JP2019013058A - Inverter device - Google Patents

Abstract

To facilitate assembly operation of an inverter device.SOLUTION: A serial multiple inverter device 1 outputs a multistep voltage by connecting the output side of each inverter unit 3 in series thereby superimposing the outputs of respective inverter units 3. An output terminal 9 of the inverter unit 3 is stood upright on the top face of the inverter unit 3, and an output terminal 10 of the inverter unit 3 is stood upright on the undersurface of the inverter unit 3. Input terminals 6 to 8 are aligned in insertion/extraction direction of the inverter unit 3 at one side of the inverter unit 3, and connection terminals 16 to 18 connected with the input terminals 6 to 8 are provided on a board side. A combination of the output terminal 9, 10 (and the input terminals 6 to 8 and the connection terminals 16 to 18) has an engagement structure connectable in the insertion/extraction direction of the inverter unit 3. The inverter unit 3 is inserted into a board frame 4, and thereby the adjacent output terminal 9, 10 of the inverter unit 3 are connected with each other.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an inverter device. In particular, the present invention relates to a serial multiple inverter device having a structure in which output sides of single-phase inverters are connected in series.

  A serial multiple inverter outputs a multi-stage voltage by superimposing the outputs of each inverter unit by connecting in series a single-phase inverter composed of a single-phase bridge circuit called an inverter unit (or cell unit). be able to.

For example, in the serial multiple inverter device 21 having three single-phase inverter units U ₁ , U ₂ , U ₃ as shown in FIG. 7, the inverter units U ₁ , U ₂ , U ₃ are arranged in the housing 22. Be placed. As shown in FIG. 8, the wiring on the AC side and the output side of the inverter units U ₁ , U ₂ , U ₃ arranged side by side is performed by fixing bus bars and cables with bolts on the front surface of the housing 22.

  As a method for facilitating the connection between the connection terminal provided on the housing side and the terminal of the inverter unit housed in the housing, there is a method of connecting the terminals by press fitting or the like (for example, Patent Literature 1, 2).

JP 2013-126263 A JP 2010-148193 A Japanese Utility Model Publication No. 05-018205 JP 2007-027033 A

  Conventionally, an input terminal and an output terminal of an inverter unit are arranged on the front side of the casing, and the connection between the inverter units is performed by a bus bar or an electric wire.

  As described above, since the input / output terminal of the inverter unit needs to be arranged on the front side of the housing due to the problem of the board wiring work, restrictions on the layout of the unit parts and additional members are required, which may increase the unit size. There is. Furthermore, since the control board component layout and wiring space can be restricted, the board size may increase.

  In addition, when connecting the output terminals of the inverter units arranged on the front side of the housing to each other and the power input terminals with bus bars or electric wires, it is necessary to connect the terminals, which may increase the maintenance time. There is.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an inverter unit connection structure that facilitates assembly work of an inverter device.

One aspect of the inverter device of the present invention that achieves the above object is as follows.
A plurality of inverter units that output a single phase; and a housing in which the inverter units are slidably housed, and the output sides of two or more inverter units of the inverter units are connected in series. An inverter device,
The inverter units connected in series are juxtaposed in the housing,
The inverter unit includes a first output terminal projecting in the direction of another inverter unit arranged in parallel, and a second output terminal projecting in a direction opposite to the projecting direction of the first output terminal,
When the inverter unit is housed in the housing, the first output terminal is connected to an output terminal of another inverter unit adjacent to the protruding direction of the first output terminal, and the second output terminal is connected to the first output terminal. It is connected to the output terminal of the other inverter unit adjacent to the protrusion direction of 2 output terminals, or the connection terminal provided in the said housing | casing.

