KR20180080428A - Resistor for controlling motor - Google Patents

Abstract

The present invention comprises: a resistance unit connected in series so that a plurality of resistors form a plate; a pair of insulation units covering both surfaces of the resistance unit; a heat dissipation unit which covers the resistance unit and the insulation unit and dissipates heat emitted from the resistance unit; a fuse unit connected to the resistance unit and disconnecting from the resistance unit when the heat generation temperature of the resistance unit reaches the set temperature; and a base unit provided with a connection terminal to which the resistance unit and the fuse unit are connected. Therefore, the present invention improves safety against overheating of the resistance unit, and can prevent defects due to an inflow of a foreign matter.

Description

[0001] RESISTOR FOR CONTROLLING MOTOR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a motor control register, and more particularly, to a motor control register for controlling a current supplied to a motor.

Generally, the vehicle is provided with a cooling device that circulates refrigerant to cool the room. The cooling device discharges the cool air to the room of the vehicle by the fan device. The fan unit includes a case in which the air supply mechanism and the air outlet are formed, a fan disposed inside the case, and a fan motor for rotating the fan. In order to control the current supplied to the fan motor, the rotation speed of the fan motor, that is, the blowing amount can be adjusted. In order to control the current supplied to the fan motor, a motor control register is installed between the power supply part of the vehicle and the fan motor do.

Conventionally, when the resistance portion included in the motor control resistor is overheated, the fuse melts and short-circuiting occurs. However, the position of the fuse is distant from each resistance portion, so that a rapid short circuit can not be achieved. In addition, there is a problem that an external foreign matter can flow into the interior and cause defects. Therefore, there is a need to improve this.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 2011-0135683 (published on December 19, 2011, entitled "Register for Motor Controller and Method of Manufacturing the Same").

SUMMARY OF THE INVENTION It is an object of the present invention to provide a motor control register capable of improving safety against overheating and suppressing defects due to foreign matter inflow.

A motor control register according to the present invention includes: a resistance portion connected in series so that a plurality of resistors form a plate; A pair of insulating portions covering both surfaces of the resistance portion; A heat dissipation unit covering the resistor unit and the insulation unit and radiating heat radiated from the resistor unit; A fuse unit connected to the resistor unit and disconnected from the resistor unit when a temperature of the resistor unit reaches a set temperature; And a base portion on which a connection terminal to which the resistor portion and the fuse portion are connected is provided.

Wherein the resistance portion includes a high resistance portion connected to a first connection terminal provided on the base portion; A low resistance part connected to the high resistance part and connected to a third connection terminal provided on the base part; And a middle resistance portion disposed between the high resistance portion and the low resistance portion and connected to the high resistance portion and connected to a second connection terminal provided in the base portion.

Wherein the high resistance portion includes a high extension portion formed to extend to a predetermined length; A high coupling portion formed at one end of the high extension portion and disposed adjacent to the middle resistance portion, the fuse portion being coupled to the high coupling portion; And a high terminal part formed at the other end of the high extension part and connected to the first connection terminal.

The heat dissipation unit includes a first heat dissipation unit that covers one side of the resistance unit. A second heat dissipation unit covering the other side of the resistance unit; And a lift preventing part extending from the first heat dissipating part and bent to be in close contact with the second heat dissipating part.

Wherein the first heat dissipating unit includes: a first heat dissipating plate covering one side of the resistor; And a first heat radiating cover part protruding from an edge of the first heat radiating plate part and surrounding an edge of the resistance part.

The first heat dissipating unit may include a first heat dissipating leg unit extending from the first heat dissipating cover unit toward the base unit and coupled to the base unit to support the first heat dissipating plate unit and the base unit to be spaced apart from each other; And a first heat dissipating hole portion hollowly formed between the first heat dissipating plate portion and the first heat dissipating leg portion.

The first heat dissipating unit may further include a first wedge part formed on the first heat dissipating leg part and fastened to the base part.

Wherein the lifting prevention portion includes at least one circumferential tightening portion formed to protrude from the first heat dissipation cover portion toward the second heat dissipation portion and to be bent at an end thereof to be in close contact with the second heat dissipation portion; And an intermediate adhesion part protruding from the middle part of the first heat sink part toward the second heat dissipation part and passing through the middle part of the second heat dissipation part and being bent at an end part and coming into close contact with the second heat dissipation part .

