, the output path inductance between the individual output terminals of the switching elements SW1a, SW1b to SW4a, SW4b and the output terminal portions 25g, 26g of the output plates 25, 26 is configured to be equal.

  As a result, the difference in output current / voltage transmission between the switching elements SW1a, SW1b to SW4a, SW4b is extremely small, so that the distortion of the generated high-frequency AC power is small. As a result, the high-frequency AC power output from the inverter circuit 11 is stabilized, and consequently contributes to stabilization of the output power of the DC-DC converter 10.

Next, characteristic effects of the present embodiment will be described.
(1) In the output plates 25 and 26 of the wiring structure 21, the output terminals 25g and 26g of the inverter circuit 11 from the output terminal (emitter terminal te or collector terminal tc) for each switching element SW1a, SW1b to SW4a and SW4b. The power transmission distances L1 to L4 to (output node) are configured to be equal. As a result, the inductances of the output paths of the switching elements SW1a, SW1b to SW4a, and SW4b are equal, so that the output current / voltage transmission differences among the switching elements SW1a, SW1b to SW4a, and SW4b are extremely small, and the inverter circuit 11 The high-frequency AC power output from the (bridge circuit) can be stabilized with little distortion, and the output power of the DC-DC converter 10 can be stabilized.

  (2) The plus-side and minus-side power supply bus bars 23 and 24 are configured such that the directions of main currents flowing through them are opposite to each other. Thus, the magnetic fields generated in the power bus bars 23 and 24 act so as to cancel each other, and the radiation magnetic field can be reduced and the inductance of the power bus bars 23 and 24 can be reduced.

  (3) Since the parasitic capacitance is formed by the flat plate portions 23b and 24b provided in the plus-side and minus-side power bus bars 23 and 24, the capacitance effect contributes to the reduction of the inductance of the power bus bars 23 and 24. be able to. Moreover, since the heat radiation area is expanded by the flat plate portions 23b and 24b, the heat radiation effect in the power bus bars 23 and 24 can be improved.

  (4) The control input plates 27 to 30 are configured such that their own signal transmission paths intersect the main current flow of the power supply bus bars 23 and 24. As a result, the influence of the radiated magnetic field on the control signal side at the power supply bus bars 23 and 24, which can be relatively large, can be reduced, and problems such as malfunctions can be prevented.

  (5) The switching elements SW1a, SW1b to SW4a, SW4b arranged in each arm of the inverter circuit 11 (bridge circuit) are configured by connecting two elements in parallel. The electric power between the output terminals (emitter terminal te or collector terminal tc) of the switching elements SW1a, SW1b to SW4a, SW4b paired for each arm and the output terminal portions 25g, 26g (output nodes) of the inverter circuit 11 The transmission distances L1, L2, L3, and L4 are set equal to each other. As a result, the inductances of the output paths are equal among the switching elements SW1a, SW1b to SW4a, SW4b connected in parallel for each arm, so that the output current / voltage of the switching elements SW1a, SW1b to SW4a, SW4b are equal to each other. Is extremely small and can contribute to stabilization of output power of the inverter circuit 11 (bridge circuit).

  (6) Since the switching elements SW1a, SW1b to SW4a, SW4b that make a pair for each arm are arranged on both sides of the wiring structure 21 and are arranged in parallel so as to face each other, the power source of the wiring structure 21 Various plate wirings such as bus bars 23 and 24, output plates 25 and 26, and control input plates 27 to 30 can be formed in a simple shape such as the same shape or symmetrical shape. It can contribute to downsizing.

  (7) The control input plates 27 to 30 for connecting the gate terminals tg (control terminals) of the switching elements SW1a, SW1b to SW4a and SW4b that make a pair for each arm are formed in the same shape. . Thereby, the control input plates 27 to 30 become one product number, and it is easy to perform component management and assembly.

(8) Since the control input plates 27 to 30 have a point-symmetric shape, they can be assembled even if they are rotated 180 degrees, and the complexity of the assembly can be reduced.
(9) The output plates 25 and 26 are formed in the same shape, particularly including the output path. Thereby, it can contribute to the improvement of the current balance between the plates 25 and 26 for output.

In addition, you may change embodiment of this invention as follows.
In the above embodiment, the shape, arrangement, fixing method, and the like of the power bus bars 23 and 24, the output plates 25 and 26, and the control input plates 27 to 30 of the wiring structure 21 may be appropriately changed.

  For example, with respect to the arrangement, the plus side power bus bar 23, the minus side power bus bar 24, the output plates 25 and 26, and the control input plates 27 to 30 are laminated in this order from the substrate 22 side. Not limited to this, it may be changed as appropriate.

Moreover, about the fixing method, although these were mutually fixed with the double-sided adhesive sheet, you may fix using an adhesive agent, a resin mold, etc., for example.
Further, regarding the shape, the power supply bus bars 23, 24 are provided with the flat plate portions 23b, 24b, but may be omitted.

  Further, the connection terminal portions 23d and 24d of the power supply bus bars 23 and 24 used for connecting the optional elements, the connection terminal portions 25e and 26e themselves of the output plates 25 and 26, and the related portions may be omitted. In this way, the output plates 25 and 26 can be formed in the same shape.

