JP2010141279A - Structure and method for radiating heat of element - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure and method for radiating heat of an element for improving heat radiation performance for suppressing temperature rise of the element. <P>SOLUTION: This structure for radiating heat of an element includes: an element 1 mounted on a board 3 and arranged to expose an element heat radiation part 12 to a surface on the board side; the board 3 where a through-hole 32 penetrating a mounting surface and the back side of the mounting surface is formed to expose the element heat radiation part 12 of the element 1 to the back side of the mounting surface; and a radiator 4 provided with a projecting part 43 coming into surface contact with the element heat radiation part 12 of the element 1 through a heat transfer material 2 by penetrating the through-hole 32, and provided with heat radiation fins 42 for increasing a heat radiation area. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention belongs to the technical field of element heat dissipation structures and methods.

  Conventionally, an LED lamp is mounted on a metal substrate and placed on a radiation fin via an insulating heat conductive sheet to radiate the LED lamp (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 2002-093206 (page 2-3, full view)

  However, in the past, there has been a strong demand for further cooling, and in order to suppress the temperature rise of the element, the radiator (radiating fin) has to be cooled to a lower temperature.

  The present invention has been made paying attention to the above-mentioned problems, and an object of the present invention is to provide a heat dissipation structure and method for an element that can improve heat dissipation performance that suppresses temperature rise of the element.

  In order to achieve the above object, in the present invention, in the heat dissipation structure of the element that transmits the heat generated by the element to the radiator and dissipates heat, the element is mounted on the substrate and the heat dissipation part is exposed on the surface on the substrate side. A substrate provided with a through hole penetrating the element, the mounting surface and the back side of the mounting surface to expose the heat dissipation portion of the element to the back side of the mounting surface, and heat dissipation of the element through the through hole And a heat dissipating means provided with a heat dissipating part which has a heat dissipating part which increases the heat dissipating area.

  Therefore, in this invention, the heat dissipation performance which suppresses the temperature rise of an element can be improved.

FIG. 3 is an explanatory cross-sectional view showing a heat dissipation structure of the element of Example 1. FIG. 3 is an explanatory perspective view showing a heat dissipation structure of the element of Example 1. 3 is an explanatory diagram of an inclined portion of a terminal 11. FIG. It is explanatory drawing which shows the thermal radiation structure of an element. It is explanatory drawing which shows the thermal radiation structure of an element. It is explanatory drawing which shows the thermal radiation structure of an element. 6 is an explanatory cross-sectional view showing a heat dissipation structure of an element of Example 2. FIG. 6 is an explanatory cross-sectional view showing a heat dissipation structure of an element of Example 3. FIG. 6 is an explanatory cross-sectional view showing a heat dissipation structure of an element of Example 4. FIG. 10 is an explanatory perspective view of a heat dissipation structure for an element of Example 5. FIG. 6 is an explanatory cross-sectional view of a heat dissipation structure for an element of Example 6. FIG. FIG. 12 is a partially enlarged view of FIG. 11. 10 is an explanatory perspective view showing a heat dissipation structure of an element according to Example 6. FIG. 10 is an explanatory cross-sectional view of a heat dissipation structure for an element according to Example 7. FIG. FIG. 15 is a partially enlarged view of FIG. 14. FIG. 10 is an explanatory perspective view showing a heat dissipation structure for an element of Example 7. FIG. 10 is an explanatory perspective view of a heat dissipation structure for an element according to Example 8. 10 is an explanatory sectional view of a heat dissipation structure for an element according to Example 9. FIG. 10 is an explanatory perspective view showing a heat dissipation structure for an element according to Example 9. FIG. It is explanatory drawing sectional drawing of the heat dissipation structure of the element of Example 10 of Example 10. FIG. FIG. 10 is an explanatory perspective view showing a heat dissipation structure of an element according to Example 10. 14 is an explanatory perspective view of a heat dissipation structure for an element according to Example 11. FIG. It is a description perspective view of the heat dissipation structure of the element of Example 12.

  Embodiments for realizing a heat dissipation structure and method for an element according to the present invention will now be described with reference to the first embodiment corresponding to the first and tenth embodiments and the first and second embodiments. 2, Example 3 corresponding to the invention according to claims 1, 3, 10, Example 4 corresponding to the invention according to claims 1, 3, 4, 10, and claims 1, 2, 5, 10. Example 5 corresponding to the invention according to claim 1, Example 6 corresponding to the invention according to claims 1 to 6 and 10, Example 7 corresponding to the invention according to claims 1 to 7 and 10, and Claim 1 Corresponding to the eighth embodiment corresponding to the invention according to the fifth to tenth aspects, the ninth embodiment corresponding to the inventions according to the first to fifth aspects of the invention, and the invention according to the first to fifth aspects. Description will be given based on Example 10 and Examples 11 and 12 corresponding to the inventions according to claims 1 to 5 and 10.

First, the configuration will be described.
FIG. 1 is an explanatory cross-sectional view showing a heat dissipation structure of an element according to the first embodiment. FIG. 2 is an explanatory perspective view showing the heat dissipation structure of the element according to the first embodiment.

The element heat dissipation structure of the first embodiment includes an element 1, a heat conductive material 2, a substrate 3, a radiator 4, and screws 5.
The element 1 is an electronic component that includes a terminal 11 and an element heat radiation unit 12 and is mounted on the substrate 3. For example, there are a semiconductor element, an LED, etc., which are in an excellent driving state or an element that needs cooling for long-term use.
The terminal 11 has a shape that extends obliquely downward from two opposite side portions, and is electrically connected to the energization pattern of the substrate 3. For example, it is joined by soldering. Further, as shown in FIG. 1, the terminal 11 has a shape in which a connecting portion to the substrate 3, that is, a tip is inclined.
The element heat radiation part 12 is a metal part exposed on the back side of the element, that is, on the substrate side. In FIG. 1, for the sake of explanation, the substrate side is shown to have a thickness.