Another aspect of the inverter device of the present invention that achieves the above object is the above inverter device,
The inverter unit includes a plurality of input terminals protruding from a wall surface in a direction perpendicular to the sliding direction of the inverter unit,
The input terminals are arranged side by side in the sliding direction of the inverter unit,
The housing is provided with a connection terminal connected to the input terminal,
One terminal of the input terminal and the connection terminal connected to the input terminal includes a first plate member provided in parallel with the sliding direction of the inverter unit,
The other terminal among the connection terminals connected to the input terminal and the input terminal is provided in parallel with the sliding direction of the inverter unit, and a pair of second plate members from which the first plate member can be put in and out, And a pressing member that is provided on each of the opposing wall surfaces of the second plate member and presses the first plate member provided between the second plate members.

Another aspect of the inverter device of the present invention that achieves the above object is the above inverter device,
The first output terminal, the output terminal of another inverter unit connected to the second output terminal, or the connection terminal provided on the housing is a third plate member provided parallel to the sliding direction of the inverter unit. With
The output terminal of the other inverter unit connected to the first output terminal and the second output terminal are provided in parallel with the sliding direction of the inverter unit, and a pair of fourth terminals through which the third plate member can enter and exit. It is characterized by comprising a plate member and a pressing member that is provided on each of the opposing wall surfaces of the fourth plate member and presses the third plate member provided between the fourth plate members.

  According to the above invention, the assembly work of the inverter device is facilitated.

It is a principal part front view of the inverter apparatus which concerns on embodiment of this invention. It is a circuit block diagram of an inverter unit. (A) Perspective view of inverter unit, (b) Front view of inverter unit. It is a principal part enlarged view of an inverter apparatus. (A) The top view of the output terminal 9 (male side output terminal), (b) The side view of the output terminal 9 (male side output terminal). (A) Perspective view of output terminal 10 (female side output terminal), (b) Top view of output terminal 10 (female side output terminal). It is a circuit block diagram of the inverter apparatus which concerns on a prior art. It is a principal part front view of the inverter apparatus which concerns on a prior art.

  An inverter device according to an embodiment of the present invention will be described in detail based on the drawings. In the description of the embodiment, for convenience of explanation, the side on which the opening into which the inverter unit is inserted (or pulled out) is formed will be described as the front side of the inverter device. The present invention is not limited at all. That is, the position where the opening is formed may be any of the front surface and the side surface of the inverter device.

  As shown in FIG. 1, the inverter device 1 according to the embodiment of the present invention includes a housing 2 and a plurality of inverter units 3 provided in the housing 2. The inverter device 1 is a series multiple inverter that has a configuration in which the output side of an inverter unit 3 having a single-phase inverter circuit is connected in series, and outputs a multi-stage voltage in which outputs of the inverter units 3 connected in series are superimposed. is there.

  The housing 2 includes, for example, a panel frame 4, and the inverter unit 3 is supported on the panel frame 4. One of the panel frames 4 is formed with an opening through which the inverter unit 3 can be inserted and removed. The board frame 4 is provided with a rail 5 extending from the opening in the insertion / extraction direction of the inverter unit 3 (paper surface direction in the figure). The inverter unit 3 is slid (slid) on the rail 5, and the inverter unit 3 is attached to (or removed from) the panel frame 4.

  A plurality of inverter units 3 are provided in each phase (U phase, V phase, W phase). The number of inverter units 3 is set as appropriate according to the circuit constituting the inverter device 1. For example, in the inverter apparatus 1, the example in which the five inverter units 3 are provided in one phase (for example, U phase) is shown. In FIG. 1, the inverter unit 3 constituting another phase (for example, V phase and W phase) is not shown. Since the configuration and mounting manner of the inverter unit 3 of the other phases (for example, the V phase and the W phase) are the same as those of the illustrated inverter unit 3 of one phase, detailed description thereof is omitted. In the case of the circuit configuration as shown in FIG. 7, the inverter device 21 is provided with three inverter units 3 for each phase (U phase, V phase, W phase).

  As shown in FIG. 2, the inverter unit 3 includes input terminals 6 to 8 and output terminals 9 and 10. The inverter unit 3 is configured by including a diode 12, a smoothing capacitor 13, an IGBT 14 (switching element), a heat sink (not shown), and the like in a housing 11. In the inverter unit 3, a bridge circuit is formed by four IGBTs 14. A three-phase input power supply 15 is connected to the input terminals 6 to 8. The power input from the input power supply 15 is rectified by the diode 12 and input to the bridge circuit. A predetermined single-phase alternating current is output from the output terminals 9 and 10 by the switching operation of the IGBT 14.

