KR102451764B1 - Assembly of power converter-inverter module which reactor vibration is reduced - Google Patents

Abstract

The present invention relates to a power converter assembly, and is an assembly in which a transformer and a reactor are stacked in a vertical structure, including a support plate, an intermediate plate, an upper plate, and a fixed plate. According to the present invention, it is possible to effectively reduce the installation area by vertically stacking transformers and reactors even in places with narrow internal spaces, such as railway vehicles, aircraft, and automobiles, and effectively fixing the reactor when stacking the reactor on top of the transformer, Reduce the vibration of the reactor.

Description

Assembly of power converter-inverter module which reactor vibration is reduced

The present invention relates to a power converter assembly, and more particularly, to a power converter assembly that can be usefully applied to transportation institutions such as railway vehicles, airplanes, and automobiles that lack the installation space of the power converter.

In the case of a commercial frequency transformer, which is a conventional power conversion device, as the size of the large-capacity transformer increases, it is difficult to prepare a space for installing the transformer, which has become a problem. However, in the case of a high-frequency power converter using a semiconductor power device, the size and weight of the transformer decrease as the frequency increases, so the problem of insufficient space for installing a large-capacity transformer can be solved. Therefore, in recent years, semiconductor transformers using a frequency band of 5 to 10 kHz, which is a high frequency, are attracting attention as a new future industry, and are being actively researched and developed in each field.

On the other hand, the power conversion device is developed by connecting a pair of modules with one transformer and one reactor in series or in parallel. Installing multiple transformers and reactors on the same plane in transport facilities such as aircraft, ships, railroad vehicles, and automobiles, where space is scarce, is very poor in space utilization. However, in the conventional commercial frequency transformer, the transformer and the reactor could not be installed vertically, and the above inefficiency was tolerated.

In the case of semiconductor transformers, the size and weight are small, so transformers and reactors can be stacked vertically to increase the installation space utilization rate. have. There is a prior art related to the conventional transformer installation structure, but it needs improvement as a structure installed inside the above-described transportation engine.

In particular, when the reactor is mounted on the upper part of the transformer and fixed to the assembly, the structure needs to be improved so as to safely mount and fix the reactor while reducing vibration.

Registered Patent Publication No. 10-2005809 (2019.07.25. Registered)

The present invention is an assembly of a power conversion device, to increase the space efficiency by reducing the installation area inside various transportation institutions where the installation space is limited, and to provide an assembly with durability against vibration and shock generated in the transportation system. do.

The present invention relates to a power converter assembly including a transformer and a reactor, a support plate for supporting the first transformer from the bottom, and an intermediate plate located on the upper surface of the first transformer and connected to the support plate and supporting the lower surface of the second transformer and an upper plate positioned on the upper surface of the second transformer and connected to the intermediate plate to support the lower surface of the reactor, and a fixing plate positioned on the upper surface of the reactor and connected to the upper plate.

Preferably, the support plate has a first guide surrounding the lower end of the first transformer on an upper surface, and a fixing hole for fixing a position on the floor, and the middle plate is a first guide surrounding the upper end of the first transformer on a lower surface. A first upper plate having a second guide and a third guide enclosing the lower end of the second transformer on an upper surface, the upper plate having a fourth guide enclosing a periphery of the upper portion of the second transformer on a lower surface, and on the upper surface One aspect includes a second upper plate having a fifth guide surrounding the lower periphery of the reactor and connected to the first upper plate.

Also, preferably, a gap generating unit is provided between the first upper plate and the second upper plate to form a gap between the first upper plate and the second upper plate.

According to the present invention, since the transformer or reactor is vertically stacked, efficient installation is possible even in a narrow space, and the risk of deformation or damage of the transformer or reactor due to vibration generated in a transportation institution is reduced, so that the installation structure is stable.

In addition, when two reactors are stacked and fixed on the upper part of the transformer, there is an effect of minimizing the vibration of the reactor while increasing the fixing effect of the reactor.

1 is a perspective view of a power converter assembly according to an embodiment of the present invention.
Figure 2 is an exploded view showing the power converter assembly according to an embodiment of the present invention.
Figure 3 shows the base plate of the power converter assembly.
Figure 4 shows an intermediate plate of the power converter assembly.
Figure 5 shows the first upper plate of the power converter assembly.
6 shows a second upper plate of the power converter assembly.
7 shows a fixing plate of the power converter assembly.

The specific structural or functional descriptions presented in the embodiments of the present invention are merely exemplified for the purpose of describing the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms.

In addition, this specification should not be construed as being limited to the described embodiments, but should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. In the description of the present invention, when it is determined that the description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the description thereof is omitted.

1 is a perspective view of a power converter assembly 100 according to an embodiment of the present invention, Figure 2 is an exploded view of the power converter assembly 100.