The heat conductive material 2 is a member that transfers heat efficiently. For example, an adhesive sheet is used as an example.
The substrate 3 includes a terminal portion 31 and a through hole 32, and the element 1 is mounted thereon. In the first embodiment, a circuit board (PCB board) is used as the board 3.
The terminal portion 31 has a position size corresponding to the terminal 11 of the element 1 and is formed by, for example, an energization pattern. Thereby, the circuit formed on the substrate 3 and the element 1 are electrically connected.

The through holes 32 are provided between the terminal portions 31 provided in two pairs on the substrate 3 so as to correspond to the terminals 11 provided on both sides of the element 1. Further, the through hole 32 is provided at a position and size corresponding to the position and size of the element heat radiation portion 12 of the element.
The radiator 4 includes a plate-like portion 41, a radiation fin 42, a protruding portion 43, and an attachment hole 44. These are formed as one member.
The plate-like portion 41 is a plate-like portion arranged so as to be stacked below the substrate 3.
The heat dissipating fin 42 has a plurality of fins projecting downward from the plate-like portion 41 and has a large contact area with the surrounding air. Therefore, the fin shape may be another shape.

The protruding portion 43 is a portion protruding in a columnar shape from the upper surface of the plate-like portion 41, that is, the side surface opposite to the side of the radiation fin 42. The protrusion 43 has a diameter that can pass through the through hole 32 of the substrate 3, and has a thickness that can penetrate the substrate 3 and come into contact with the element heat radiation portion 12 of the element 1 through the heat conductive material 2. To do.
The shape of the heat conductive material 2 is a circle that matches the protrusion 43.
The attachment hole 44 is a hole that vertically penetrates the end of the plate-like portion 41, and the screw 5 passes therethrough.

Next, the mounting state of the element heat dissipation structure of Example 1 will be described.
The element 1 is mounted by soldering the terminals 11 advanced to both sides to the terminal portions 31 of the substrate 3 by soldering. In this state, the element heat radiation part 12 of the element is exposed downward through the through hole 32 of the substrate 3.
The heat conductive material 2 having the same planar shape as the protrusion 43 is attached to the upper surface of the protrusion 43 of the radiator 4. Then, the projecting portion 43 and the heat conducting material 2 are passed through the through hole 32 of the substrate 3 from below to above so that the heat conducting material 2 is in contact with the element heat radiating portion 12 of the element 1. It is preferable that the interview between the heat conductive material 2 and the element heat radiation portion 12 is bonded. The radiator 4 is fixed to the substrate 3 with screws 5. A fixing tool for fixing the screw 5 is provided on the lower surface of the substrate 3. Illustration is omitted.

FIG. 3 is an explanatory diagram of an inclined portion of the terminal 11.
The mounting order of the element 1 on the substrate 3 and the mounting order of the radiator 4 on the substrate may be reversed. At that time, as shown in FIG. 3, the element 1 adjusts the vertical position from the mounting surface, that is, the upper surface of the substrate 3 so that the inclined tip of the terminal 11 approaches the plane. Thus, when the terminals are joined by soldering, the element heat radiating portion 12 and the heat conducting material 2 may be mounted in a good surface contact state.
In FIG. 1 and FIG.

The operation will be described.
[Improvement in performance to suppress temperature rise of element]
In the element 1 according to the first embodiment, for example, a semiconductor or a light emitting element inside the resin package generates heat by driving. This heat generation is transmitted inside the element to the element heat radiating portion 12 which is a metal part exposed on the lower surface of the element 1.
The heat of the element heat radiating portion 12 is transmitted to the protrusion 43 of the radiator 4 through the heat conducting material 2 at the portion of the through hole 32 provided in the substrate 3, and heat exchange with the air is performed by the heat radiating fins 42.

In the first embodiment, since one radiator 4 is assigned to the element 1, even if the heat conductive material 2 has some electrical conductivity, electricity is not transmitted to other electrical components and circuit patterns.
Thus, in Example 1, since the element 1 transfers heat to the radiator 4 only through the heat conducting material 2, heat is radiated more directly. Therefore, the heat transfer loss between members is omitted, and the performance of suppressing the temperature rise of the element 1 is improved.

In order to clarify the operation of the first embodiment, further explanation will be added.
FIG. 4 is an explanatory view showing a heat dissipation structure of the element.
The following can be considered as a structure for radiating heat from the mounted element. The circuit board (PCB board) is directly cooled. However, the circuit board (PCB board) is made of resin, and the board itself has poor thermal conductivity. Therefore, as shown in FIG. 4, a circuit pattern copper foil portion 33 is provided on the substrate 3 to be joined to the element heat radiation portion 12 by the solder portion 61. And the copper foil part 35 is widely provided in the lower surface on the opposite side to the element of the board | substrate 3 so that it may become a contact surface with the heat radiator 4a.

And the through-hole 34 penetrated to the board | substrate 3 is provided so that the copper foil part 33 and the copper foil part 35 may be electrically connected. Then, the copper foil portion 35 on the lower surface of the substrate is radiated through the heat conductive material 2a by joining the through hole 34 and between the copper foil portion 33 and the element heat radiating portion 12 so as to be filled with the solder portion 61. It is the structure which conducts heat to 4a.
In this structure, the heat from the element heat radiation part 12 of the element 1 is conducted to the copper foil part 33 through the solder, and is conducted to the copper foil part 35 on the lower surface through the through hole 34. And it conducts from the copper foil part 35 to the heat radiator 4a through the heat conductive material 2a, and the heat radiator 4a radiates heat in the air.