  As shown in FIG. 3A, input terminals 6 to 8 are provided on the side wall in the direction perpendicular to the insertion / extraction direction of the inverter unit 3 (hereinafter referred to as the unit insertion / extraction direction). As shown in FIG. 4, the housing 2 is provided with connection terminals 16 to 18, and input terminals 6 to 8 are connected to the connection terminals 16 to 18. In addition, in the example of Fig.3 (a), although it becomes the aspect by which the connection terminals 16-18 of a panel side are inserted / extracted between the input terminals 6-8 of the inverter unit 3, the input terminals 6-8 and a connection terminal The shape of 16-18 can be reversed and the input terminal by the side of the inverter unit 3 can also be inserted / extracted between the connection terminals by the side of a board.

  The input terminals 6 to 8 are arranged side by side in the unit insertion / extraction direction. That is, the input terminals 6 to 8 are arranged on the side surface of the inverter unit 3 in a row at the same height with respect to the unit insertion / extraction direction. In the portion of the inverter unit 3 where the input terminals 6 to 8 are provided, a step 19 (escape portion) extending in the unit insertion / extraction direction is formed, and the connection terminals 16 to 18 connected to the input terminals 6 to 8 are input. It does not collide with any place other than the terminals 6-8.

  As shown in FIG. 3B, the output terminal 9 protrudes from the upper surface of the inverter unit 3, and the output terminal 10 protrudes from the lower surface of the inverter unit 3. As shown in FIG. 4, when the inverter unit 3 is provided on the panel frame 4, the output terminal 10 of the upper inverter unit 3 is connected to the output terminal 9 of the lower inverter unit 3 in the inverter units 3 adjacent to each other in the vertical direction. As a result, the output sides of the inverter units 3 that are vertically adjacent to each other are connected in series. The output terminal 9 (or output terminal 10) of the inverter unit 3 disposed at the upper end (or lower end) of the panel frame 4 is a connection terminal (not shown) disposed on the housing 2 (panel) side. Connected to.

  As shown in FIG. 3B, the output terminal 9 includes a plate member (a fitting portion 9a described in detail later), and is erected on the upper surface of the inverter unit 3 so as to be parallel to the unit insertion / extraction direction. On the other hand, the output terminal 10 is provided with a pair of plate members (a plate member 10a to be described in detail later) through which the output terminal 9 can enter and exit, and is erected on the lower surface of the inverter unit 3 so as to be parallel to the unit insertion / extraction direction. . In the portion of the inverter unit 3 where the output terminal 10 is provided, a step 20 (escape portion) extending in the unit insertion / extraction direction is formed, and the output terminal 9 of another inverter unit 3 connected to the output terminal 10 is It does not collide with any place other than the output terminal 10. In the inverter unit 3 shown in FIG. 3B, the output terminal 9 is inserted and removed between the output terminals 10, but the shape of the output terminal 9 and the output terminal 10 is reversed, and the inverter unit The output terminal provided on the lower surface of the inverter unit 3 may be inserted and removed between the output terminals provided on the upper surface of the inverter 3.

  Here, the shape of the output terminals 9 and 10 will be described in detail with reference to FIGS. The shapes of the input terminals 6 to 8 and the connection terminals 16 to 18 on the board side can be the same structure as the output terminals 9 and 10. Therefore, detailed description of the structures of the input terminals 6 to 8 and the connection terminals 16 to 18 is omitted.

  As shown in FIG. 5, the output terminal 9 includes a fitting portion 9 a erected from the upper surface of the inverter unit 3 and a fixing portion 9 b provided at an end portion of the fitting portion 9 a. The fixing part 9 b is fixed to the upper surface of the inverter unit 3 or a circuit part in the inverter unit 3. Notches 9c are formed on both sides of the tip of the fitting portion 9a, and the notches 9c are chamfered. The output terminal 9 is guided to a predetermined position of the output terminal 10 by the notch 9c, and the connection between the output terminal 9 and the output terminal 10 is smoothly performed.

