KR101707111B1 - Electrical connector - Google Patents

Abstract

An electrical connector of the present invention comprises: a thermal conductance case; at least one base which is installed in the thermal conductance case and has upper and lower push-pull holes; at least one up and down separation thermal conductance component which includes an upper separation plate having an upper hole, a front panel being joined and connected to a front side of the upper separation plate and a front side of a lower separation plate, and the lower separation plate while the upper separation plate has an upper hole and the lower separation plate has a lower hole and corresponds with the upper push-pull hole and the lower push-pull hole by dividing the thermal conductance case with an upper push-pull path and a lower push-pull path; at least one upper thermal conductance panel which includes an upper thermal conductance side, a lower thermal conductance side, and at least one unit of a first airflow path, located between the upper thermal conductance side and the lower thermal conductance side, includes at least one thermal conductance component, installed in the upper and lower separation thermal conductance component, and at least one upper thermal conductance plate protruding to the inside of the upper push-pull path, is installed in the upper hole, and is connected to the upper thermal conductance side; and at least one lower thermal conductance panel which includes one lower thermal conductance plate, protruding in the lower push-pull path, is installed in the lower hole, and is connected to the lower thermal conductance side. Accordingly, the temperature of the lower push-pull path of the electrical connector can be decreased by a simple structure.

Description

ELECTRICAL CONNECTOR

The present invention provides an electrical connector, and more particularly, to an electrical connector capable of lowering the temperature of the lower push-pull passage of the electrical connector with a simple structure.

Electrical connectors are often used for data transmission in electronic devices. Typical electrical connectors, however, often experience lower heat dissipation in the lower push-pull passageways when transmitting data, resulting in higher temperatures. As a result, the heat conduction panel of U.S. patent no. 2013/0164970 A1 has one main wall or at least one side wall (U or L), and the spring finger support is fixed to the side wall. And the ability of the spring fingers to reduce contact thermal resistance to transfer the heat generated by the electrical connector to the heat conduction panel and then dissipate heat through the heat dissipation plate outside the conduction panel. However, due to the limited use environment of the electrical connector, the transverse heat dissipation plate on the main wall of the heat conducting panel of the electrical connector in parallel occupies too much space. Also, since the spring finger supports are assembled to the electrical connector through the heat conduction panel, both the assembly process and the structure are complicated. And because the spring finger supports are installed in the upper push-pull passage of the electrical connector and the lower push-pull passage, the contact force of the push-pull device and the push-pulling force are both difficult to reach perfection.

Therefore, the present invention intends to propose how to invent an electric connector that can lower the temperature of the lower push-pull passage of the electric connector with a simple structure.

The inventor, who is aware of the drawbacks of the existing techniques described above, has studied to solve such drawbacks and invented the electric connector for the purpose of lowering the temperature of the lower push-pull passage of the electric connector with a simple structure.

To achieve these and other objects, the first form of the invention provides an electrical connector, which includes: a heat conduction case. At least one base installed in the heat-conducting case and having an upper and lower push-pull hole. There is one top separator, one front panel, and one bottom separator, the front panel is connected between the front of the top separator and the front of the bottom separator, the top separator has an upper hole, There is a hole, at least one heat conduction component separated up and down. The up-and-down detachable heat-conducting part separates the heat-conducting case into one upper push-pull passage and one lower push-pull passage to correspond to the corresponding upper push-pull hole and lower push-pull hole. There is one upper heat conduction surface, one lower heat conduction surface, and at least one first air flow passage, the first air flow passage being between the upper heat conduction surface and the lower heat conduction surface, and at least one heat conduction component . At least one upper thermal conductive plate projecting into the upper push-pull passage and at least one upper thermal conductive panel installed in the upper opening and connected to the upper thermal conductive surface. And at least one lower thermal conductive plate protruding from the lower push-pull passage, and at least one lower thermal conductive panel installed in the lower opening and connected to the lower thermal conductive surface.

In the electrical connector of the first form, when there are several bases, the bases are installed in the heat conduction case in such a manner that they are arranged horizontally. The electrical connector further includes at least one left and right detachable heat transfer panel, which has a plurality of left and right heat transfer plates in the left and right separation heat transfer panel. And the left and right separation heat conduction panels separate the upper and lower push-pull passages, the upper and lower split heat conduction parts, and the lower push-pull passage on the left and right sides. The left thermally conductive plate projects into the upper push-pull passage and the lower push-pull passage, and the right thermally conductive plate also protrudes into the upper push-pull passage and the lower push-pull passage.