  In this structure, since there are many members that transfer heat, the heat dissipator 4a has to be cooled to a lower temperature because of the large heat transfer loss between the members. On the other hand, in Example 1, the number of members that transfer heat is small, and heat can be radiated efficiently. Further, in the first embodiment, it is not necessary to transfer heat to the back side of the substrate 3 as compared with this structure, so that it is not necessary to provide the through hole 34 and a single-sided substrate can be used, thereby reducing the cost.

In addition, the following structure can be considered as a structure for dissipating heat from the mounted element.
FIG. 5 is an explanatory view showing a heat dissipation structure of the element.
In the heat dissipation structure shown in FIG. 5, the circuit board is a flexible substrate 3 a (FPC substrate) thinner than the PCB substrate, and the copper foil 36 provided on the flexible substrate 3 a and the element heat dissipation portion 12 are joined by the solder portion 62. The flexible substrate 3a is bonded to the radiator 4a by the adhesive 7.

In this structure, the heat from the element heat radiation part 12 of the element 1 is transmitted in the order of the solder portion 62, the copper foil 36, the flexible substrate 3a, the adhesive 7, and the radiator 4a.
However, in this structure, in the flexible substrate 3a, heat transfer is performed through the film 7 and the adhesive 7 having a heat conductivity inferior to that of metal, so that heat transfer loss increases, and accordingly, the radiator 4a must be cooled to a lower temperature. I must. On the other hand, in Example 1, between the element thermal radiation part 12 and the heat radiator 4, only the heat conductive material 2 is interposed, and it can thermally radiate efficiently.
In this structure, heat resistance is required for the base material of the flexible substrate 3a, which increases the cost.
In Example 1, since there is no such requirement for the base material of the substrate, the cost is suppressed.

In addition, the following structure can be considered as a structure for dissipating heat from the mounted element.
FIG. 6 is an explanatory view showing a heat dissipation structure of the element.
In the heat dissipation structure shown in FIG. 6, the circuit board is an aluminum substrate 3b. Since the aluminum substrate 3b is conductive, the insulating layer 8 is provided on the upper surface, and the copper foil 36 is provided thereon. The aluminum substrate 3b and the radiator 4a are joined by the heat conductive material 2a in order to improve adhesion and thermal conductivity.

In this structure, the heat from the element heat radiation portion 12 of the element 1 is transferred in the order of the solder portion 62, the copper foil 36, the insulating layer 8, the aluminum substrate 3b, the heat conductive material 2a, and the radiator 4a.
However, in this structure, since there are many members that transfer heat, the heat dissipator 4a has to be cooler because of the large heat transfer loss between the members. On the other hand, in Example 1, the number of members that transfer heat is small, and heat can be radiated efficiently.
Further, although the aluminum substrate is expensive, in the first embodiment, the cost is suppressed by using the PCB substrate.
Thus, in Example 1, it cools more directly by reducing the number of members to which heat is transmitted. In addition, the cost is controlled without any particular increase.

Next, the effect will be described.
In the heat dissipation structure of the element of Example 1, the effects listed below can be obtained.

  (1) In the heat dissipation structure of the element 1 that transmits the heat generated by the element 1 to the radiator 4 to dissipate heat, the element 1 is mounted on the substrate 3 and is provided so that the element heat dissipation portion 12 is exposed on the surface on the substrate side. And a through hole 32 penetrating the mounting surface and the back side of the mounting surface so as to expose the element heat radiating portion 12 of the element 1 to the back side of the mounting surface, and the element penetrating the through hole 32 1 is provided with a heat sink 4 provided with a projecting portion 43 that is in contact with the heat radiating portion 12 with the heat conducting material 2 interposed therebetween, and with a heat radiating fin 42 that increases the heat radiating area. Heat dissipation performance can be improved.

  (10) The element 1 is mounted on the substrate 3 so that the element heat dissipation part 12 of the element 1 is exposed to the substrate side in the heat dissipation method of the element 1 that transmits the heat generated by the element 1 to the radiator 4 to dissipate heat. The substrate 3 is provided with through holes 32 that penetrate the mounting surface and the back side of the mounting surface, and the heat radiation fins 42 that expose the element heat radiation portion 12 of the mounted element 1 to the back side of the substrate 3 and increase the heat radiation area are provided. The provided radiator 4 is provided with a projecting portion 43, and the projecting portion 43 passes through the through-hole 32 so as to be in contact with the element heat radiating portion 12 of the element 1 through the heat conducting material 2, and the heat generation of the element 1 is substrated. Since the heat is transmitted to the projecting portion 43 of the radiator 4 that has passed through the three through holes 32, the heat dissipation performance that suppresses the temperature rise of the element can be improved.

Example 2 is an example in which a substrate and a radiator are joined with an adhesive.
The configuration will be described.
FIG. 7 is an explanatory cross-sectional view showing the heat dissipation structure of the element of the second embodiment.
In Example 2, several places between the lower surface of the substrate 3 and the radiator 4 are bonded with an adhesive 9.
The space between the lower surface of the substrate 3 and the radiator 4 is a gap in many parts.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In the heat dissipation structure of the element of Example 1 and Example 2, the circuit pattern (copper foil) provided on the substrate 3 does not transfer heat to the radiator 4. Therefore, the substrate 3 and the radiator 4 do not need to be in close contact with each other. Therefore, as in the second embodiment, even if a gap is provided between the upper surface of the radiator 4 and the lower surface of the substrate 3 so as to be partially bonded, the heat radiation performance is not affected. Therefore, it is possible to provide a mounting structure that suppresses costs, and it is also possible to mount electronic components between the substrate 3 and the radiator 4.