The intermediate adhered portion is cut out from the first heat dissipating plate portion and bent so as to protrude in the direction of the second heat dissipating portion, and heat is released to the contact forming hole portion formed in the first heat dissipating plate portion by bending the intermediate adhered portion.

According to the motor control register of the present invention, since the heat dissipated from the resistance portion is dissipated through the heat dissipation portion, the overheat of the resistance portion can be further delayed. When the resistance portion overheats at the set temperature, the fuse portion is short- The risk of fire can be solved. Thus, the safety against overheating of the resistance portion can be further improved.

1 is an assembled perspective view schematically showing a motor control register according to an embodiment of the present invention.
FIG. 2 is a view schematically showing a state in which the fuse section is short-circuited in FIG.
3 is an exploded perspective view schematically showing a motor control register according to an embodiment of the present invention.
4 is a view schematically showing a resistance portion in a motor control register according to an embodiment of the present invention.
5 is a view schematically showing a heat dissipation unit in a motor control register according to an embodiment of the present invention.
6 is a view schematically showing a first heat dissipation unit in a motor control register according to an embodiment of the present invention.

Hereinafter, embodiments of the motor control register according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. Further, terms to be described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view schematically showing a motor control register according to an embodiment of the present invention. FIG. 2 is a schematic view showing a state where the fuse section is short-circuited in FIG. 1, and FIG. 3 is a cross- Fig. 3 is an exploded perspective view schematically showing a motor control register according to the present invention; 1 to 3, a motor control register 1 according to an embodiment of the present invention includes a resistance portion 10, an insulation portion 20, a heat dissipation portion 30, a fuse portion 40, And a base portion 50, as shown in Fig.

The resistance portion 10 is connected in series so that a plurality of resistors form a plate shape. The insulating portion 20 covers both surfaces of the resistance portion 10. For example, the insulating portion 20 may be formed to have the same size as that of the resistor portion 10 and may cover the front portion and the rear portion of the resistor portion 10.

The heat dissipation unit 30 covers the resistance unit 10 and the insulation unit 20 and dissipates the heat dissipated from the resistance unit 10. For example, the heat dissipation unit 30 may be made of a heat dissipation material that can dissipate heat generated in the resistor unit 10 through the current to the air. That is, the heat dissipating unit 30 may be made of aluminum. In addition, a variety of metal materials having excellent thermal conductivity may be used for the heat dissipating unit 30. [

The fuse unit 40 is electrically and physically connected to the resistance unit 10 through the heat dissipation unit 30. [ The fuse unit 40 is disconnected from the resistor 10 when the temperature of the resistor 10 reaches the set temperature.

For example, the fuse portion 40 may include a fuse connecting portion 41 and a fuse elastic portion 42. [ The fuse connecting portion 41 may be coupled to the resistance portion 10 through the heat dissipating portion 30. The heat dissipated from the resistance portion 10 can be conducted to the fuse connecting portion 41. [ The fuse elastic portion 42 has a shape of a leaf spring, is fixed to the base portion 10, and can be soldered to the fuse connecting portion 41. When the resistance portion 10 is overheated to a predetermined temperature, the solder is melted by the heat transferred to the fuse connecting portion 41, so that the fuse elastic portion 42 can be separated from the fuse connecting portion 41. When the fuse elastic portion 42 is separated from the fuse connection portion 41, the flow of current passing through the resistance portion 10 can be disconnected.

The base portion 50 is provided with a power supply portion of the vehicle, and a connection terminal for connecting the resistance portion 10 and the fuse portion 40. A plurality of resistors provided in the resistance portion 10 are selectively connected to the respective connection terminals.

For example, the base portion 50 includes a first connection terminal portion 51, a second connection terminal portion 52, a third connection terminal portion 53, a fuse connection terminal portion 54, a terminal installation portion 55, . ≪ / RTI > The terminal fitting portion 55 includes a heat insulating material such as synthetic resin and has a first connecting terminal portion 51, a second connecting terminal portion 52, a third connecting terminal portion 53, And a fuse connection terminal portion 54 may be provided. On the other hand, the terminal mounting portion 55 may be connected to the connector of the power supply portion and may be powered.