In the first type of electrical connector, the front panel of the upper and lower discrete thermally conductive parts has at least one forward airflow hole, at least one second airflow passage between the upper push-pull hole and the lower push- The hole, the first airflow passage, and the second airflow passage are in turn connected and communicated.

In the first type of electrical connector, the upper heat conductive surface of the thermally conductive component is planar, and the lower thermal conductive surface of the heat conductive component is planar.

In the first type of electrical connector, the upper heat conducting panel is integrated with the upper separating plate of the upper and lower separating heat conducting parts, and the lower heat conducting panel is integrated with the lower separating plate of the upper and lower separating heat conducting parts.

In the first type of electrical connector, when there are several upper thermally conductive plates of the upper thermally conductive panel, the upper thermally conductive plate protrudes into the upper push-pull passage and contacts the upper thermally conductive surface of the thermally conductive component. If there are several lower thermally conductive plates of the lower thermally conductive panel, they project into the lower push-pull passage and contact the lower thermally conductive surface of the thermally conductive component.

The electrical connector of the first type further includes a push-pull device which is received in the upper push-pull passage or the lower push-pull passage and contacts the upper thermally conductive plate of the upper thermally conductive panel or the lower thermally conductive plate of the lower thermally conductive panel.

The electrical connector of the first type further includes a push-pull device which is accommodated in the upper push-pull passage or the lower push-pull passage and contacts the upper heat conduction plate of the upper heat conduction panel or the lower heat conduction plate of the lower heat conduction panel, The left side thermally conductive plate or the right side thermally conductive plate.

The first type of electrical connector further includes at least one heat dissipation component and at least one top hole in the heat conduction case, the heat dissipation component is installed in the upper hole, and the base of the heat dissipation component is inserted into the upper push- Protruding.

To achieve these and other objects, a second form of the invention provides an electrical connector, which includes: a heat conduction case. At least one base installed in the heat-conducting case and having an upper and lower push-pull hole. There is one top separator, one front panel, and one bottom separator, the front panel is connected between the front of the top separator and the front of the bottom separator, the top separator has an upper hole, There is a hole, at least one heat conduction component separated up and down. The up-and-down detachable heat-conducting part separates the heat-conducting case into one upper push-pull passage and one lower push-pull passage to correspond to the corresponding upper push-pull hole and lower push-pull hole. There is one upper heat conduction surface, one lower heat conduction surface, and at least one first air flow passage, the first air flow passage being between the upper heat conduction surface and the lower heat conduction surface, and at least one heat conduction component . At least one upper heat conduction block installed in the upper hole and connected to the upper heat conduction surface, projecting within the upper push-pull passage. And at least one lower thermal conduction block installed in the lower hole and connected to the lower thermal conductive surface and protruding within the lower push-pull passage.

In the electrical connector of the second type, when there are several bases, the bases are installed in the heat conduction case in such a manner that they are arranged horizontally. The electrical connector further includes at least one left and right detachable heat transfer panel, which has a plurality of left and right heat transfer plates in the left and right separation heat transfer panel. And the left and right separation heat conduction panels separate the upper and lower push-pull passages, the upper and lower split heat conduction parts, and the lower push-pull passage on the left and right sides. The left thermally conductive plate projects into the upper push-pull passage and the lower push-pull passage, and the right thermally conductive plate also protrudes into the upper push-pull passage and the lower push-pull passage.

In the second type of electrical connector, the front panel of the upper and lower discrete thermally conductive parts has at least one forward airflow hole, at least one second airflow passage between the upper push-pull hole and the lower push-pull hole, The hole, the first airflow passage, and the second airflow passage are in turn connected and communicated.

In the electrical connector of the second type, the upper heat conduction surface of the heat conduction part is flat and the lower heat conduction surface of the heat conduction part is flat.

The second type of electrical connector further includes a push-pull device which is received in the upper push-pull passage or the lower push-pull passage and contacts the upper heat conduction block or the lower heat conduction block.

The second type of electrical connector further includes a push-pull device which is installed in the upper push-pull passage or the lower push-pull passage to come into contact with the upper heat conduction block or the lower heat conduction block, and the left heat conduction plate or the right heat conduction plate / RTI >

The second type of electrical connector further has at least one heat dissipation component and at least one top hole in the heat conduction case, the heat dissipation component is installed in the upper hole, and the base of the heat dissipation component is inserted into the upper push- Protruding.