Explain the effect.
In addition to the above (1) and (10), the element heat dissipation structure of Example 2 has the following effects.
(2) In the above (1), since the back side of the mounting surface of the substrate 3 and the upper surface of the radiator 4 are separated from each other, it is possible to make a structure that further suppresses costs, such as partially bonding with an adhesive 9. .
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

Example 3 is an example in which a flexible substrate is used as the substrate.
The configuration will be described.
FIG. 8 is an explanatory cross-sectional view showing the heat dissipation structure of the element of Example 3.
In Example 3, the flexible substrate 37 is used as the substrate. The flexible substrate 37 is provided with a through hole 371 for allowing the protruding portion 43 to pass therethrough. The lower surface of the flexible substrate 37 is bonded to the upper surface of the radiator 45 by an adhesive 91 by bonding. Since the flexible substrate 37 is thinner than the substrate 3, the height of the protrusion 43 is changed in accordance with this.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In the third embodiment, the flexible substrate 37 is used. However, since the flexible substrate 37 is not required to have a function of conducting heat, the cost of the base material of the flexible substrate 37 is suppressed.
That is, it is possible to use a base material having a low heat resistant temperature. Moreover, the adhesive 91 having a low heat-resistant temperature can be used, and the cost is suppressed.
Note that the flexible substrate 37 and the heat radiator 45 may be fixed by partially bonding them with a gap.
The flexible substrate 37 has advantages in its arrangement, shape, and three-dimensional circuit structure. Even under such conditions, the element 1 can dissipate heat efficiently.

Explain the effect.
In addition to the above (1) and (10), the element heat dissipation structure of Example 3 has the following effects.
(3) In the above (1) or (2), since the substrate is the flexible substrate 37, the heat resistant temperature of the base material of the flexible substrate 37 can be lowered.
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

Example 4 is an example in which the protruding portion is formed of a heat conductive material.
The configuration will be described.
FIG. 9 is an explanatory cross-sectional view showing the heat dissipation structure of the element of Example 4.
In Example 4, the upper surface of the radiator 46 is a flat surface without providing a protrusion. Then, the lower surface of the flexible substrate 37 and the upper surface of the radiator 46 are joined by the heat conductive material 21 having adhesiveness. Then, on the upper surface of the heat conducting material 21, a protruding portion 211 that penetrates the through hole 371 and contacts the element heat radiating portion 12 of the element 1 is provided as the heat conducting material 21.
Since other configurations are the same as those of the third embodiment, the description thereof is omitted.

The operation will be described.
In Example 4, since the protrusion part 211 is provided as a part of the heat conductive material 21, this protrusion part 211 adheres to the element heat radiation part 12 with the adhesiveness. Since the flexible substrate 37 provided with the through hole 371 is thin, it is easier to manufacture the protrusion 211 with the heat conductive material 21. This further reduces costs.
In addition, the element radiating portion 12 and the radiator 4 of the element 1 can be fixed and the radiator 4 and the flexible substrate 37 can be fixed by the same member, which further reduces the cost.

Explain the effect. In addition to the above (1), (3), and (10), the element heat dissipation structure of Example 4 has the following effects.
(4) In the above (3), the projecting portion 211 is formed integrally with the heat conducting material 21, and the heat conducting material 21 is an adhesive member, and the radiator 46 is connected to the element heat radiating portion 12 of the element 1. Since the fixing and fixing of the radiator 46 to the flexible substrate 37 are performed, the cost can be further reduced.
Since other functions and effects are the same as those of the third embodiment, description thereof is omitted.

Example 5 is an example in which a plurality of elements are installed on the same substrate.
The configuration will be described.
FIG. 10 is an explanatory perspective view of a heat dissipation structure for an element according to the fifth embodiment.
In the fifth embodiment, a plurality of terminal portions 31 and through holes 32 are arranged on the substrate 38, and a plurality of elements are mounted on the substrate 38.
The radiator 47 is sized to radiate heat from the plurality of elements 1, and a plurality of protrusions 43 are provided on the upper surface. The heat conductive material 2 is provided on the upper surface of the protrusion 43.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In the fifth embodiment, the heat of the plurality of elements 1 is radiated by the substrate 38. When it is necessary to mount a plurality of elements 1 that require cooling on the substrate 38 due to the circuit configuration, the common radiator 47 may be used. By using the common radiator 47, the operation is easy and the number of parts is reduced.

Explain the effect.
In addition to the above (1) to (4), (10), the element heat dissipation structure of Example 5 has the following effects.
(5) In the above (1) to (4), the substrate 38 includes a plurality of through holes 32, the radiator 47 includes a plurality of protrusions 43, and the plurality of elements 1 are radiated by the common radiator 47. Therefore, the work can be facilitated and the number of parts can be reduced.

Example 6 is an example in which an annular element fixing copper foil part is provided and joined to the element heat dissipation part.
The configuration will be described.
FIG. 11 is an explanatory sectional view of a heat dissipation structure for an element according to the sixth embodiment. FIG. 12 is a partially enlarged view of FIG. FIG. 13 is an explanatory perspective view showing a heat dissipation structure of an element according to the sixth embodiment.
In Example 6, an annular element fixing copper foil portion 301 is provided around the through hole 32 on the element side surface of the substrate 3. The element fixing copper foil portion 301 is a copper foil portion similar to that provided as an energization pattern on the substrate 3.

In Example 6, as shown in FIGS. 11 to 13, the relationship between the radial size of the circular element heat radiating portion 12, the heat conducting material 2, and the protrusion 43 of the radiator 4 is the element heat radiating portion. The outer diameter of the protrusion part 43 of the heat conductive material 2 and the radiator 4 is made smaller than the outer diameter of 12.
Furthermore, the relationship between the radial size of the circular element heat radiating portion 12 and the element fixing copper foil portion 301 is such that the outer diameter of the element heat radiating portion 12 is larger than the inner diameter of the element fixing copper foil portion 301 and the element fixing copper foil portion 301 is fixed. The outer diameter of the element heat radiation part 12 is made smaller than the outer diameter of the copper foil part 301.
As a result, the outer peripheral end of the element heat radiating portion 12 is configured such that the inner diameter side of the element fixing copper foil portion 301 faces the surface.