4 is a view schematically showing a resistance portion in a motor control register according to an embodiment of the present invention. 1 to 4, a resistor 10 according to an embodiment of the present invention includes a high resistance part 11, a middle resistance part 12, and a low resistance part 13.

The high resistance portion 11 is connected to the first connection terminal portion 51 provided on the base portion 50. [ The high storage portion 11 has a first set width and is formed to extend by a first set length. One end of the high resistance section 11 may be connected to the fuse connection section 41 of the fuse section 40 and the other end of the high resistance section 11 may be connected to the first connection terminal section 51. [

The middle resistance portion 12 is formed to extend by a second set length with a second set width smaller than the first set width. For example, one end of the middle resistance portion 12 may be connected to the high resistance portion 11 to form a continuous plate, and the other end may be connected to the second connection terminal portion 52.

The row resistance portion 13 is formed to extend by a third set length with a third set width smaller than the second set width. For example, one end of the row resistance portion 13 may be connected to the high resistance portion 11 and the middle resistance portion 12 to form a continuous plate, and the other end may be connected to the third connection terminal portion 53.

The high resistance portion 11, the middle resistance portion 12 and the low resistance portion 13 are connected in series to form a rectangular flat plate and have a first connection terminal portion 51 serving as a conduction path through which current is discharged, The second connection terminal portion 52 and the third connection terminal portion 53 are arranged in parallel on the same horizontal line corresponding to the lower end portion of the quadrangle.

For example, the high resistance portion 11 may form the left portion and the upper portion of the resistance portion 10. [ The middle resistance portion 12 may be disposed on the right side of the high resistance portion 11 and the upper portion thereof may be disposed below the upper portion of the high resistance portion 11. The lower portion of the middle resistance portion 12 is located in the lower middle portion of the resistance portion 10 and the upper portion thereof may be located in the right middle portion of the resistance portion 10. Further, the row resistance portion 13 may be disposed on the right side of the middle resistance portion 12, and the upper portion thereof may be disposed below the upper portion of the middle resistance portion 12. Thus, the row resistance portion 13 can be formed to the lower right portion of the resistance portion 10.

The high resistance section 11 may include a high extension section 111, a high coupling section 112, and a high terminal section 113. The high extension part 111 may be formed as a main body of the high resistance part 11 and may be formed to extend by a first set length with a first set width. 4, the high resistance portion 111 may include a boundary portion 1111, a spacing extension portion 1112, a proximal extension portion 1113, and an intermediate extension portion 1114. [

The boundary portion 1111 can form a boundary with the middle resistance portion 12 of the high resistance portion 11. The boundary portion 1111 is located below the resistance portion 10 and can be connected to the first connection terminal portion 51. [ The middle resistance portion 12 extends upward from the boundary portion 1111 and can be connected to the high resistance portion 11 continuously. The spacing extension part 1112 may be formed to extend upward from the boundary 1111 to be spaced apart from the first connection terminal part 51 and may be disposed on the left side of the resistance part 10. The proximal extension portion 1113 may be disposed between the spacing extension portion 1112 and the middle resistance portion 12 and may extend downward to a point where it does not interfere with the boundary portion 1111. The proximal extension portion 1113 is located closer to the row resistance portion 13 than the spacing extension portion 1112 and in particular the lower portion of the proximal extension portion 1113 has a low resistance Can be positioned closer to the portion (13). The intermediate extension 1114 may connect the spacing extension 1112 to the proximal extension 1113. [ The intermediate extension portion 1114 includes an upper extension portion 1114a that extends to the right from the upper portion of the spacing extension portion 1112 and a lower extension portion 1114b that is continuously connected from the lower portion of the upper extension portion 1114a, And a lower extension portion 1114b extending to the left side of the proximal extension portion 1113 and connected to the upper portion of the proximal extension portion 1113. [

The high coupling portion 112 is a portion to which the fuse connecting portion 41 of the fuse portion 40 is coupled and is connected to one end of the high resistance portion 111 which is relatively close to the low resistance portion 13, And may be formed at a lower portion of the extension portion 1113. The high terminal portion 113 is connected to the first connection terminal portion 51 and may be formed on the boundary portion 1111.