As a result, the electrical connector of the present invention can lower the temperature of the lower push-pull passage of the electrical connector with a simple structure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded view of a structure of an electrical connector used in a first embodiment of the present invention.
FIG. 2 is an exploded perspective view of a side structure of an electrical connector used in a first embodiment of the present invention.
3 is a second view explaining the structure of the electrical connector used in the first embodiment of the present invention.
4 is a first diagram showing a combination of the structures of electrical connectors used in the first embodiment of the present invention.
5 is a second diagram showing a combination of the structures of electrical connectors used in the first embodiment of the present invention.
FIG. 6 is a first view explaining a structure of an electrical connector used in a second embodiment of the present invention.
FIG. 7 is a second view explaining the structure of an electrical connector used in a second embodiment of the present invention.
8 is a diagram showing a combination of the upper heat conduction block and the lower heat conduction block of the second embodiment of the present invention in combination with the heat conduction parts.
9 is a view showing that the upper heat conduction panel and the lower heat conduction panel of the first embodiment of the present invention are integrated with the upper and lower separation heat conduction parts.
FIG. 10 is an exploded view of an electrical connector including a push-pull device according to first and second embodiments of the present invention.
11 is a graph simulating the temperatures of electrical connectors of the first and second embodiments of the present invention, which are relatively specific.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

1 to 5. As shown in the figure, the electrical connector of the first form of the invention comprises a heat conducting case 1, at least one base 2, at least one upper and lower separate heat conducting parts 3, at least one heat conducting part 4 ), At least one upper heat conduction panel (5), and at least one lower heat conduction panel (6). Among them, the heat conduction case 1 may be rectangular. The base 2 has one upper push-pull hole 21 and one lower push-pull hole 22, and the base 2 can be installed on the rear side in the heat conductive case 1. [ The electrical connection surface 24 of the base 2 is exposed to the heat conducting case 1 to connect an electric furnace electrical circuit board (not shown). The upper and lower separating heat conductive parts 3 are each provided with one upper separating plate 31, one front panel 33 and one lower separating plate 32. The front panel 33 is composed of the upper separating plate 31, And the front shaft of the lower separator plate 32. [0033] The upper separation plate 31 has one upper hole 311 and the lower separation plate 32 has one lower hole 321. [ The upper and lower push-pull holes 12 and 22 are separated from each other by the upper and lower push-pull passages 11 and 12 and the heat-conductive case 1 is divided into the upper push- . The number of the upper and lower separated heat conductive parts 3 corresponds to the number of the base 2. The heat conducting component 4 has one upper heat conducting surface 41, one lower heat conducting surface 42, and at least one first air flow passage 43. The first air flow passage 43 is located between the upper heat conduction surface 41 and the lower heat conduction surface 42 and the heat conduction component 4 is installed in the lower heat conduction component 3. The number of the heat conduction parts 4 corresponds to the number of the bases 2. Each of the light conductor receiving areas 44 may be provided on both sides of the heat conduction part 4 to accommodate the light conductor 25. The upper heat conduction panel 5 is provided with at least one upper heat conduction plate 51 and the upper heat conduction panel 5 is provided in the upper hole 311. The upper heat conduction panel 5 is provided on the upper heat conduction surface 41). The upper thermally conductive plate (51) protrudes into the upper push-pull passage (11) to contact the push-pull device. The number of the upper heat conduction panels 5 corresponds to the number of the heat conduction parts 4. If the upper thermally conductive plate 51 is straight, the free end of the upper thermally conductive plate 51 faces the upper push-pull hole 21. Thus, the upper thermally conductive plate 51 can be prevented from blocking the push-pull device. If the upper thermally conductive plate 51 is of a horizontal arcuate shape, the free end of the upper thermally conductive plate 51 may face the upper push-pull hole 21 or the upper push-pull hole 21 backward. The lower heat conduction panel 6 is provided with at least one lower heat conduction plate 61 and the lower heat conduction panel 6 is provided in the lower hole 321. The lower heat conduction panel 6 is provided with a lower heat conduction plate 61 by means of rivets, May be connected to the surface 42. The lower thermally conductive plate 61 protrudes into the lower push-pull passage 12 to contact the push-pull device. The number of the lower heat conduction panels 6 corresponds to the number of the heat conduction parts 4. If the lower thermally conductive plate 61 is straight, the free end of the lower thermally conductive plate 61 faces the lower push-pull hole 22. Thus, the lower thermally conductive plate 61 can be prevented from blocking the push-pull device. If the lower thermally conductive plate 61 is a horizontal arch, the free end of the lower thermally conductive plate 61 may face the lower push-pull hole 22 or the lower push-pull hole 22 back.