In Example 6, first, the protrusion 43 of the radiator 4 is inserted into the through hole 32 of the substrate 3, and the radiator 4 is fixed to the substrate 3 with screws 5 as shown in FIG. 13. Next, the element heat dissipating part 12 of the element 1 is attached to the heat conducting material 2 provided on the end surface of the protruding part 43 protruding from the through hole 32 of the substrate 3. It is desirable from the viewpoint of workability that the heat conductive material 2 is an adhesive member.
And the terminal 11 of the element 1 and the terminal part 31 of the board | substrate 3, the element thermal radiation part 12, and the copper foil part 301 for element fixation are solder-joined. The solder part 61 of the element heat radiating part 12 and the element fixing copper foil part 301 has an assembled structure to be an annular solder part.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In Example 6, the soldering of the element 1 and the substrate 3 is performed uniformly in a furnace at a predetermined temperature. At that time, since the lower surface of the element 1 is joined in an annular shape, the element 1 is stabilized. This prevents the element 1 from being tilted and soldered.
And since the element heat dissipation part 12 and the copper foil part 301 for element fixation which were joined are thermally conducted via the solder part 61, the heat dissipation of an element improves.

  In addition, since the heat conducting material 2 has elasticity, when it is sufficiently in close contact with the element 1, a force that urges the element 1 upward, that is, a force that separates the element 1 from the substrate 3 is applied. On the other hand, in Example 6, the element fixing copper foil portion 301 joined by the annular solder portion 61 sufficiently receives this urging force. Therefore, stress is generated in the solder portion 6 between the terminal 11 of the element 1 and the terminal portion 31 of the substrate 3, and it is reliably prevented that the crack and the solder portion 6 and the terminal portion 31 are separated. That is, the stress of the solder portion 6 of the terminal 11 is reduced.

In addition, when vibration is applied to the entire structure in which the element 1, the substrate 3, the radiator 4, and the like are integrated, the element 1 moves the element 1 upward from the protrusion 43 of the radiator 4 through the heat conductive material 2. A biasing force, that is, a force for separating the element 1 from the substrate 3 is applied.
Also against this, the element fixing copper foil portion 301 joined by the annular solder portion 61 sufficiently receives this urging force. Therefore, the stress of the solder portion 6 of the terminal 11 is reduced.

Explain the effect.
The element heat dissipation structure of Example 6 has the following effects in addition to the above (1) to (5) and (10).
(6) In the above (1) to (5), the substrate 3 includes the element fixing copper foil portion 301 in which the energization pattern is formed in a shape surrounding the periphery of the through hole 32, and the element heat radiation portion 12 of the element 1 and the substrate Since the element fixing copper foil portion 301 is joined by the solder portion 61, solder cracks and peeling of the terminal portion can be prevented, and the device can be prevented from being inclined and joined at the time of solder joining. .
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

Example 7 is an example in which an annular element fixing copper foil portion is extended to the inner wall of the through hole of the substrate.
The configuration will be described.
FIG. 14 is an explanatory sectional view of a heat dissipation structure for an element according to the seventh embodiment. FIG. 15 is a partially enlarged view of FIG. FIG. 16 is an explanatory perspective view showing a heat dissipation structure of an element according to the seventh embodiment.
In Example 7, the inner wall portion 302 having a shape in which the end portion in the inner circumferential direction of the annular element fixing copper foil portion 301 is extended downward, that is, toward the radiator 4 so as to be the inner wall of the through hole 32 of the substrate 3. Is provided. The inner wall portion 302 is an integral part of the element fixing copper foil portion 301 and is a copper foil portion similar to the substrate 3. The inner wall 302 has a cylindrical shape and is provided as an energization pattern that is in close contact with the inner wall of the through hole 32 of the substrate 3.
The lower end of the inner wall portion 302 is positioned inside the through hole 32 as shown in FIGS.
Since other configurations are the same as those of the sixth embodiment, the description thereof is omitted.

The operation will be described.
In Example 7, an inner wall 302 that extends the element fixing copper foil 301 provided on the substrate 3 to the inner wall of the through hole 32 is provided. The element fixing copper foil portion 301 and the inner wall portion 302 are copper foil portions that are similar to the energization pattern, and are fixed to the substrate 3. Therefore, by increasing the area, the force in the direction in which the element 1 is separated from the substrate 3. Will be more strongly received. Thereby, the stress generated in the solder portion 6 between the terminal 11 of the element 1 and the terminal portion 31 of the substrate 3 is further reduced, and the occurrence of cracks and peeling of the solder portion 6 and the terminal portion 31 is further reliably prevented. .

Explain the effect.
The element heat dissipation structure of Example 7 has the following effects in addition to the above (1) to (6) and (10).
(7) In the above (6), the element fixing copper foil portion 301 is provided with the inner wall portion 302 that extends the end portion on the inner peripheral side to the inner wall of the through hole, thereby preventing solder cracks and peeling of the terminal portion. Can do.

Example 8 is an example in which a plurality of through holes and element fixing copper foil portions are provided on a substrate, and a plurality of elements are installed on the same substrate.
The configuration will be described.
FIG. 17 is an explanatory perspective view of a heat dissipation structure for an element according to the eighth embodiment.
In Example 8, a plurality of terminal portions 31 and through holes 32 are arranged on the substrate 38, and an annular element fixing copper foil portion 301 is provided around the through holes 32. Then, the plurality of elements 1 are mounted on the substrate 38.
The radiator 47 is sized to radiate heat from the plurality of elements 1, and a plurality of protrusions 43 are provided on the upper surface. The heat conductive material 2 is provided on the upper surface of the protrusion 43.
Since other configurations are the same as those of the sixth embodiment, the description thereof is omitted.