The fuse unit 40 is connected to the fuse connection terminal unit 54 provided in the base unit 50 and the current flows into the high resistance unit 11 via the fuse connection terminal unit 54 and the fuse unit 40. When the current flowing into the high resistance section 11 flows to the first connection terminal section 51 through only the high resistance section 11, the motor has three rotation speeds and the high resistance section 11 and the middle resistance section 12 , The motor has two rotation speeds lower than the third rotation speed and flows through the high resistance part 11, the middle resistance part 12 and the low resistance part 13 to the third connection terminal part 52 through the third connection terminal part 52, When the current flows to the connection terminal portion 53, the motor has a rotation speed of one stage lower than the second stage.

Resistance heat is generated in proportion to the energization time of each of the high resistance part 11, the middle resistance part 12 and the low resistance part 13. Since the current flows mainly in the high resistance part 11 as described above Accordingly, the fuse unit 40 is installed to receive the resistance heat from the high resistance unit 11.

According to an embodiment of the present invention, since the high coupling portion 112 is formed in the lower right portion of the high resistance portion 11, which is adjacent to the low resistance portion 13, The resistance heat generated in the row resistance portion 13 is more affected by the fuse portion 40 than to the fuse portion 40 at the lower left portion which is relatively spaced from the row resistance portion 13.

When the fuse portion 40 is coupled to the left lower portion of the high resistance portion 11 which is relatively spaced apart from the low resistance portion 13, the open or not of the fuse portion 40 is limited only to the heat generation temperature of the high resistance portion 11 The open / closed state of the fuse unit 40 is determined by not only the heat generation temperature of the high resistance unit 11 but also the heat generation temperature of the low resistance unit 13, The function of the fuse unit 40 provided as a safety measure against overheating of the fuse unit 40 can be more stably performed.

FIG. 5 is a view schematically showing a heat dissipating unit in a motor control register according to an embodiment of the present invention, and FIG. 6 is a view schematically showing a first heat dissipating unit in a motor control register according to an embodiment of the present invention. 1 to 6, a heat dissipating unit 30 according to an embodiment of the present invention includes a first heat dissipating unit 31, a second heat dissipating unit 32, and a tripping preventing unit 33 .

The first heat dissipation unit 31 covers one side of the resistance unit 10 and the second heat dissipation unit 32 covers the other side of the resistance unit 10. The unsticking prevention unit 33 includes a first heat dissipation unit 31 and the second heat dissipating unit 32 to prevent lifting of the resistor 10. The lift preventing portion 33 extends from the first heat radiating portion 31 and is bent so as to be in close contact with the second heat radiating portion 32. [

The first heat radiating part 31 according to an embodiment of the present invention includes a first heat radiating plate part 311 and a first heat radiating cover part 312.

The first heat sink part 311 covers one side of the resistor part 10. For example, the first heat sink part 311 may have a rectangular plate shape to cover the resistor part 10 and the insulating part 20 located on one side of the resistor part 10.

The first heat dissipation cover portion 312 protrudes from the edge of the first heat dissipation plate portion 311 and surrounds the edge of the resistance portion 10. For example, the first heat dissipation cover portion 312 protruding from the upper and both ends of the first heat dissipation plate portion 311 may cover the resistance portion 10 and the insulation portion 20.

The first heat dissipating unit 31 may further include a first heat dissipating leg 313 and a first heat dissipating hole 314 according to an embodiment of the present invention.

The first heat dissipating leg portion 313 extends from the first heat dissipating cover portion 312 in the direction of the base portion 50 and is connected to the base portion 50 so that the first heat dissipating plate portion 311 and the base portion 50 . That is, since the first heat radiating plate portion 311 and the base portion 50 are disposed apart from each other, it is possible to prevent damage such as melting of the base portion 50 due to resistance heat conducted to the first heat radiating plate portion 311 have. For example, the first heat radiation cover portion 312 is formed from the upper end to the intermediate point of the first heat radiation plate portion 311, and the first heat radiation leg portion 313 extending from the lower end portion of the first heat radiation cover portion 312 The length of the first heat dissipation cover portion 312 is longer than the vertical length of the first heat dissipation cover portion 312 so that the conducted heat is released into the air to improve the cooling performance and to suppress thermal damage to the base portion 50.