Referring to Figure 1, the power converter assembly 100 is composed of a total of three stages, two semiconductor transformers are vertically arranged in stage 1 and stage 2, and two reactors are arranged in parallel at stage 3.

The power converter assembly 100 includes a support plate 110 , an intermediate plate 120 , an upper plate 130 , and a fixing plate 140 . The support plate 110 supports the load of the first transformer 10 , the intermediate plate 120 supports the load of the second transformer 20 , and the upper plate 130 supports the load of the reactor 30 , , the fixing plate 140 fixes each of the reactors 30 on top of the plurality of reactors 30 .

The support plate 110 , the intermediate plate 120 , the upper plate 130 , and the fixing plate 140 are connected to each other by the fastening bolts 150 while supporting or fixing the transformer or reactor in each floor. It also includes guides for securing the transformer or reactor.

3 to 7 show in detail the support plate 110 , the intermediate plate 120 , the upper plate 130 , and the fixing plate 140 , and each configuration will be described below.

3 is a view showing the upper surface and the side of the support plate (110). The support plate 110 is formed of a plate-shaped member having a rectangular shape, and has an area capable of sufficiently supporting the first transformer 10 .

The support plate 110 includes bent portions 114 symmetrically formed at both ends. Both ends of the support plate 110 are bent once toward the ground and once outward of the support plate 110 to form the bent portion 114 having a stepped cross section. As the bent portion 114 is formed, portions of the support plate 110 that are in direct contact with the ground are both edge portions, and the central portion of the support plate 110 supports the upper load at a predetermined distance from the ground. The support plate 110 is preferably formed of a material having a rigidity capable of sufficiently supporting the upper load.

However, the shape, material, etc. of the support plate 110 includes those that can be appropriately changed by a person having ordinary knowledge in the technical field to which the present invention pertains (hereinafter referred to as 'the person skilled in the art').

Both ends of the edge of the support plate 110 on which the bent portion 114 is formed includes fixing holes 112 . A fixing hole 112 is formed in a portion of the support plate 110 in direct contact with the ground, and the power converter assembly 100 can be connected to the ground through the fixing hole 112 .

The shape and number of the fixing holes 112 include those that can be appropriately changed by those skilled in the art in order to stably fix the power converter assembly 100 to the ground.

A central portion directly supporting the first transformer 10 in the support plate 110 has a first guide 112 on its upper surface. The first guide 112 may be formed in a 'L' shape at the portion where the four corners of the first transformer 10 are located in consideration of the lower area of the first transformer 10 . The first guide 112 prevents separation of the first transformer 10 by limiting the movement of the first transformer 10 on a horizontal plane.

In the case of transportation institutions, acceleration and deceleration are repeated and irregular vibration is induced depending on the condition of the running surface. The guide restricts the movement of the transformer and protects the transformer from running safely. The shape and position of the guides include those that are suitably modified by those skilled in the art.

The support plate 110 has a first fastening hole 113 in an outer portion of a surface in contact with the first transformer 10 . The first fastening hole 113 is connected to the second fastening hole 123 of the intermediate plate 120 by the fastening bolt 150 . Both ends of the fastening bolt 150 are inserted into the first fastening hole 113 and the second fastening hole 123, respectively, and nuts are tightened at both ends to provide the support plate 110, the first transformer 10, and the intermediate plate 120. ) can be securely fastened.

The shape, position, and number of the first fastening holes 113 include those that can be appropriately changed by those skilled in the art within the range that satisfies the above-described functions. The position and number of the second fastening holes 123 correspond to the first fastening holes 113 .

4 shows the bottom, side and top of the intermediate plate 120 . The intermediate plate 120 is positioned above the first transformer 10 and supports the lower portion of the second transformer 20 . The shape of the intermediate plate 120 may be formed as a rectangular flat plate along the support plate 110 .

The lower surface of the intermediate plate 120 includes the second guide 121 to constrain the upper movement of the first transformer 10 , and the upper surface of the intermediate plate 120 includes the third guide 122 for the second The lower movement of the transformer 20 is constrained. The guide can be formed in a position and shape to suit the shape of the transformer according to the above-mentioned purpose, and is expressed in the shape of a 'L' in the drawing.

The intermediate plate 120 includes a second fastening hole 123 and a third fastening hole 124 . The third fastening hole 124 connects the middle plate 120 and the first upper plate 131 to correspond to the fourth fastening hole 136 of the first upper plate 131 . Both ends of the fastening bolt 150 are inserted into the third fastening hole 124 and the fourth fastening hole 136, respectively, and nuts are tightened at both ends of the intermediate plate 120, the second transformer 20, and the first upper part. The plate 131 can be firmly fastened.

The shape, position, and number of the third fastening holes 124 include those that can be appropriately changed by those skilled in the art within the range satisfying the above-described functions. The fourth fastening hole 136 is formed to correspond to the third fastening hole 124 to be fastened.