The operation will be described.
In the case of mounting a plurality of elements 1 on the board 38 in terms of circuit configuration, if the common radiator 47 is used in this way, the operation is easy and the number of parts is reduced. The heat sink 47 becomes larger by this commonization, but the element heat radiation portion 12 of each element 1 and the element fixing of the substrate 3 are fixed so that the vibration does not cause cracks or peeling in the solder portion 6 of the element 1. The stress is sufficiently reduced by the solder portion 61 of the copper foil portion 301 for use.

Explain the effect.
The element heat dissipation structure of Example 8 has the following effects in addition to the above (1) to (4), (10).
(5) ′ In the above (1) to (4), the substrate 38 includes a plurality of through holes 32 and an element fixing copper foil portion 301 in which an energization pattern is formed in a shape surrounding the through holes 32. 1 heat sink 47 and the element fixing copper foil portion 301 of the substrate 3 are joined by a solder portion 61. The heat sink 47 includes a plurality of protrusions 43, and the plurality of elements 1 are connected by a common heat sink 47. Since heat is dissipated, the work can be facilitated and the number of parts can be reduced. Further, the stress generated in the solder portion 6 of the terminal portion of the element 1 due to the vibration of the radiator 47 that has become larger due to the common use can be reduced.

Example 9 is an example in which a printing unit and a bracket for supporting an element are provided.
The configuration will be described.
FIG. 18 is an explanatory sectional view of a heat dissipation structure for an element according to Example 9. FIG. 19 is an explanatory perspective view showing the heat dissipation structure of the element of Example 9.
In the ninth embodiment, an annular fixing silk printing portion 303 is provided around the through hole 32 on the element side surface of the substrate 3. The fixing silk printing portion 303 is a printing portion provided at a height at which the upper surface of the fixing silk printing portion 303 is in contact with and supported by the lower surface of the element 1.
In Example 9, as shown in FIG. 18, the radial size of the heat radiating portion 12 is made smaller than the inner diameter of the fixing silk printing portion 303 and has a gap in the radial direction.

Furthermore, the board 3 of Example 9 is provided with a copper foil portion 304 for brackets in a direction substantially orthogonal to the direction in which the through hole 32 is at the center and the pair of terminal portions 31 are provided. The bracket copper foil part 304 is provided so as to face the through hole 32. The bracket copper foil portion 304 is a copper foil portion similar to the pattern provided on the substrate 3 for energization.
In the ninth embodiment, a bracket 305 is provided. As shown in FIGS. 18 and 19, the bracket 305 further extends from the end of the flat portion that contacts the upper surface of the element, the portion that extends obliquely downward from both ends of the flat portion, and the portion that extends obliquely downward. The shape includes a flat portion 305a provided. Then, the flat portions 305 a provided at both ends serve as portions for soldering with the bracket copper foil portion 304 of the substrate 3.

In the ninth embodiment, first, the protrusion 43 of the radiator 4 is inserted into the through hole 32 of the substrate 3, and the radiator 4 is fixed to the substrate 3 with screws 5 as shown in FIG. 13. Next, the element heat dissipating part 12 of the element 1 is attached to the heat conducting material 2 provided on the end surface of the protruding part 43 protruding from the through hole 32 of the substrate 3. At this time, the lower surface of the element 1 comes into contact with the fixing silk printing portion 303. Next, the bracket 305 is disposed in combination with the element 1, and the terminal 11 of the element 1 and the terminal portion 31 of the substrate 3, the planar portions 305 a at both ends of the bracket 305, and the copper foil portion 304 for the bracket of the substrate 3 are joined by soldering. It is a configuration. Solder portions of the planar portions 305 a at both ends of the bracket 305 and the bracket copper foil portion 304 of the substrate 3 are referred to as solder portions 62.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In the ninth embodiment, when soldering is performed in a furnace or the like, a portion in the outer peripheral direction from the element heat radiating portion 12 is in contact with and supported by the fixing silk printing portion 303 on the lower surface of the element 1. Therefore, the element 1 is stabilized and the element 1 is prevented from being tilted and soldered. Since the metal bracket 305 is in contact with the element 1 from above, heat generated by the element 1 is also transmitted to the bracket 305, so that heat dissipation is improved.

  Further, the bracket 305 receives a force for separating the element 1 from the substrate 3 due to an urging force or vibration caused by the heat conducting material 2. Thereby, the stress which arises in the solder part 6 of the terminal 11 of the element 1 and the terminal part 31 of the board | substrate 3 is reduced, and it is prevented reliably that a crack and peeling of the solder part 6 and the terminal part 31 arise.

Explain the effect. The element heat dissipation structure of Example 9 has the following effects in addition to the above (1) to (5) and (10).
(8) In the above (1) to (5), the substrate 3 includes a fixing silk printing portion 303 in which a silk printing portion is formed in a shape surrounding the periphery of the through hole 32, and is in a direction away from the substrate 3 of the element 1. Since the bracket 305 that covers the element 1 is provided so as to limit the movement to the terminal, solder cracks and peeling of the terminal portion can be prevented, and the element can be prevented from being inclined and joined during solder joining.
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

Example 10 is an example in which a bracket that supports the element and restricts movement in a direction away from the substrate is provided.
The configuration will be described.
FIG. 20 is an explanatory cross-sectional view of the heat dissipation structure for the element according to Example 10 of Example 10. FIG. 21 is an explanatory perspective view showing a heat dissipation structure of an element according to the tenth embodiment.
In Example 10, the bracket copper foil 304 is provided in a direction substantially orthogonal to the direction in which the through hole 32 of the substrate 3 is in the center and the pair of terminal portions 31 is provided, and the bracket 306 is provided.