  As shown in FIG. 6, the output terminal 10 includes a pair of plate members 10a through which the fitting portions 9a of the output terminals 9 can enter and exit, a fixing portion 10b that supports the plate member 10a, and a spring member provided on the plate member 10a. 10c.

  The plate member 10a is provided substantially parallel to the unit insertion / extraction direction. The plate members 10 a are arranged such that the distance between the plate members 10 a (that is, the opening dimension W 0) is equal to or greater than the thickness t of the fitting portion 9 a of the output terminal 9. Moreover, the opening dimension Wc including the height hs (height in the protruding direction) of the spring member 10c is set to be equal to or less than the thickness t of the fitting portion 9a. A guide portion 10d is formed at the opening end of each plate member 10a. The guide part 10d is formed so that the opening part in the unit insertion / extraction direction between the plate members 10a becomes wider as it goes to the end part. By forming the guide portion 10d, the output terminal 9 is guided to a predetermined position of the output terminal 10, and the connection between the output terminal 9 and the output terminal 10 is smoothly performed.

  Each of the spring members 10c is provided on the wall surface of the facing plate member 10a in a state of being bent so as to be convex in the direction of the facing plate member 10a, for example. That is, the spring member 10c is bent so that the central portion is convex, and the end portions in the unit insertion / extraction direction are fixed to the wall surface of the plate member 10a. When the fitting part 9a is provided between the plate members 10a, the spring member 10c has a shape having elasticity so that a sufficient reaction force can be obtained because the plate member 10a and the fitting part 9a can be conducted. Yes. Further, the spring member 10c has a curved surface with respect to the insertion / extraction direction of the fitting portion 9a, and the spring member 10c has a curved surface in either the insertion / extraction direction A or the insertion / extraction direction B indicated by a white arrow in the drawing. Insertion and extraction are possible. The insertion / removal direction A indicates the direction when the inverter unit 3 is inserted / removed, and the insertion / removal direction B indicates the direction when the adjacent inverter unit 3 is inserted / removed.

  As shown in FIG. 4, the inverter unit 3 is attached by inserting the inverter unit 3 from the opening of the panel frame 4.

  When the inverter unit 3 is moved in the insertion direction from the front of the housing 2 along the rail 5 provided on the panel frame 4, the connection terminal 16 (U phase) and the input terminal 8 (W phase) on the panel side are fitted. To do. Subsequently, when the inverter unit 3 is inserted, the connection terminal 16 (U phase) and the input terminal 8 (W phase) are disengaged, and the panel side connection terminal 17 (V phase) and the input terminal 8 (W phase) are connected. The board-side connection terminal 16 (U phase) and the input terminal 7 (V phase) are fitted. Further, when the inverter unit 3 is inserted, the connection terminal 17 and the input terminal 8 (and the connection terminal 16 and the input terminal 7) are disengaged again, and the inverter unit 3 is inserted to a predetermined position. When the inverter unit 3 is inserted to a predetermined position, the input terminals 6 to 8 and the connection terminals 16 to 18 (U phase, V phase, W phase) corresponding to the input terminals 6 to 8 are fitted. Thus, by inserting the inverter unit 3 into the board frame 4, the input terminals 6 to 8 and the connection terminals 16 to 18 corresponding to the phases of the input terminals 6 to 8 are connected. When removing the inverter unit 3, the connection between the input terminals 6 to 8 and the connection terminals 16 to 18 is disconnected by an operation reverse to the insertion operation of the inverter unit 3, and the inverter unit 3 is pulled out from the panel frame 4.