See FIGS. 6 to 8. As shown in the figure, the second form of the present invention provides an electrical connector of another structure. The difference between the second form of the electrical connector and the first form is as follows. In the first type of electrical connector, the upper thermally conductive panel 5 with the upper thermally conductive plate 51 is installed in the upper hole 311 of the upper and lower separated thermally conductive parts 3 and is provided with heat conduction through the rivets, latches, Is connected to the upper heat conductive surface (41) of the component (4). And the upper thermally conductive plate 51 protrudes into the upper push-pull passage 11 and contacts the push-pull device. The lower thermally conductive panel 6 with the lower thermally conductive plate 61 is installed in the lower hole 321 of the upper and lower separated thermally conductive parts 3 and is attached to the lower thermally conductive surface 4 of the thermally conductive part 4 through rivets, (42). And the lower thermally conductive plate 61 protrudes into the lower push-pull passage 12 and contacts the push-pull device. However, in the electrical connector of the second type, the upper heat conduction block 5 'is installed in the upper hole 311 of the upper and lower separate heat conduction parts 3 and is connected to the upper heat conduction surface 41 of the heat conduction part 4. Further, the upper heat conduction block 5 'protrudes into the upper push-pull passage 11 and contacts the push-pull device. The lower heat conduction block 6 'is installed in the lower hole 321 of the upper and lower separate heat conduction parts 3 and is connected to the lower heat conduction surface 42 of the thermoelectric part 4. Further, the lower heat conduction block 6 'protrudes into the lower push-pull passage 12 and contacts the push-pull device.

As described above, the electrical connectors of the first and second forms of the present invention are configured such that the upper and lower thermal conductive parts 3, the upper thermal conductive plate 51 and the upper thermal conductive block 5 ' Heat generated in the push-pull device of the electrical connector through the lower heat-conducting block 6 'and the lower heat-conducting plate 61 of the lower heat-conducting panel 6 and the heat-conducting component 4 and the lower heat- The heat generated in the push-pull device is transferred to the heat conduction case 1, and then the heat is discharged from the heat conduction case 1 to the surrounding environment so that the heat is concentrated in the specific region, thereby preventing the temperature of the specific region from rising. Also in the first and second forms of the present invention, the heat conducting part 4 of the electrical connector has the first air flow passage 43 to increase the heat transfer area to improve the heat transfer efficiency. Thus, the electrical connector of the present invention can lower the temperature of the lower push-pull passage of the electrical connector with a simple structure.

Referring again to Figures 1 and 6, in the first and second forms of the electrical connector, as shown in the figure, when there are several bases (2), the bases (2) In the rear side of the inside of the heat conduction case 1. The electrical connector may further include at least one left and right separate heat conducting panel (7). The left and right separate heat conductive panels 7 include a plurality of left side heat conductive plates 71 and a plurality of right side heat conductive plates 72. The left and right separate heat conductive panels 7 separate the upward upper push-pull passage 11, the upper and lower separate heat conductive parts 3, and the lower push-pull passage 12 from each other. The left thermally conductive plate 71 protrudes into the upper push-pull passage 11 and the lower push-pull passage 12, respectively, and contacts the push-pull device. And the right side thermally conductive plate 72 protrudes into and contacts the push-pull device 10 in the upper push-pull passage 11 and the lower-axis push-pull passage 12, respectively. The number of the left and right separate heat conductive panels 7 is a value obtained by subtracting one day from the number of the base 2. The number and arrangement of the left side heat conductive plate 71 and the right side heat conductive plate 72 are the same as those shown in FIGS. But it can be set in a different manner depending on the actual demand. When the left side thermally conductive plate 71 and the right side thermally conductive plate 72 are in a straight shape, the free ends of the left side thermally conductive plate 71 and the right side thermally conductive plate 72 are connected to the upper push-pull hole 11 or the lower push- ). Thus, it is possible to prevent the left thermally conductive plate 71 and the right thermally conductive plate 72 from blocking the push-pull device. The free ends of the left side thermally conductive plate 71 and the right side thermally conductive plate 72 are connected to the upper push-pull hole 21 or the lower push-pull hole 72 (left side thermally conductive plate 71) 22, or the upper push-pull hole 21 or the lower push-pull hole 22 may be directed backward. Thus, when the base 2 is arranged in parallel, the heat generated in the push-pull device of the electric connector, particularly in the push-pull device of the lower push-pull passage 12, flows through the left and right separate heat- And is then discharged from the heat conduction case 1 to the surrounding environment to prevent the heat from being concentrated in a specific area and the temperature of the specific area to rise.