The first heat dissipating hole portion 314 is hollow between the first heat dissipating plate portion 311 and the first heat dissipating leg portion 313. The heat of the first heat radiation plate portion 311 is transmitted to the first heat radiation leg portion 313 only through the lower end portion of the first heat radiation cover portion 312 by the first heat radiation hole portion 314, The thermal damage of the base portion 50 can be prevented more stably.

The first heat radiating part 31 according to an embodiment of the present invention may further include a first wedge part 315. The first wedge portion 315 is formed on the first heat dissipating leg portion 313 and is engaged with the base portion 50. That is, when the first heat dissipating leg portion 313 is inserted into the base portion 50, the first wedge portion 315 is fixed to the inside of the base portion 50 to improve the bonding force with the base portion 50 .

The second heat dissipation unit 32 may be disposed in front of the first heat dissipation unit 31 with the resistor unit 10 and the insulation unit 20 interposed therebetween. The second heat dissipating unit 32 may have a panel shape capable of covering the front surface of the resistor unit 10 and the insulating unit 20. [ For example, the second heat dissipating unit 32 may have a width corresponding to that of the first heat dissipating plate unit 311 and may be inserted into the first heat dissipating cover unit 312.

The unthrottling prevention part 33 according to an embodiment of the present invention includes a circumferential tightening part 331 and an intermediate tightening part 332. [ The circumferential tightening portion 331 is formed to protrude from the first heat dissipating cover portion 312 in the direction of the second heat dissipating portion 32 and is bent at an end thereof to be in close contact with the second heat dissipating portion 32. The intermediate adhered portion 332 is formed to protrude from the intermediate portion of the first heat dissipating plate portion 311 toward the second heat dissipating portion 32 and penetrates the middle portion of the second heat dissipating portion 32, And is in close contact with the heat dissipating portion 32.

The circumferential tightening portion 331 is formed so as to protrude from the left side portion, the right side portion and the upper side of the first heat radiation cover portion 312 in the direction of the second heat radiation portion 32 and extends to the front side of the second heat radiation portion 32 The extended end portion may be bent so as to enclose the edge portion of the second heat dissipating portion 32 and be brought into close contact with the second heat dissipating portion 32.

The intermediate adhering portion 332 is a portion that closely adheres the first heat dissipating plate portion 311 and the second heat dissipating portion 32 to the intermediate portion of the resistance portion 10. The intermediate adhered portion 29 protrudes from the middle portion of the first heat dissipating plate portion 311 toward the second heat dissipating portion 32 and penetrates through the middle portion of the second heat dissipating portion 32 to form the second heat dissipating portion 32, Respectively.

The edge portions of the first heat radiation plate portion 311 and the second heat radiation portion 32 can be firmly adhered to the both side portions of the resistance portion 10 by the peripheral tight contact portion 331. [ The intermediate portion of the first heat radiation plate portion 311 and the second heat radiation portion 32 can be firmly adhered to the both side portions of the resistance portion 10 by the intermediate adhesion portion 332. The entire surface of the first heat radiation plate portion 311 and the second heat radiation portion 32 is tightly adhered to the resistance portion 10 firmly by using the circumferential adhesion portion 331 and the intermediate adhesion portion 332, The heat is not stagnated on the inner space portion corresponding to the clearance of the first heat radiating portion 311 and the second heat radiating portion 32 but is smoothly transferred to the first heat radiating plate portion 311 and the second heat radiating portion 32 It can be conducted and cooled down to the air.

