JPWO2020166000A1 - Power converter - Google Patents

Abstract

The power conversion device has a power module having terminals and a power module mounting board having through holes into which terminals are inserted, and the power module mounting board has wiring patterns arranged inside and outside and wiring patterns. It has an insulating layer that insulates between them, and a solder pool that stores solder.

Description

The present invention relates to a power conversion device including a power module mounting board connected to a power module.

Conventionally, Patent Document 1 is known as a technique of inserting an external connection terminal into a through hole of a wiring board and joining the external connection terminal with molten solder. Patent Document 1 discloses a technique for suppressing a solder bridge by inserting an external connection terminal such as a connector into a through hole and defining a distance between lands when soldering.

JP-A-2018-101756

Patent Document 1 discloses a land structure that suppresses solder bridges and has high solder connection reliability. However, in the soldering method, solder is jetted into a molten solder bath, and a wiring board is formed on the molten solder that has been jetted. The flow soldering method of immersing the solder is used.

In a power conversion device, connection technology such as screwing of a terminal and a metal bar is used for the path through which a large current flows, and in a large current component such as a power module, the terminal and the printed circuit board are solder-bonded. .. Further, since the power module has a large heat capacity, it is difficult to mount it on a multilayer board such as a printed circuit board, and it is mounted separately from the printed circuit board. It is difficult to solder the terminals of the power module in the through holes of the printed circuit board of another component by the above flow soldering method.

When soldering is used to connect the terminals of high-current components such as power modules to the through-holes on the printed circuit board, at least between the through-hole surface plating and the terminals to prevent an increase in electrical resistance in the through-holes. It is necessary to fill with solder at least 75% of the through-hole depth. On the other hand, in order to supply a large current without loss, it is necessary to connect the multilayer wiring in a plurality of via holes while performing the multilayer wiring in the substrate with the solid copper foil of the multilayer substrate.

It can be said that this is an excellent structure in terms of heat dissipation as a product. However, from the viewpoint of the manufacturing process of solder bonding, the heat dissipation rate from the through hole to the solid copper foil (multilayer wiring) is too fast, so the molten solder is cooled before it is sufficiently filled between the through hole and the terminal. And it hardens in the middle of the through hole. As a result, sufficient connection for passing a large current cannot be secured, and problems of heat generation and heat dissipation of the terminal joint may occur during circuit operation.

Further, as a method of sufficient solder filling, there are application of a large heat capacity soldering iron and heating for a long time, but both of them have poor workability in component mounting and cause great heat damage to the printed circuit board.

An object of the present invention is to suppress a temperature rise of a power converter having a power module mounting board having a through hole into which a terminal of the power module is inserted.

A preferred example of the present invention is a power conversion device having a power module having terminals and a power module mounting board having a through hole into which the terminals are inserted.
The power module mounting board is
It is a power conversion device having a wiring pattern arranged inside and outside, an insulating layer that insulates between the wiring patterns, and a solder pool that stores solder.

According to the present invention, it is possible to suppress a temperature rise of a power conversion device having a power module mounting board having a through hole into which a terminal of the power module is inserted.

The figure explaining the power conversion apparatus of Example 1. FIG. The figure explaining the power conversion apparatus of Example 2. FIG. The figure explaining the power conversion apparatus of Example 3. FIG. The flow from the production of the printed circuit board to the completion of the mounting board. The figure explaining the manufacturing process of a printed circuit board. Explanatory drawing of the printed circuit board of the comparative example. The figure explaining the case which used the printed circuit board of the comparative example. The figure which shows the circuit structure of the power conversion apparatus in Example 1. FIG. It is a block diagram before assembling the power conversion apparatus of Example 1. FIG. It is a block diagram after assembling the power conversion apparatus of Example 1. FIG.

Hereinafter, examples of the present invention will be described in detail with reference to the drawings.

A configuration example of the power conversion device will be described with reference to FIGS. 1 to 10.

FIG. 1 is a diagram for explaining the power conversion device of the first embodiment, and specifically, is a state in which the component pad 8, the through hole 7, and the power module terminal 12 in the printed circuit board 1 are soldered. .. The printed circuit board 1 on which the components are mounted has a configuration in which circuits such as a control circuit and a drive circuit of a power conversion device are mounted on a bare board and connected to the power module 11.