Referring again to Figures 1 and 6, in the electrical connectors of the first and second forms, as shown in the figure, the front panel 33 of the respective upper and lower separated heat transfer component 3 has at least one front air flow There may be a hole 331 and at least one second airflow passageway 23 in the base 2 may be between the upper push-pull hole 21 and the lower push- The front airflow hole 331, the first airflow passage 43, and the second airflow passage 23 are sequentially connected and communicated. In addition, the first and second forms of the electrical connector of the present invention may further include one back plate 9 connected to the rear of the heat conducting case 1 and located at the rear of the base 2. [ The rear plate 9 has at least one rear airflow hole 91 and is connected to and communicates with the second airflow passage 23 of the base 2. In this way, the electrical connectors of the first and second forms of the present invention can not only discharge the heat to the surrounding environment with the above-described structure, but also can be provided with the front airflow hole 331, the first airflow passage 43, the second airflow passage 23 ) And the rear airflow hole 91, the heat transfer efficiency is further improved.

Referring again to Figures 1 and 6, in the electrical connectors of the first and second forms, as shown in the figure, the upper heat conducting surface 41 of the thermally conductive component 4 may be planar, The lower heat conductive surface 42 of the heat sink 4 may also be planar. The upper heat conduction panel 5 and the upper heat conduction block 5 'can be conveniently connected to the upper heat conduction surface 41 and the lower heat conduction panel 6 and the lower heat conduction block 6' ). ≪ / RTI >

Referring again to Figs. 1 and 6, as shown in the figure, the electrical connectors of the first and second forms may further have at least one heat dissipation component 8. The heat dissipation component 8 may have at least one heat dissipation fin 82 and the heat conduction case 1 has at least one top hole 13 so that the heat dissipation component 8 can be inserted into the upper hole 13 ). Then, the base 81 of the heat dispersing element 8 protrudes into the upper push-pull passage 11 and contacts the push-pull device. In this way, the first and second electrical connectors of the present invention not only can discharge the heat to the surrounding environment with the above-described structure, but also generate heat flow through the heat dissipating component 8 to further improve the heat transfer efficiency.

See FIG. The upper heat conduction panel 5 can be integrated with the upper separation plate 31 of the upper and lower separation heat transfer component 3 and the lower heat conduction panel 6 can be integrated with the upper separation plate 31. [ Can be integrated with the lower separator plate 32 of the up-and-down separating heat-conducting component 3. Thus, the structure of the first and second time electrical connectors of the present invention can be simplified.

Referring again to FIG. As shown in the figure, in the first type of electrical connector described above, when the upper heat conduction plate 51 of the upper heat conduction panel 5 is plural, the upper heat conduction plate 51 is located inside the upper push-pull passage 11 And comes into contact with the upper heat conduction surface 41 of the push-pull device and the heat conduction part 4. The lower thermally conductive plate 61 is protruded into the lower push-pull passage 12 so that the lower heat conductive plate 61 of the push-pull device and the lower thermally conductive plate 4 of the heat- 42). Thus, the upper heat conduction plate 51 and the lower heat conduction plate 61 can reliably contact the heat conduction part 4 and the push-pull device to increase the heat transfer efficiency.

See FIG. As shown in the figures, the electrical connectors of the first and second forms described above further include one push-pull device 10 to receive the upper push-pull passage 11 or the lower push-pull passage 12, Contact with the upper heat conduction plate 51 or the upper heat conduction block 5 'of the heat conduction panel 5 or with the lower heat conduction plate 61 or the lower heat conduction block 6' Thus, heat generated in the push-pull apparatus 10 can be surely released to the surrounding environment.

