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CN-224218410-U - Router

CN224218410UCN 224218410 UCN224218410 UCN 224218410UCN-224218410-U

Abstract

The utility model discloses a router, and relates to the technical field of router structures. The router comprises a shell, a main board, a first heat conduction assembly, a second heat conduction assembly, a first heat dissipation piece and a second heat dissipation piece, wherein the main board, the first heat conduction assembly, the second heat conduction assembly, the first heat dissipation piece and the second heat dissipation piece are arranged in the shell, the first heat dissipation piece and the second heat dissipation piece are respectively arranged on two sides of the main board, the first heat conduction assembly is arranged between the first heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the first heat dissipation piece, and the second heat conduction assembly is arranged between the second heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the second heat dissipation piece. The router provided by the utility model solves the limitation of traditional unilateral heat dissipation, and provides efficient, balanced and reliable technical guarantee for continuous and stable operation of the high-load router.

Inventors

  • JIANG YU
  • ZHAO JIANYI
  • ZHAO JIANBIN

Assignees

  • 深圳市广联智通科技有限公司

Dates

Publication Date
20260508
Application Date
20250416

Claims (10)

  1. 1. The router is characterized by comprising a shell, a main board, a first heat conduction assembly, a second heat conduction assembly, a first heat dissipation piece and a second heat dissipation piece, wherein the main board, the first heat conduction assembly, the second heat conduction assembly, the first heat dissipation piece and the second heat dissipation piece are arranged in the shell, the first heat dissipation piece and the second heat dissipation piece are respectively arranged on two sides of the main board, the first heat conduction assembly is arranged between the first heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the first heat dissipation piece, and the second heat conduction assembly is arranged between the second heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the second heat dissipation piece.
  2. 2. The router of claim 1, further comprising a first shielding cover and a second shielding cover, the first shielding cover and the second shielding cover respectively covering two sides of the motherboard.
  3. 3. The router of claim 2, wherein the first thermally conductive assembly comprises a first thermally conductive gasket and a second thermally conductive gasket, the first thermally conductive gasket is disposed between the motherboard and the first shield cover and in contact with the motherboard and the first shield cover, respectively, and the second thermally conductive gasket is disposed between the first shield cover and the first heat sink and in contact with the first shield cover and the first heat sink, respectively.
  4. 4. The router of claim 3, wherein the second thermally conductive assembly comprises a third thermally conductive gasket disposed between the motherboard and the second shield cover and in contact with the motherboard and the second shield cover, respectively, and a fourth thermally conductive gasket disposed between the second shield cover and the second heat sink and in contact with the second shield cover and the second heat sink, respectively.
  5. 5. The router of claim 4, wherein the first thermally conductive pad at least partially overlaps the projection of the second thermally conductive pad on the first shield cover and the third thermally conductive pad at least partially overlaps the projection of the fourth thermally conductive pad on the second shield cover.
  6. 6. The router of claim 4, wherein the motherboard includes a heat generating device, the first and/or third thermally conductive pads being in contact with the heat generating device.
  7. 7. The router of claim 1, further comprising a cooling fan, wherein the motherboard includes a temperature sensor, wherein the cooling fan is connected to the motherboard, and wherein the cooling fan is disposed on one side of the first cooling member.
  8. 8. The router of claim 7, wherein the first heat sink is provided with heat sink fins, an air duct is formed between two adjacent heat sink fins, and an air outlet side of the heat sink fan is disposed toward the air duct.
  9. 9. The router of claim 1, further comprising an antenna, wherein the antenna comprises a rotating shaft, the housing is provided with a shaft hole, the rotating shaft is rotatably connected with the shaft hole, the antenna is provided with an antenna limiting block positioned on one side of the rotating shaft, the housing is provided with a starting limiting block, a middle damping block and a stopping limiting block which are arranged around the shaft hole at intervals, the starting limiting block and the stopping limiting block form a rotation limiting block for the antenna limiting block, and when the antenna limiting block rotates to the middle damping block, the antenna limiting block is contacted with the middle damping block and can slide over the middle damping block.
  10. 10. The router of claim 1, wherein the router is configured to, the router also comprises a display screen, and the display screen is arranged on the shell.

Description

Router Technical Field The utility model relates to the technical field of routers, in particular to a router. Background When the current router device operates under high load for a long time, the problem of insufficient heat dissipation efficiency is generally faced. The traditional heat dissipation scheme is mostly dependent on a passive heat dissipation structure (such as a heat dissipation fin), and can cope with the conventional use scene, but under the intensive data processing or high-temperature environment, the temperature of a chip is easy to quickly rise, so that performance is attenuated and even hardware is damaged. Furthermore, there are significant limitations to the antenna tuning design of existing routers. The antenna angle adjustment of most products depends on manual rotation of users, lacks accurate limit and tactile feedback, leads to the signal coverage direction to be difficult to quickly position, and frequently adjusts and easily causes the structure to become flexible. When the antenna is switched between different gears, the antenna has no explicit physical identification, and lacks operation feedback (such as sound or hand feeling), so that the user experience is poor, and especially in a scene needing multi-angle flexible deployment, the prior art is difficult to meet the dual requirements of convenience and stability. In the user interaction level, the traditional router relies on external equipment (such as a mobile phone and a computer) to perform network configuration, and an account number and a password are required to be manually input, so that the operation is complex and the router is not friendly to non-professional users. Meanwhile, equipment state information (such as connection rate and terminal number) is usually checked through special software, and the lack of localized visual display limits the real-time control of the network state by a user. There is a need to develop a new router. Disclosure of utility model The technical problem to be solved by the embodiment of the utility model is at least one of the problems mentioned in the background art, and a router is provided. In order to solve the above problems, the embodiments of the present utility model provide the following technical solutions: The router comprises a shell, a main board, a first heat conduction assembly, a second heat conduction assembly, a first heat dissipation piece and a second heat dissipation piece, wherein the main board, the first heat conduction assembly, the second heat conduction assembly, the first heat dissipation piece and the second heat dissipation piece are arranged in the shell, the first heat dissipation piece and the second heat dissipation piece are respectively arranged on two sides of the main board, the first heat conduction assembly is arranged between the first heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the first heat dissipation piece, and the second heat conduction assembly is arranged between the second heat dissipation piece and the main board and is used for transmitting heat generated by the main board to the second heat dissipation piece. The technical scheme is that the novel main board further comprises a first shielding cover and a second shielding cover, wherein the first shielding cover and the second shielding cover are respectively covered on two sides of the main board. The first heat conduction assembly comprises a first heat conduction gasket and a second heat conduction gasket, wherein the first heat conduction gasket is arranged between the main board and the first shielding cover and is respectively contacted with the main board and the first shielding cover, and the second heat conduction gasket is arranged between the first shielding cover and the first heat dissipation piece and is respectively contacted with the first shielding cover and the first heat dissipation piece. The second heat conduction assembly comprises a third heat conduction gasket and a fourth heat conduction gasket, wherein the third heat conduction gasket is arranged between the main board and the second shielding cover and is respectively contacted with the main board and the second shielding cover, and the fourth heat conduction gasket is arranged between the second shielding cover and the second heat dissipation piece and is respectively contacted with the second shielding cover and the second heat dissipation piece. The heat conducting device comprises a first heat conducting gasket, a second heat conducting gasket, a third heat conducting gasket, a fourth heat conducting gasket, a third heat conducting gasket and a fourth heat conducting gasket, wherein the first heat conducting gasket and the second heat conducting gasket are at least partially overlapped on the first shielding cover in projection. The main board comprises a heating device, and the first heat conduction gasket and/or the third heat conduc