The printed circuit board 1 includes copper foils 2a and 2b, vias 6 having copper plating 4 on the inner surface, through holes 7, solder reservoirs 31, component pads 8 formed by etching copper foil, and wiring (not shown). It has an insulating layer 3 that insulates between the copper foils 2a and 2b constituting the pattern, a solder resist 5, and silk 9. Here, the through hole 7 is a through hole having an inner surface made of copper plating 4 and penetrating the power module terminal 12 connected to the element in the power module 11. The solder reservoir 31 is formed by inserting a counterbore in an area including the through hole 7, and stores the solder 21.

The through hole 7 is provided for the purpose of electrically conducting the component pads 8 formed on the front and back surfaces of the printed circuit board 1, the external wiring pattern, and the internal wiring pattern.

The solder pool 31 has a depth that reaches the inner layer copper foil 2b of the first layer from the upper surface of the printed circuit board 1, thereby increasing the connection area between the solder 21 and the inner layer copper foil 2b.

The power module terminal 12 provided in the power module 11 is passed through the solder pool 31, and the bottom of the solder pool 31 and the through hole 7 are connected to each other. Further, by filling solder between the copper plating 4 on the inner surface of the through hole 7 and the power module terminal 12, the power module terminal 12 and the wiring such as the copper foils 2a and 2b are electrically conductive and fixed. ..

Further, when the printed circuit board has a core layer, the solder filling depth can be made sufficiently deeper than the length of the through hole by setting the depth of the solder reservoir 31 to reach the core layer. Therefore, the electric resistance between the power module terminal 12 and the wiring can be lowered, and it becomes easy to suppress heat generation during operation. Further, when the solder pool reaches the core layer, the electric resistance can be lowered even for a multi-layered thick printed circuit board in the same manner as described above, and it becomes easy to suppress heat generation during operation.

FIG. 4 is a flow showing the flow of the manufacturing process (S40 to S45) of the printed circuit board 1 (bare board) in the power module mounting board 81 and the component mounting process (S46) on the printed circuit board 1.

The base material charging step (S40) for preparing the base material such as the printed circuit board 1 and the components to be mounted is executed.

Then, as shown in FIG. 5A, a drilling step (S41) such as a through hole 7 or a via 6 is executed on the printed circuit board.

Then, as shown in FIG. 5B, the counterbore step (S42) for forming the solder pool 31 is executed.

Then, as shown in FIG. 5C, a copper plating step (S43) of applying copper plating 4 to the front and back surfaces of the printed circuit board 1 and the inner walls of holes such as through holes 7 and vias 6 is executed.

Then, as shown in FIG. 5D, an etching step (S44) for etching the wiring pattern on the surface of the printed circuit board and the component pad 8 is executed.

Then, as shown in FIG. 5 (e), a resist applying step of applying the solder resist 5 and a resist-silk printing step (S45) of printing silk are executed.

Then, as shown in the examples of FIGS. 1, 2 and 3, the solder is locally heated and melted in the solder pool in which the solder is stored by the soldering iron, and the through hole 7 is filled with the solder. The soldering step (S46) for joining the power module terminal 12 and the inner surface of the through hole is executed. Then, the power module mounting board 81 is completed (S47).

The manufacturing process of the printed circuit board 1 provided with the copper foils 2a and 2b and the component pad 8 which are wiring patterns will be described with reference to FIGS. 5A to 5E.

In the substrate loading process, the printed circuit board 1 is initially in the state of a copper-clad plate in which copper foil is stretched over the entire front and back surfaces, and in the case of a double-sided two-layer substrate, it is also called a substrate. In the case of a multilayer printed circuit board, an inner layer in which a wiring pattern is formed is combined inside the printed circuit board 1.

In the drilling process, drilling as shown in FIG. 5A is performed to form a via 6 for interlayer connection to the printed circuit board 1 or a through hole 7 for mounting component terminals such as power module terminals. I do.

Further, a counterbore processing step as shown in FIG. 5B is performed so that the solder reservoir 31 that stores the solder to be filled in the through hole 7 has a depth that reaches the inner layer copper foil 2b.

In the copper plating process, copper plating 4, which is a conductor, is applied to the inner walls of holes such as through holes 7 and vias 6 as shown in FIG. 5 (c) in order to conduct the circuit with the front and back of the printed circuit board or the inner layer of the multilayer board. ..