The base plate 110 , the first transformer 10 , the intermediate plate 120 , the second transformer 20 and the upper plate 130 are firmly bound to each other and fixed to the ground, while the movements of the transformer and the reactor are restricted. .

5 and 6 show the first upper plate 131 and the second upper plate 132 . The upper plate 130 includes a first upper plate 131 and a second upper plate 132 .

Referring to FIG. 5 , a bottom surface, a side surface and an upper surface of the first upper plate 131 are shown. The first upper plate 131 is positioned above the second transformer 20 , and the first upper plate 131 may have a rectangular shape along the support plate 110 . The lower surface of the first upper plate 131 includes the fourth guide 133 to constrain the upper movement of the second transformer 20 . The fourth guide 133 may be provided to completely surround the upper periphery of the second transformer 20 .

In addition, the first upper plate 131 has a fourth fastening hole 136 for connecting to the intermediate plate 120 and a fifth fastening hole 137 for connecting to the second upper plate 132 .

The second upper plate 132 is connected on top of the first upper plate 131 , and the upper surface of the second upper plate 132 includes the fifth guide 134 to constrain the lower movement of the reactor 30 . The fifth guide 134 may be provided to completely surround the lower periphery of the reactor 30 . That is, when there are two reactors 30 , the fifth guide 134 may be formed to completely surround the lower periphery of each reactor 30 .

In addition, the second upper plate 132 has a sixth fastening hole 138 for connecting to the first upper plate 131 and a seventh fastening hole 139 for connecting to the fixing plate 140 .

In addition, the material of the second upper plate 132 is made of aluminum. This is to minimize heating of the second upper plate 132 due to the influence of the reactor driving frequency.

Meanwhile, the positions and shapes of the fourth and fifth guides 133 and 134 may be changed to suit the shape of the transformer or reactor.

The gap generator 135 is provided between the first upper plate 131 and the second upper plate 132 . The gap generator 135 functions to create a predetermined gap between the first upper plate 131 and the second upper plate 132 when the first upper plate 131 and the second upper plate 132 are connected. do The gap generator 135 may be connected to the upper surface of the first upper plate 131 or connected to the lower surface of the second upper plate 132 .

Typically, since the size of the reactor is smaller than that of the transformer, the reactor 30 placed on the second transformer 20 is located within the upper area of the second transformer 20 . When fixing the reactor 30, it is advantageous to use the fastening bolt 150 at a position close to the reactor 30, but in this case, the fastening bolt 150 penetrates the upper plate 130 and interferes with the second transformer 20. There is a problem with this occurring.

In order to solve this problem, the upper plate 130 of the power converter assembly 100 includes a first upper plate 131 and a second upper plate 132 connected to each other at a predetermined distance. The fastening bolt 150 for fixing the reactor 30 may pass through the seventh fastening hole 139 of the second upper plate 132 at a position close to the reactor 30 to fix the reactor 30, 1 Since it does not penetrate the upper plate 131 , there is no fear of interfering with the second transformer 20 .

7 shows the bottom and side surfaces of the fixing plate 140 . The fixing plate 140 is located at the top of the assembly and serves to fix the movement of the reactor 30 . The shape of the fixing plate 140 may be provided in a rectangular shape along the support plate 110 . In addition, the fixing plate 140 may be provided as a single flat member connecting the upper portions of the two reactors 30 .

The lower surface of the fixing plate 140 includes the sixth guide 141 to constrain the upper movement of the reactor 30 . The sixth guide 141 is positioned and shaped to suit the shape of the upper surface of the reactor, and is provided to completely surround the upper periphery of the reactor 30 .

In addition, the fixing plate 140 includes an eighth fastening hole 142 . The eighth fastening hole 142 corresponds to the seventh fastening hole 139 of the second upper plate 132 , and connects the second upper plate 132 and the fixing plate 140 with the fastening bolt 150 .

The fixing plate 140 is made of an aluminum material in order to minimize the heating effect due to the driving frequency of the reactor 30 .

On the other hand, the fastening bolt 150 is a configuration used to connect the support plate 110 , the intermediate plate 120 , the first upper plate 131 , the second upper plate 132 , and the fixing plate 140 . The fastening bolt 150 is provided with a bolt of an appropriate length, and a screw thread capable of inserting a nut is formed at both ends of the bolt.

The fastening bolt 150 penetrates the first fastening hole 118 of the support plate 110 and the second fastening hole 123 of the intermediate plate 120 and connects the support plate 110 and the intermediate plate 120 by tightening the nut. do. The first fastening hole 118 and the second fastening hole 123 are provided around the first transformer 10 and are symmetrically formed with respect to the center of the area of the first transformer 10 .