As shown in FIGS. 20 and 21, the bracket 306 is composed of symmetrical brackets 306 a and 306 b, and has a structure in which the element 1 is assembled so as to sandwich the element 1 from the lateral direction.
As shown in FIG. 20, the brackets 306 a and 306 b perform solder bonding between a substantially U-shaped or substantially U-shaped portion that fixes the end of the element in the left-right direction and the bracket copper foil portion 304 of the substrate 3. It has a flat part. In addition, the opening of the part which fixes the element 1 is a shape which faces the element side, ie, a horizontal direction.
In addition, the portion for fixing the element 1 is shaped to support and cover both end portions of the element 1. The center of the element 1 has a structure in which a free state portion is provided.

In Example 10, first, the protrusion 43 of the radiator 4 is inserted into the through hole 32 of the substrate 3, and the radiator 4 is fixed to the substrate 3. Next, the left and right ends of the element 1 are assembled so as to be inserted into the brackets 306 a and 306 b, respectively, and the heat conductive material 2 provided on the end surface of the protruding portion 43 protruding from the through hole 32 of the substrate 3 is attached to the element 1. The element heat radiation part 12 is stuck. In addition, the terminal 11 of the element 1, the terminal portion 31 of the substrate 3, the planar portions of both ends of the bracket 306, and the bracket copper foil portion 304 of the substrate 3 are soldered together.
Since other configurations are the same as those of the first embodiment, description thereof is omitted.

The operation will be described.
In Example 10, since the metal bracket 306 is in contact with both ends of the element 1 from above and below, the heat generated by the element 1 is also transmitted to the bracket 306, so that heat dissipation is improved.
Since the element 1 is fixed in the direction approaching and separating from the substrate by the bracket 306, the element 1 is stabilized and the element 1 is tilted and solder-bonded when the terminals 11 of the element 1 are soldered. Is prevented.

  Further, the bracket 306 receives a force for separating the element 1 from the substrate 3 due to an urging force or vibration caused by the heat conducting material 2. Thereby, the stress which arises in the solder part 6 of the terminal 11 of the element 1 and the terminal part 31 of the board | substrate 3 is reduced, and it is prevented reliably that a crack and peeling of the solder part 6 and the terminal part 31 arise.

Explain the effect.
The element heat dissipation structure of Example 10 has the following effects in addition to the above (1) to (5) and (10).
(9) Since the bracket 306 for fixing the element 1 is provided so as to limit the movement of the element 1 in the direction close to and away from the substrate 3, solder cracks and peeling of the terminal portion can be prevented, It is possible to prevent the elements from being inclined and bonded at the time of bonding.
Since other functions and effects are the same as those of the first embodiment, description thereof is omitted.

Example 11 is an example in which a plurality of through holes, a fixing silk print portion, and a bracket copper foil portion are provided on a substrate, and the bracket is assembled to the element and a number of elements are installed on the same substrate.
The configuration will be described.
FIG. 22 is an explanatory perspective view of a heat dissipation structure for an element according to the eleventh embodiment.
In Example 11, a plurality of terminal portions 31 and through holes 32 are arranged on the substrate 38, and an annular fixing silk printing portion 303 is provided around the through holes 32. Then, the bracket 305 is assembled to the element 1, and the plurality of elements 1 are mounted on the substrate 38.
The radiator 47 is sized to radiate heat from the plurality of elements 1, and a plurality of protrusions 43 are provided on the upper surface. The heat conductive material 2 is provided on the upper surface of the protrusion 43.
Since other configurations are the same as those of the ninth embodiment, the description thereof is omitted.

The operation will be described.
In the case of mounting a plurality of elements 1 on the board 38 in terms of circuit configuration, if the common radiator 47 is used in this way, the operation is easy and the number of parts is reduced. The heat sink 47 is enlarged by this commonization, but the stress is sufficiently reduced by the bracket 305 so that the vibration does not cause cracks or peeling in the solder portion 6 of the element 1.

Explain the effect.
The element heat dissipation structure of Example 11 has the following effects in addition to the above (1) to (4), (10).
(5) ′ In the above (1) to (4), the substrate 38 includes a plurality of through holes 32 and a fixing silk printing portion 303 in which a printed portion is formed in a shape surrounding the periphery of the through holes 32. The silk printing unit 303 supports the element 1 and the bracket 305 restricts the movement of the element 1 in the direction away from the substrate 3. The radiator 47 includes a plurality of protrusions 43, and the plurality of elements 1 are shared. Since heat is radiated by the heat radiator 47, the work can be facilitated and the number of parts can be reduced. Further, the stress generated in the solder portion 6 of the terminal portion of the element 1 due to the vibration of the radiator 47 that has become larger due to the common use can be reduced.
Since other functions and effects are the same as those of the ninth embodiment, description thereof is omitted.

Example 12 is an example in which a plurality of through holes, a fixing silk printing portion, and a copper foil portion for bracket are provided on a substrate, a plurality of devices are assembled in one bracket, and a number of devices are installed on the same substrate. is there.
The configuration will be described.
FIG. 23 is an explanatory perspective view of a heat dissipation structure for an element according to the twelfth embodiment.
In the twelfth embodiment, a plurality of terminal portions 31 and through holes 32 are arranged on the substrate 38, and an annular fixing silk printing portion 303 is provided around the through holes 32. The bracket 307 includes a long planar portion that covers the upper surfaces of the plurality of elements 1 arranged in a row at intervals, and a portion that is soldered on both sides of each element 1.
Then, the brackets 307 are assembled to the plurality of elements 1, and the plurality of elements 1 are mounted on the substrate 38.
The radiator 47 is sized to radiate heat from the plurality of elements 1, and a plurality of protrusions 43 are provided on the upper surface. The heat conductive material 2 is provided on the upper surface of the protrusion 43.
Since other configurations are the same as those of the ninth embodiment, the description thereof is omitted.