In the etching process, the wiring pattern on the surface of the printed circuit board and the component pad 8 for soldering the component terminals such as the power module terminal and the wiring pattern do not require the copper foil stretched on the front and back of the printed circuit board 1 by etching or the like. It is formed as shown in FIG. 5D by removing the copper foil.

In the resist coating process, as shown in FIG. 5 (e), in order to prevent solder from adhering to wiring patterns other than the component pad 8 when the component pad 8 and the power module terminal 12 are joined by soldering. 5 is coated with solder resist.

In the silk printing process, information on parts such as component outlines and component symbols is printed on the surface of the printed circuit board on the front or back surface of the printed circuit board, as in the case of silk 9. Using this printed circuit board 1, the conductor on the inner surface of the through hole 7 and the power module terminal 12 are joined using the solder 21, and the power conversion device shown in FIG. 1 is manufactured.

Here, the printed circuit board 1 manufactured without applying the present embodiment will be described. The printed circuit board 1 of FIG. 6 is different from FIG. 5 (e) in that there is no solder reservoir 31 in which the solder 21 is stored. The printed circuit board 1 is soldered to the power module 11 to form a power module mounting board 81 which is a comparative example shown in FIG. 7.

As shown in FIG. 7, when the length of the through hole is a, the solder filling depth is b. In order not to cause problems of heat generation and heat dissipation of the terminal portion during circuit operation, it is necessary that b is 75% or more with respect to a. To join the copper plating layer on the inner surface of the through hole 7 of the printed circuit board 1 and the power module terminal 12 with solder 21, the initial molten solder 21 melted with the soldering iron 51 or the soldering iron 51 is used to connect the power module terminal 12 and the through. The holes 7 must be warmed above the solder melting point temperature required for solder penetration. The power module terminal 12 transfers the heat of the solder iron 51 or the initial molten solder 21 melted by the solder iron 51 to the power module 11 having a lower temperature.

Further, the heat of the solder iron 51 and the initial molten solder 21 melted by the solder iron 51 is transferred to the outer layer copper foil 2a and the inner layer copper foil 2b having a lower temperature via the through hole 7. At this time, when the power module 11 is a component having a large heat capacity, or when the through hole 7 is connected to the solid copper foil, the component having a large heat capacity or the solid copper foil has high heat retention, so that the soldering iron 51 or the soldering iron 51 or the soldering iron It becomes difficult to transfer the heat of the initial molten solder 21 melted in 51 to a distance of the through hole 7 to be soldered.

Therefore, the solder 21 for connecting the power module terminal 12 and the through hole 7 is not heated to a temperature higher than the melting point temperature of the solder required for sufficient penetration, and the solder 21 solidifies in the middle of the through hole 7. As a result, sufficient connection for passing a large current (the solder filling depth b when the through hole length a is 75% or more) cannot be secured, and problems of heat generation and heat dissipation of the terminal portion occur. It could be. It also causes manufacturing defects.

Therefore, in this embodiment, in FIG. 5B of the bare board manufacturing process, a counterbore having a depth reaching the inner layer copper foil 2b is inserted around the through hole 7 to be soldered, and the solder filled in the through hole 7 is filled. The printed circuit board 1 provided with the stored solder reservoir 31 is configured.

Next, the printed circuit board having the solder pool described above will be described in each embodiment.

FIG. 8 is a circuit configuration diagram of the power conversion device 60 according to the first embodiment. The power converter 60 of FIG. 8 includes a forward converter 61, a reverse converter 62, a smoothing capacitor 63, a cooling fan 65, a heat dissipation fin 83, a control circuit 66, a drive circuit 67, and a digital device for supplying power to the AC motor 64. It is provided with an operation panel 68 and a shunt resistor 69. FIG. 8 shows a case where an AC power source is used as an input power source.

The forward converter 61 converts AC power into DC power. The smoothing capacitor 63 is provided in the DC intermediate circuit and smoothes the DC power converted by the forward converter 61.

The inverse converter 62 converts DC power into AC power of an arbitrary frequency. A temperature protection detection circuit is mounted inside the inverse converter 62. The temperature protection detection circuit may be equipped with a thermistor 70 as shown in FIG. 8 to detect the temperature, or the semiconductor element in the inverse converter 62 may have a built-in sensing function for temperature sensing.