  Further, when the inverter unit 3 is moved in the insertion direction from the front surface of the housing 2 along the rail 5 provided in the panel frame 4, the output terminal 9 of the inverter unit 3 is connected to the other side of the inverter unit 3. The inverter unit 3 is inserted between the plate members 10a of the output terminals 10 and contacts the spring member 10c. And the spring member 10c deform | transforms and the output terminal 9 of the inverter unit 3 and the output terminal 10 of the inverter unit 3 provided above this inverter unit 3 are electrically connected. At this time, even if the positions of the output terminal 9 and the output terminal 10 are slightly shifted, the output terminal 9 (in the predetermined fitting position at the notch portion 9c of the output terminal 9 and the guide portion 10d of the output terminal 10). Alternatively, the output terminal 10) is guided.

  On the other hand, the output terminal 10 of the inverter unit 3 moves so as to sandwich the output terminal 9 of another inverter unit 3 provided on the lower side of the inverter unit 3, and the output terminal 9 contacts the spring member 10 c of the output terminal 10. To do. And the spring member 10c deform | transforms and the output terminal 10 of the inverter unit 3 and the output terminal 9 of the inverter unit 3 with which this inverter unit 3 is provided are electrically connected.

  Even when the inverter unit 3 or another inverter unit 3 adjacent to the upper and lower sides of the inverter unit 3 is extracted, the inverter unit provided on the lower side of the inverter unit 3 by the step 20 provided on the casing 11 of the inverter unit 3. 3 (and the output terminal 10 of the inverter unit 3 provided on the upper side of the inverter unit 3) does not interfere with the inverter unit 3, and can be extracted by the reverse operation described above.

  According to the inverter device 1 of the present invention as described above, by mounting the inverter unit 3 on the housing 2, the connection between the output terminals 9, 10 of the adjacent inverter unit 3 and the input terminal 6 of the inverter unit 3. ˜8 can be electrically connected to the connection terminals 16 to 18 on the panel side, so that the work at the time of manufacturing the inverter device 1 and maintenance replacement can be shortened.

  In particular, one terminal of the output terminals 9 and 10 includes a structure that pressurizes the other output terminals 9 and 10 connected to the output terminals 9 and 10, so that the output terminal of the inverter unit 3 connected in series is provided. 9 and 10 can be directly connected.

  Further, by inserting the inverter unit 3 into a predetermined position of the panel frame 4, the connection between the input terminals 6 to 8 and the connection terminals 16 to 18 and the connection between the output terminals 9 and 10 are performed. Processes that require human hands are reduced, and forgetting to connect and wiring mistakes can be reduced. And even if it is set as the structure which has arrange | positioned the input / output terminal in the panel back side etc. which an operator cannot access, the electrical connection of the connection terminal and input terminal (or output terminal) of a housing | casing side becomes easy.

  Furthermore, since it is not necessary to secure the worker's access and work space when replacing the unit, the degree of freedom of the component layout of the inverter unit 3 is increased, and the optimum layout becomes possible. In addition, since the output terminals 9 and 10 of the adjacent inverter units 3 can be directly connected, connection parts for connecting the output terminals 9 and 10 are not required. As a result, the number of parts can be reduced, and the inverter device 1 and the inverter unit 3 can be downsized.

  Moreover, since the input terminals 6-8 can be arrange | positioned on the same line in the unit insertion / extraction direction, the freedom degree of component layout becomes higher.

  Further, by providing the plate member 10a of the output terminal 10 with the spring member 10c, the output terminal 9 provided between the plate members 10a of the output terminal 10 can be pressurized at multiple points (surfaces). Thus, since the contact area of the output terminal 9 and the output terminal 10 can be enlarged, the connection reliability of the output terminal 9 and the output terminal 10 improves.

  Furthermore, a fitting structure capable of connecting the combination of the input terminals 6 to 8 and the connection terminals 16 to 18 and the combination of the output terminal 9 and the output terminal 10 by insertion / removal from two directions of the unit insertion direction and the unit extraction direction, By doing so, the connection between the output terminals 9 and 10 of the inverter unit 3 adjacent at the time of board mounting and the connection between the input terminals 6 to 8 and the connection terminals 16 to 18 can be performed.