The operation will be described.
In the case of mounting a plurality of elements 1 on the board 38 in terms of circuit configuration, if the common radiator 47 is used in this way, the operation is easy and the number of parts is reduced. The heat sink 47 becomes larger due to this commonization, but the stress is sufficiently reduced by the bracket 307 so that the vibration does not cause cracking or peeling in the solder portion 6 of the element 1.
In addition, since the bracket 307 has a long plane so as to span the plurality of elements 1, the heat dissipation of the element 1 is further improved.

Explain the effect.
The element heat dissipation structure of Example 12 has the following effects in addition to (1) to (4) and (10) above.
(5) ′ In the above (1) to (4), the substrate 38 includes a plurality of through-holes 32 and a fixing silk printing portion 303 in which a printed portion is formed in a shape surrounding the periphery of the through-hole 32. A bracket 307 for restricting the movement of the element 1 in the direction away from the substrate 3 is provided, the element 1 is supported by the fixing silk printing unit 303, and the movement of the element 1 in the direction away from the substrate 3 is restricted by the bracket 307. The heat radiator 47 includes a plurality of projecting portions 43, and the plurality of elements 1 are radiated by the common heat radiator 47, so that the work can be facilitated and the number of parts can be reduced. Further, the stress generated in the solder portion 6 of the terminal portion of the element 1 due to the vibration of the radiator 47 that has become larger due to the common use can be reduced.
Since other functions and effects are the same as those of the ninth embodiment, description thereof is omitted.

  As mentioned above, although the thermal radiation structure and method of the element of this invention were demonstrated based on Example 1-Example 12, it is not restricted to these Examples about a concrete structure, Each of a claim Design changes and additions are permitted without departing from the scope of the claimed invention.

For example, in the embodiment, a radiator is used as the heat radiating means, but a housing such as a unit or a bracket may be used.
For example, the board | substrate 3 of Example 6-Example 12 may be a flexible substrate.

DESCRIPTION OF SYMBOLS 1 Element 11 Terminal 12 Element thermal radiation part 2 Thermal conduction material 2a Thermal conduction material 21 Thermal conduction material 211 Protrusion part 3 Substrate 31 Terminal part 32 Through hole 33 Copper foil part 34 Through hole 35 Copper foil part 36 Copper foil 37 Flexible board 371 penetration Hole 38 Substrate 3a Flexible substrate 3b Aluminum substrate 301 Element fixing copper foil portion 302 Inner wall portion 303 Fixing silk print portion 304 Bracket copper foil portion 305 Bracket 305a Flat portion 306 Brackets 306a and 306b Bracket 307 Bracket 4 Radiator 41 Plate shape Part 42 Radiation fin 43 Projection part 44 Mounting hole 4a Radiator 45 Radiator 46 Radiator 47 Radiator 5 Screw 6 Solder part 61 Solder part 62 Solder part 7 Adhesive 8 Insulating layer 9 Adhesive 91 Adhesive

Claims (10)

In the heat dissipation structure of the element that transmits the heat generated by the element to the heat dissipation means and performs heat dissipation,
An element mounted on a substrate and provided with a heat radiation portion exposed on the surface on the substrate side;
A substrate provided with a through hole penetrating the mounting surface and the back side of the mounting surface to expose the heat dissipation portion of the element to the back side of the mounting surface;
A heat dissipating means provided with a projecting portion penetrating the through hole and contacting the heat dissipating portion of the element via a heat conductive material, and having a heat dissipating portion for increasing the heat dissipating area;
With
An element heat dissipation structure. In the heat dissipation structure of the element according to claim 1,
The back side of the mounting surface of the substrate and the upper surface of the heat dissipating means are spaced apart,
An element heat dissipation structure. In the heat dissipation structure of the element according to claim 1 or claim 2,
The substrate is a flexible substrate.
An element heat dissipation structure. In the heat dissipation structure of the element according to claim 3,
The protrusion is formed integrally with the heat conductive material,
The heat conducting material is an adhesive member, and has a structure for fixing the heat dissipation means to the heat dissipation portion of the element and fixing the heat dissipation means to the flexible substrate.
An element heat dissipation structure. In the heat dissipation structure of the element according to any one of claims 1 to 4,
The substrate includes a plurality of the through holes,
The heat dissipation means includes a plurality of the protruding portions,
Dissipate multiple elements by common heat dissipation means,
An element heat dissipation structure. In the element heat dissipation structure according to any one of claims 1 to 5,
The substrate includes element fixing means in which an energization pattern is formed in a shape surrounding the periphery of the through hole,
The heat dissipation means of the element and the element fixing means of the substrate are joined.
An element heat dissipation structure. In the heat dissipation structure of the element according to claim 6,
The element fixing means extends the inner peripheral end to the inner wall of the through hole,
An element heat dissipation structure. In the element heat dissipation structure according to any one of claims 1 to 5,
The substrate includes element fixing means in which a printed portion is formed in a shape surrounding the periphery of the through hole,
A bracket is provided to cover the element so as to limit movement of the element in a direction away from the substrate.
An element heat dissipation structure. In the element heat dissipation structure according to any one of claims 1 to 5,
A bracket for fixing the element so as to limit the movement of the element in a direction approaching and separating from the substrate;
An element heat dissipation structure. In the heat dissipation method of the element that transmits the heat generation of the element to the heat dissipation means and performs heat dissipation,
The element is mounted on the substrate so that the heat dissipation portion of the element is exposed to the substrate side,
The substrate is provided with a through hole that penetrates the mounting surface and the back side of the mounting surface, and the heat dissipation portion of the mounted element is exposed to the back side of the substrate,
Providing a protrusion on the heat dissipating means provided with a heat dissipating part that increases the heat dissipating area, the protrusion passes through the through hole and makes contact with the heat dissipating part of the element via a heat conducting material
The heat generated by the element is transferred to the protrusion of the heat radiating means passing through the through hole of the substrate to dissipate heat.
An element heat dissipation method.

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