In addition, the fastening bolt 150 penetrates through the third fastening hole 124 of the intermediate plate 120 and the fourth fastening hole 136 of the first upper plate 131 by tightening the nut to the middle plate 120 and the first fastener. 1 Connect the upper plate 131 . The third fastening hole 124 and the fourth fastening hole 136 are provided around the second transformer 20 and are symmetrically formed with respect to the center of the area of the second transformer 20 .

In addition, the fastening bolt 150 penetrates the fifth fastening hole 137 of the first upper plate 131 and the sixth fastening hole 138 of the second upper plate 132 and is connected by tightening the nut. The fifth fastening hole 137 and the sixth fastening hole 138 are provided at the edge of the upper plate 130 , and are symmetrically formed with respect to the center of the area of the upper plate 130 .

Then, the fastening bolt 150 passes through the seventh fastening hole 138 of the second upper plate 132 and the eighth fastening hole 142 of the fixing plate 140 and is connected by tightening the nut. The seventh fastening hole 138 and the eighth fastening hole 142 are provided around the reactor 30 and are formed symmetrically with respect to the center of the area occupied by the reactor 30 . When there are two reactors 30 as in the present embodiment, a seventh fastening hole 142 or an eighth fastening hole 142 may be formed around upper and lower corners of each reactor 30 . The two reactors 30 are preferably located adjacent to each other.

The length, diameter, number of fastening holes, etc. of the fastening bolt 150 include those that can be appropriately changed by those skilled in the art, and the first fastening hole 118 to the eighth fastening hole 142 has a diameter corresponding to the fastening bolt 150 . and may be formed at an appropriate position so as not to interfere with each other when connecting the fastening bolts 150 .

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it will be apparent to those skilled in the art that various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention.

10: first transformer
20: second transformer
30: Reactor
100: assembly of the power conversion device according to an embodiment of the present invention
110: base plate
112: first guide
114: bend
116: fixing hole
118: first fastening hole
120: middle plate
121: second guide
122: third guide
123: second fastening hole
124: third fastening hole
130: upper plate
131: first upper plate
132: second upper plate
133: fourth guide
134: fifth guide
135: gap generator
136: fourth fastening hole
137: fifth fastening hole
138: sixth fastening hole
139: seventh fastening hole
140: fixed plate
141: sixth guide
142: eighth fastening hole
150: fastening bolt

Claims (7)

In the power converter assembly comprising a transformer and a reactor,
a support plate for supporting the first transformer from the floor;
an intermediate plate positioned on the upper surface of the first transformer and connected to the support plate to support the lower surface of the second transformer;
an upper plate positioned on the upper surface of the second transformer and connected to the intermediate plate and supporting the lower surface of the reactor; and
and a fixing plate positioned on the upper surface of the reactor and connected to the upper plate,
The support plate is
A first guide surrounding the lower end of the first transformer on the upper surface, and a fixing hole for fixing the position on the floor,
The intermediate plate is
A second guide surrounding the upper end of the first transformer on a lower surface, and a third guide surrounding the lower end of the second transformer on an upper surface,
The upper plate is
A second upper plate having a first upper plate having a fourth guide surrounding the upper periphery of the second transformer on a bottom surface, and a fifth guide enclosing a lower periphery of the reactor on an upper surface and connected to the first upper plate including a plate,
A gap generator is provided between the first upper plate and the second upper plate to form a gap between the first upper plate and the second upper plate. The method according to claim 1,
The support plate has a first fastening hole for fastening with the intermediate plate,
The intermediate plate has a second fastening hole for fastening with the support plate and a third fastening hole for fastening with the upper plate,
The first upper plate has a fourth fastening hole for fastening with the intermediate plate and a fifth fastening hole for fastening with the second upper plate,
The second upper plate is a power converter assembly, characterized in that provided with a sixth fastening hole for fastening with the first upper plate. 3. The method according to claim 2,
The second upper plate supports two reactors, and the fixing plate connects the upper parts of the two reactors. 4. The method of claim 3,
The second upper plate and the fixing plate are power converter assembly, characterized in that made of an aluminum material. 4. The method of claim 3,
The second upper plate has a seventh fastening hole for fastening with the fixing plate,
The fixing plate includes an eighth fastening hole for fastening with the upper plate and a sixth guide on a bottom surface that completely surrounds the upper periphery of the reactor. 6. The method of claim 5,
and the fifth guide completely surrounds lower perimeters of the two reactors. 7. The method of claim 6,
The first fastening hole and the second fastening hole are connected with a fastening bolt,
The third fastening hole and the fourth fastening hole are connected with a fastening bolt,
The fifth fastening hole and the sixth fastening hole are connected with a fastening bolt,
The seventh fastening hole and the eighth fastening hole are power converter assembly, characterized in that connected to the fastening bolt.

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