Further, although the control input plates 27 to 30 have the same shape and a point-symmetric shape, these shapes may not be adopted.
Further, although the terminal portions 23c, 23d, 24c, 24d, 25e, 26e, 25g, and 26g are male screws and the terminal portions 27c to 30c are male faston terminals, other terminal shapes may be adopted. .

  In the above embodiment, the IGBT is used for the switching elements SW1a, SW1b to SW4a, SW4b. However, other than the IGBT, for example, a MOS transistor or a bipolar transistor may be used.

  In the above embodiment, two switching elements SW1a, SW1b to SW4a, SW4b are connected in parallel for each arm of the inverter circuit 11 (bridge circuit), but each arm has only one switching element. Also good.

  In the above embodiment, the inverter circuit 11 is a single-phase inverter circuit, but may be a three-phase inverter circuit. In this case, for example, in the wiring structure 21, the power supply bus bars 23 and 24 are extended in the longitudinal direction, and one output plate, two control input plates, and two sets (four) of switching elements are added. For example, a three-phase inverter circuit can be similarly configured.

In the above embodiment, the present invention is applied to the inverter circuit 11 of the insulation type DC-DC converter 10, but it may be applied to an inverter circuit used for other devices.
Next, a technical idea that can be grasped from the above embodiment and another example will be added below.

(A) In a power conversion device configured by a bridge circuit using a plurality of switching elements and converting DC power into high-frequency AC power by switching operation of each switching element, the terminals of each switching element are connected to a plurality of plate wirings. The wiring structure used for the switch module of the power conversion device configured to be connected to the wiring structure comprising:
In the plate wiring connecting between the output terminal of each switching element arranged in the upper and lower arms of the bridge circuit and the output node of the bridge circuit, the power transmission distance to the output node for each switching element is A wiring structure used for a switch module of a power converter characterized by being configured to be equal.

  By connecting a switching element to such a wiring structure and configuring a switch module, the influence of the parasitic inductance in the output path for each switching element is small, which can contribute to the stabilization of the output power of the power converter.

11 Inverter circuit (bridge circuit)
20 Switch module 21 Wiring structure 23 Plus side power supply bus bar (plate wiring)
24 Negative power supply bus bar (plate wiring)
23b, 24b Flat plate part 25, 26 Output plate (plate wiring)
25g, 26g Output terminal (output node)
27-30 Plate for control input (Plate wiring)
SW1 to SW4 Switching element SW1a, SW1b to SW4a, SW4b Switching element tc Collector terminal (output terminal)
te Emitter terminal (output terminal)
tg Gate terminal (control terminal)
L1-L4 distance

Claims (8)

In a power conversion device configured by a bridge circuit using a plurality of switching elements and converting DC power into high-frequency AC power by switching operation of each switching element, a wiring structure in which terminals of each switching element are formed by a plurality of plate wirings A switch module of a power conversion device configured to be connected to the body,
In the plate wiring of the wiring structure that connects between the output terminal of each switching element disposed on the upper and lower arms of the bridge circuit and the output node of the bridge circuit, the output node for each switching element is connected to the output node. It is configured by setting the power transmission distance equal .
A control input plate is used as the plate wiring of the wiring structure, and a control signal is input to the control terminal of the switching element through the control input plate.
Each of the switching elements disposed in each arm of the bridge circuit is formed by connecting two switching elements in parallel.
The control input plate for connecting between control terminals of each switching element paired for each arm is provided for each arm, and is formed in the same shape. Switch module of conversion device. In the switch module of the power converter according to claim 1,
As the plate wiring of the wiring structure, plus side and minus side power bus bars are used, and the DC power is input to the bridge circuit via each power bus bar,
Each of the power bus bars is configured such that the directions of main currents flowing through the power bus bars are opposite to each other. In the switch module of the power converter according to claim 2,
A switch module of a power conversion device, wherein the plus side and minus side power supply bus bars are provided with flat plate portions that face each other and form a parasitic capacitance. In the switch module of the power converter according to claim 2 or 3 ,
Switch module before Symbol control input plate, the power conversion apparatus characterized by signal transmission path itself is configured to intersect the flow of the main current of the bus bar each supply. In the switch module of the power converter device according to any one of claims 1 to 4,
Switch module of the power conversion apparatus characterized by being configured by setting equal the power transmission distance between the output terminal and the output node of the switching elements in the pair for each of the arms. In the switch module of the power converter device according to any one of claims 1 to 5 ,
Each switching element which makes a pair for every said arm is arrange | positioned on both sides which pinched | interposed the said wiring structure, and was arranged in parallel so that it might mutually oppose, The switch module of the power converter device characterized by the above-mentioned. In the switch module of the power converter according to any one of claims 1 to 6 ,
The switch module of a power conversion device, wherein the control input plate is formed in a point-symmetric shape. In the switch module of the power converter of any one of Claims 1-7 ,
An output plate having the output node is used as the plate wiring of the wiring structure, and output terminals of the switching elements of the upper and lower arms are connected to output the high-frequency AC power from the output node.
The power conversion device switch module according to claim 1, wherein the output plate is provided for each of the upper and lower arms and is formed in the same shape.

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