Referring again to FIG. As shown in the figures, the electrical connectors of the first and second forms described above further include one push-pull device 10 to receive the upper push-pull passage 11 or the lower push-pull passage 12, Contact with the upper heat conduction plate 51 or the upper heat conduction block 5 'of the heat conduction panel 5 or with the lower heat conduction plate 61 or the lower heat conduction block 6' of the lower heat conduction panel 6, The left side thermally conductive plate 71 or the right side thermally conductive plate 72 of the left and right separate heat conductive panel 7 are brought into contact with each other. Thus, heat generated in the push-pull apparatus 10 can be surely released to the surrounding environment.

See FIGS. 1, 6 and 11. 11 is a diagram simulating the temperature of the electrical connector. In the same test environment and conditions, the upper part shows the temperature distribution of the general electric connector, and the lower part shows the temperature distribution of the first and second forms of the electric connector of the present invention. The upper heat conduction surface 41 and the lower heat conduction surface 42 of the heat conduction component 4 are connected to the upper heat conduction panel 5 and the lower heat conduction panel 6 respectively or are connected to the upper heat conduction block 5 ' And the temperature distribution of the electrical connector connected to the heat conduction block 6 '. The temperature used is the temperature indicated at the center point of the push-pull device accommodated in each push-pull passage. As shown in the figure, the heat of a typical electrical connector is not easy to transfer, so the heat is concentrated in a specific area, causing the temperature of the particular area to rise. Especially in the push-pull device of the lower push-pull passage. The temperature difference between the push-pull device of the lower push-pull passage and the other zone is from 5 degrees to 8 degrees. In contrast, the heat of the first and second forms of the electrical connector of the present invention is very easy to transfer, so that the heat is not concentrated in a particular area. Therefore, the temperature of the electrical connector is evenly distributed, and the temperature difference between each zone is only 1 degree to 2 degrees.

It should be noted that the above-described embodiments are only examples, and the present invention is not limited thereto. Anything that has substantially the same constitution as the technical idea described in the claims of the present invention and achieves the same operational effects is included in the technical scope of the present invention. Accordingly, those skilled in the art will recognize that various changes, substitutions, alterations, and alterations can be made hereto without departing from the spirit of the invention as defined in the appended claims. I will say.

1 heat conduction case
11 Top push-pull passage
12 Bottom push-pull passage
13 Top hole
2 Base
21 Upper push-hole
22 Lower push-pull hole
23 Second air flow passage
24 Electrical connection face
25 photoconductor
3 upper and lower separation heat conduction parts
31 Upper separation plate
311 Top hole
32 Lower separation plate
321 Lower hole
33 Front panel
331 Front airflow hole
4 Heat conduction parts
41 Top Thermal Drawing
42 Lower Thermoelectric Drawing
43 First air flow passage
44 Photoconductor mounting area
5 Top heat conduction panel
51 Top Heat Conduction Clip
5 'upper heat conduction block
6 Bottom heat conduction panel
61 Bottom heat conduction clip
6 'lower heat conduction block
7 left and right separation heat conduction panel
71 Left heat conduction clip
72 Right-hand heat conduction clip
8 Heat dissipation parts
81 base
82 heat dissipation pin
9 Rear panel
91 Rear airflow slot
10 push-pull devices

Claims (16)