Generally, the forward converter 61 and the reverse converter 62 are packaged as a forward converter module 61A and a reverse converter module 62A, respectively. Further, it is common to integrate the forward converter module 61A and the reverse converter module 62A into the power module 11, but the power module 11 is equipped with either the forward converter 61 or the reverse converter 62. You may. Here, the power conversion device 60 is configured by electrically connecting electrical junction components such as electric wires and metal bars, or components of the circuit shown in FIG. 8 using a printed circuit board.

The power conversion device 60 in this embodiment can be applied as a power conversion device to a general-purpose inverter, a servo amplifier, a DCBL controller, and the like.

FIG. 9 is a configuration diagram before assembling the power conversion device having the printed circuit board, the power module, and the like of the first embodiment. In FIG. 9, the cooling fan 65, the AC motor 64, and the digital operation panel 68 of FIG. 8 are omitted.

The power module 11 is fixed to the heat radiation fin 83 by the mounting screw 84. The power module mounting board 81 is assembled so that the embedded board 82 is fixed to the heat radiation fins 83 and then fixed to the heat radiation fins 83.

The embedded board 82 is a board on which a smoothing capacitor 63 is mounted, and the power module mounting board 81 is a board on which the control circuit 66 and the drive circuit 67 of FIG. 8 are mounted on a bare board (printed circuit board 1).

FIG. 10 is a configuration diagram after assembling the power module mounting board 81, the embedded board 82, the power module 11 and the heat radiation fin 83 of the first embodiment. FIG. 10 is a block diagram of the power conversion device after the process described with reference to FIG.

The power module terminal 12 of the power module 11 is inserted through the component pad 8 of the power module mounting board 81. The power module terminal 12 and the component pad 8 are electrically connected by soldering, but it is difficult to manufacture by flow and reflow soldering, and soldering by hand soldering is required. When an attempt is made to mount a power conversion device as shown in FIG. 10 with a normal flow device, there arises a manufacturing problem that the residual heat time is long and the soldering is not stable unless the residual heat temperature is high. Further, the power conversion device is quite heavy and difficult to flow in the flow device.

Further, as shown in FIGS. 9 and 10, by mounting the power module mounting board 81 and the embedded board 82 on the power module 11, power conversion measures are taken as compared with the case where those parts are separately arranged on a plane. Area can be reduced.

The solder pool 31 of the printed circuit board 1 of the first embodiment is filled with the molten solder 21 to increase the contact area and heat transferability between the molten solder 21 and the outer layer copper foil 2a, the inner layer copper foil 2b, and the power module terminal 12. ..

According to the first embodiment, the heat capacity obtained from the solder pool suppresses the decrease in heat transfer from the soldered surface of the printed circuit board 1, and makes it easy to maintain the solder melting point temperature required for solder penetration or higher. Then, the molten solder can maintain the molten state for the time required for filling the through holes, and it is possible to avoid the occurrence of insufficient flow-up (insufficient soldering).

Further, according to the first embodiment, it is not necessary to use a large-sized soldering iron having a large heat capacity and to heat for a long time, so that the workability is improved. Further, in the first embodiment, the height of filling the solder in the height direction of the through hole 7 by the depth of the solder reservoir 31 is shorter than that of the comparative example, and the solder is sufficiently filled in the gap in the through hole 7. Can be easily filled.

Further, since the solder 21 in the solder pool 31 has a heat capacity corresponding to its volume, the heat capacity obtained from the solder pool during circuit operation absorbs and dissipates heat generated by the circuit, and the printed circuit board 1 has a heat capacity. Suppress the temperature rise.

The power conversion device according to the second embodiment will be described with reference to FIGS. 2 and 7. This embodiment describes another configuration example of the printed circuit board 1 in the first embodiment. Therefore, the description of the parts common to the first embodiment will be omitted.

FIG. 2 is a cross-sectional view of the printed circuit board 1 and the power module 11 on which the components are mounted. In this embodiment, the solder reservoir 31 is formed by arranging the stepped structure 41 on the surface on the soldering side of the printed circuit board 1 to be locally soldered with a soldering iron 51 or the like.