The tripping prevention part 33 according to an embodiment of the present invention may further include a lower adhesion part 333. The lower contact part 333 is formed to protrude from the lower end of the first heat radiating part 311 in the direction of the second heat radiating part 32 and the end extending to the front of the second heat radiating part 32 is formed in the second heat radiating part 32 and may be in close contact with the second heat dissipating part 32. [

The intermediate adhered portion 332 is cut out from the first heat dissipating plate portion 311 and bent so as to protrude in the direction of the second heat dissipating portion 32. The intermediate adhered portion 332 is closely contacted with the first heat dissipating plate portion 311 And emits heat to the formation hole portion 318. That is, the intermediate adhered portion 332 can protrude forward by bending a part of the middle portion of the first heat radiating plate portion 311 and bending it forward, and the end portion passing through the second heat radiating portion 32 can be protruded forward, (32) and can be brought into close contact with the second heat radiation portion (32). The formation of latent heat in the heat radiation portion 30 can be suppressed by the tightly formed hole portion 318. [

According to the motor control register 1 of the present invention having the above-described structure, the heat dissipated from the resistance portion 10 can be dissipated through the heat dissipation portion 30 to further delay the overheat of the resistance portion 10 If the resistance portion 10 is overheated at the set temperature, the fuse portion 40 is short-circuited, and the risk of fire due to overheating of the resistance portion 10 can be solved. Thus, the safety against overheating of the resistance portion 10 can be further improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the true scope of protection of the present invention should be defined by the following claims.

10: Resistance section 11: High resistance section
12: middle resistance portion 13: low resistance portion
20: insulation part 30:
31: first heat radiating part 32: second heat radiating part
33: lifting prevention part 40: fuse part
41: fuse connecting part 42: fuse elastic part
50: base portion 51: first connection terminal portion
52: second connection terminal portion 53: third connection terminal portion
54: fuse connecting terminal portion 55: terminal fitting portion

Claims (9)

A resistor connected in series to form a plurality of resistors;
A pair of insulating portions covering both surfaces of the resistance portion;
A heat dissipation unit covering the resistor unit and the insulation unit and radiating heat radiated from the resistor unit;
A fuse unit connected to the resistor unit and disconnected from the resistor unit when a temperature of the resistor unit reaches a set temperature; And
And a base portion on which a connection terminal to which the resistor portion and the fuse portion are connected is provided.
2. The apparatus as claimed in claim 1,
A high resistance part connected to a first connection terminal provided on the base part;
A low resistance part connected to the high resistance part and connected to a third connection terminal provided on the base part; And
And a middle resistance portion disposed between the high resistance portion and the low resistance portion and connected to the high resistance portion and connected to a second connection terminal provided on the base portion.
3. The apparatus of claim 2, wherein the high resistance portion
A high extension extending to a set length;
A high coupling portion formed at one end of the high extension portion and disposed adjacent to the middle resistance portion, the fuse portion being coupled to the high coupling portion; And
And a high terminal portion formed at the other end of the high extension portion and connected to the first connection terminal.
The plasma display panel of claim 1,
A first heat dissipation unit covering one side of the resistance unit;
A second heat dissipation unit covering the other side of the resistance unit; And
And a lift preventing part extending from the first heat dissipating part and bent so as to be in close contact with the second heat dissipating part.
The plasma display panel of claim 4, wherein the first heat-
A first heat radiating plate part covering one side of the resistor part; And
And a first heat radiating cover portion protruding from an edge of the first heat radiating plate portion and surrounding an edge of the resistance portion.
The plasma display panel of claim 5, wherein the first heat-
A first heat dissipation leg portion extending from the first heat dissipation cover portion toward the base portion and coupled to the base portion to support the first heat dissipation plate portion and the base portion so as to be separated from each other; And
And a first heat dissipating hole portion hollowly formed between the first heat dissipating plate portion and the first heat dissipating leg portion.
The plasma display panel of claim 6, wherein the first heat-
And a first wedge portion formed on the first heat dissipating leg portion and engaged with the base portion.
6. The apparatus according to claim 5, wherein the lifting prevention portion
At least one circumferential tightening part formed to protrude from the first heat dissipating cover part toward the second heat dissipating part and to be bent at an end thereof and brought into close contact with the second heat dissipating part; And
And an intermediate tightening part protruding from the middle part of the first heat sink part toward the second heat dissipating part and passing through the middle part of the second heat dissipating part and being bent at an end thereof and coming into close contact with the second heat dissipating part Features a motor control register.
9. The method of claim 8,
Wherein the intermediate adhered portion is cut out from the first heat dissipating plate portion and is bent so as to protrude toward the second heat dissipating portion,
And heat is released to the contact-forming hole portion formed in the first heat sink plate portion by bending the intermediate contact portion.

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