Heat conduction case;
At least one base installed in the heat conduction case and having upper and lower push-pull holes;
Wherein the front panel is connected between the front side of the upper separator and the front side of the lower separator, the upper separator has an upper hole, and the lower separator has an upper hole, a front panel, and a lower separator, At least one upper and lower push-pull passage and at least one lower and upper push-pull hole corresponding to the upper push-pull hole and the lower push-pull hole, the lower heat-
Wherein the first air flow passage is between the upper heat transfer surface and the lower heat transfer surface, and wherein at least one heat transfer component installed in the upper and lower heat transfer components And at least one upper heat conduction plate protruding into the upper push-pull passage, the at least one upper heat conduction panel being installed in the upper hole and connected to the upper heat conduction surface; And
And at least one lower thermally conductive plate protruding from the lower push-pull passage, the at least one lower thermally conductive plate being mounted to the lower hole and connected to the lower heat conductive surface. The method according to claim 1,
When the plurality of bases are provided, the bases are installed in the heat conduction case in such a manner that the bases are arranged horizontally,
Wherein the left and right separation heat conduction panels include a plurality of left side heat conduction plates and a plurality of right side heat conduction plates, and the left and right separation heat conduction panels include left and right separation heat conduction panels, And the lower heat transfer plate and the lower push-pull passage, wherein the left heat transfer plate protrudes into the upper push-pull passage and the lower push-pull passage, and the right heat transfer plate separates the upper push- An electrical connector protruding into the full path. The method according to claim 1,
Wherein at least one forward airflow hole is provided in the front panel of the upper and lower separation heat transfer parts, and at least one second airflow passage is located between the upper push-pull hole and the lower push-pull hole, The first air flow passage, and the second air flow passage are sequentially connected and communicated. The method according to claim 1,
Wherein the upper thermally conductive surface of the thermally conductive component is planar and the lower thermally conductive surface of the thermally conductive component is planar. The method according to claim 1,
Wherein the upper heat conduction panel is integrated with the upper separation plate of the up-and-down separation heat transfer component, and the lower heat transmission panel is integrated with the lower separation plate of the upper and lower separation heat transfer component. 6. The method of claim 5,
Wherein the upper thermally conductive plate protrudes into the upper push-pull passage and contacts the upper thermally conductive surface of the thermally conductive component when the upper thermally conductive plate of the upper thermally conductive panel has a plurality of upper thermally conductive plates, The lower thermally conductive plate is projected into the lower push-pull passage and is in contact with the lower thermally conductive surface of the thermally conductive component. The method according to claim 1,
And a push-pull device accommodated in the upper push-pull passage or the lower push-pull passage and in contact with the upper heat conduction plate of the upper heat conduction panel or the lower heat conduction plate of the lower heat conduction panel. 3. The method of claim 2,
Wherein the upper push-pull passage or the lower push-pull passage is in contact with the upper heat conduction plate of the upper heat conduction panel or the lower heat conduction plate of the lower heat conduction panel, and the left side heat conduction plate or the right side heat conduction plate Further comprising a push-pull device in contact with the plate. The method according to claim 1,
Further comprising at least one heat dispersing element,
Wherein the heat conduction case includes at least one top hole, the heat dissipating component is installed in the top hole, and the base of the heat dissipating component projects into the upper push-pull passage. Heat conduction case;
At least one base installed in the heat conduction case and having upper and lower push-pull holes;
Wherein the front panel is connected between the front side of the upper separator and the front side of the lower separator, the upper separator has an upper hole, and the lower separator has an upper hole, a front panel, and a lower separator, At least one upper and lower push-pull passage and at least one lower and upper push-pull hole corresponding to the upper push-pull hole and the lower push-pull hole, the lower heat-
Wherein the first air flow passage is between the upper heat transfer surface and the lower heat transfer surface, and wherein at least one heat transfer component installed in the upper and lower heat transfer components ;
At least one upper heat conduction block installed in the upper hole and connected to the upper heat conduction surface and protruding into the upper push-pull passage; And
And at least one lower heat transfer block mounted in the lower hole and connected to the lower heat transfer surface and projecting into the lower push-pull passage. The method according to claim 1,
When the plurality of bases are provided, the bases are installed in the heat conduction case in such a manner that the bases are arranged horizontally,
Wherein the left and right separation heat conduction panel includes a plurality of left side heat conduction plates and a plurality of right side heat conduction plates, and the left and right separate heat conduction panels include left and right upper push- Wherein the left thermally conductive plate protrudes into the upper push-pull passage and the lower push-pull passage, and the right thermally conductive plate separates the upper push-pull passage and the lower push- An electrical connector protruding into the passageway. 11. The method of claim 10,
Wherein at least one forward airflow hole is provided in the front panel of the upper and lower separation heat transfer parts, and at least one second airflow passage is located between the upper push-pull hole and the lower push-pull hole, The first air flow passage, and the second air flow passage are sequentially connected and communicated. 11. The method of claim 10,
Wherein the upper thermally conductive surface of the thermally conductive component is planar and the lower thermally conductive surface of the thermally conductive component is planar. 11. The method of claim 10,
And a push-pull device received in the upper push-pull passage or the lower push-pull passage and in contact with the upper heat-conducting block or the lower heat-conducting block. 12. The method of claim 11,
And a push-pull device accommodated in the upper push-pull passage or the lower push-pull passage and in contact with the upper heat-conducting block or the lower heat-conducting block and in contact with the left or right heat- coupler. 11. The method of claim 10,
Further comprising at least one heat dispersing element,
Wherein the heat conduction case includes at least one top hole, the heat dissipating component is installed in the top hole, and the base of the heat dissipating component projects into the upper push-pull passage.

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