In the second embodiment, in order to form the solder pool 31, a stepped structure 41 is provided on the soldered side surface of the printed circuit board 1 around the component pad 8 to be soldered and the power module terminal 12. The step structure 41 has a sufficient thickness to form a solder reservoir 31, and functions to prevent the molten solder 21 from spreading in the lateral direction of the printed circuit board 1.

The step structure 41 may perform the above-mentioned functions. FIG. 7 shows a printed circuit board 1 manufactured without applying this embodiment. By adding the stepped structure 41 to the printed circuit board 1 of FIG. 7, the printed circuit board 1 having the solder reservoir 31 can be provided. Further, the printed circuit board 1 having the solder reservoir 31 can be provided by giving the solder resist 5 and the silk 9 described in FIG. 7 a sufficient thickness to form the solder reservoir 31.

The power conversion device according to the third embodiment will be described with reference to FIG. The third embodiment describes an example in which the via 6 is embedded in the solder pool 31 of the printed circuit board 1 in the first embodiment. The description of the parts common to the first embodiment will be omitted.

FIG. 3 is a cross-sectional view of the printed circuit board 1 and the power module 11 on which the components are mounted.
In this embodiment, the via 6 is provided in contact with the solder reservoir 31. The via 6 transfers the heat of the molten solder 21 filled in the solder reservoir 31 to the inner layer copper foil 2b connected to the via 6 and the outer layer copper foil 2a on the back surface of the soldering side of the printed circuit board 1.

This has a function of warming the heat transfer from the soldered surface of the printed circuit board 1 of the through hole 7 from the side surface. Further, in the circuit operation, it has a function of absorbing heat by the heat capacity obtained from the solder pool and dispersing the heat dissipation path, and can further enhance the suppression of the temperature rise of the printed circuit board 1.

In FIGS. 1, 2, 3, and 5, the multilayer board is described, but the same can be applied to a two-layer (double-sided) substrate.

1 ... Printed circuit board,
6 ... Beer,
7 ... Through hole,
11 ... Power module,
12 ... Power module terminal,
31 ... Solder pool,
41 ... Step structure,
81 ... Power module mounting board,
82 ... Embedded board

Claims (13)

A power module with terminals and
A power conversion device having a power module mounting board having a through hole into which the terminal is inserted.
The power module mounting board is
Wiring patterns arranged inside and outside,
An insulating layer that insulates between the wiring patterns and
A power conversion device characterized by having a solder pool that stores solder. In the power conversion device according to claim 1,
The power module is a power converter having a forward converter or an inverse converter, or having both a forward converter and an inverse converter. In the power conversion device according to claim 1,
The power module mounting board is
The terminal penetrates the solder pool and
A power conversion device characterized in that the terminal and a conductor on the inner surface of the through hole are joined by the solder. In the power conversion device according to claim 1,
The power module mounting board is a printed circuit board.
A power conversion device characterized in that the solder pool reaches the inner layer wiring of the printed circuit board. In the power conversion device according to claim 1,
The power module mounting board is a printed circuit board.
A power conversion device characterized in that the solder pool reaches the core layer of the printed circuit board. In the power conversion device according to claim 1,
The power module mounting board is a printed circuit board.
On the surface of the printed circuit board on the soldering side,
A power conversion device having a stepped structure that supports the solder pool. In the power conversion device according to claim 1,
The power module mounting board is
A printed circuit board with vias
The via is in contact with the solder pool and is in contact with the solder pool.
A power conversion device characterized in that the inside of the via is filled with the solder. In the power conversion device according to claim 1,
The power module mounting board is
A power conversion device characterized by mounting a control circuit, a drive circuit, and a digital operation panel. In the power conversion device according to claim 1,
The power module is a power conversion device characterized in that it is fixed to a heat radiation fin. In the power conversion device according to claim 1,
The solder pool is arranged on one surface of the power module mounting board.
A power conversion device characterized in that the power module is arranged so as to face the other surface of the power module mounting board. In the power conversion device according to claim 1,
The filling height of the solder in the through hole is
A power conversion device characterized by having a length of 75% or more of the through hole. In the power conversion device according to claim 3,
The power module mounting board is a printed circuit board having component pads, and is a printed circuit board.
A power conversion device characterized in that the component pad and the terminal are joined by the solder. In the power conversion device according to claim 1,
The power module mounting board is
A power conversion device characterized by having a solder resist and silk.

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