  In particular, the combination of the output terminals 9 and 10 that connect the output side of the inverter unit 3 in series is a pair of parallel plates through which a plate-like electrode terminal (so-called male-side electrode terminal) and a plate-like electrode terminal can enter and exit. The output terminals 9 and 10 can be connected from both directions of the insertion direction and the extraction direction of the inverter unit 3. As a result, even when a plurality of inverter units 3 are connected to each other, the order in which the inverter units 3 are mounted on the panel frame 4 can be configured without any restrictions.

  In addition, when the fitting structure as shown in Patent Document 1 (for example, the fitting structure as shown in FIG. 7 of Patent Document 1) is applied to the output terminal that connects the output side of the inverter unit, the inverter unit is a unit. It has a structure having a female side connection part having an opening in the drawing direction and a male side connection part inserted into the female side connection part. As a result, when pulling out the inverter unit, the female side connecting portion interferes with the male side connecting portion of the connection destination unit, and thus the order of pulling out the inverter unit is limited.

  Although the inverter device of the present invention has been described with reference to a specific embodiment, the inverter device of the present invention is not limited to the embodiment, and the design can be changed as appropriate without departing from the characteristics of the inverter device. Those whose design has been changed also belong to the technical scope of the present invention.

  For example, the plate member 10a and the spring member 10c may not be separate components, and the plate member 10a may have a structure having an elastic force and other spring portions.

DESCRIPTION OF SYMBOLS 1 ... Inverter apparatus 2 ... Housing 3 ... Inverter unit 4 ... Board frame 5 ... Rails 6-8 ... Input terminal 9 ... Output terminal (1st output terminal)
9a ... fitting part (first and third plate members), 9b ... fixed part, 9c ... notch part 10 ... output terminal (second output terminal)
DESCRIPTION OF SYMBOLS 10a ... Plate member (2nd, 4th plate member), 10b ... Fixed part, 10c ... Spring member (pressing member), 10d ... Guide part 11 ... Case 12 ... Diode 13 ... Smoothing capacitor 14 ... IGBT
15 ... Input power source 16-18 ... Connection terminals 19, 20 ... Step

Claims (3)

A plurality of inverter units that output a single phase; and a housing in which the inverter units are slidably housed, and the output sides of two or more inverter units of the inverter units are connected in series. An inverter device,
The inverter units connected in series are juxtaposed in the housing,
The inverter unit includes a first output terminal projecting in the direction of another inverter unit arranged in parallel, and a second output terminal projecting in a direction opposite to the projecting direction of the first output terminal,
When the inverter unit is housed in the housing, the first output terminal is connected to an output terminal of another inverter unit adjacent to the protruding direction of the first output terminal, and the second output terminal is connected to the first output terminal. 2. An inverter device, wherein the inverter device is connected to an output terminal of another inverter unit adjacent to the projecting direction of the two output terminals or a connection terminal provided in the housing. The inverter unit includes a plurality of input terminals protruding from a wall surface in a direction perpendicular to the sliding direction of the inverter unit,
The input terminals are arranged side by side in the sliding direction of the inverter unit,
The housing is provided with a connection terminal connected to the input terminal,
One terminal of the input terminal and the connection terminal connected to the input terminal includes a first plate member provided in parallel with the sliding direction of the inverter unit,
The other terminal among the connection terminals connected to the input terminal and the input terminal is provided in parallel with the sliding direction of the inverter unit, and a pair of second plate members from which the first plate member can be put in and out, The inverter according to claim 1, further comprising: a pressing member that is provided on each of the opposing wall surfaces of the second plate member and presses the first plate member provided between the second plate members. apparatus. The first output terminal, the output terminal of another inverter unit connected to the second output terminal, or the connection terminal provided on the housing is a third plate member provided parallel to the sliding direction of the inverter unit. With
The output terminal of the other inverter unit connected to the first output terminal and the second output terminal are provided in parallel with the sliding direction of the inverter unit, and a pair of fourth terminals through which the third plate member can enter and exit. The plate member and a pressing member that is provided on each of the opposing wall surfaces of the fourth plate member and presses the third plate member provided between the fourth plate members, respectively. Or the inverter apparatus of Claim 2.

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