CN210202344U

CN210202344U - Radiator for communication equipment

Info

Publication number: CN210202344U
Application number: CN201921145681.5U
Authority: CN
Inventors: Xiaofei Tong; 童小飞; Jiazhong Hong; 洪家中
Original assignee: Kunshan Cheng Yuan Precision Electronics Corp Ltd
Current assignee: Kunshan Cheng Yuan Precision Electronics Corp Ltd
Priority date: 2019-07-22
Filing date: 2019-07-22
Publication date: 2020-03-27
Anticipated expiration: 2029-07-22

Abstract

The utility model discloses a radiator for communications facilities, including base member and a plurality of formation in the fin in the outside of base member, it is a plurality of the equidistant parallel distribution of fin, the fin is narrow platykurtic fin down in the width, the outside of fin is with the heat conduction strip, the heat conduction strip by the lower extreme of fin extends to the upper end of fin, the height of heat conduction strip equals the height of fin. The utility model discloses can dispel the heat fast electronic communication equipment, prevent to influence the use because of generating heat seriously, improve communication equipment's life.

Description

Radiator for communication equipment

Technical Field

The utility model belongs to the technical field of the cooling device, especially, relate to a radiator for communications facilities.

Background

With the rapid development of the communication industry, a 5G communication technology base station needs a rapid heat dissipation component to support equipment operation urgently to ensure smooth communication signals.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the main technical problem who solves provides a radiator for communications facilities, can dispel the heat fast to electronic communications facilities, prevents to influence the use because of generating heat seriously, improves communications facilities's life.

In order to solve the technical problem, the utility model discloses a technical scheme be: a radiator for communication equipment comprises a base body and a plurality of radiating fins formed on the outer side of the base body, wherein the radiating fins are distributed in parallel at equal intervals, the radiating fins are flat radiating fins with wide lower parts and narrow upper parts, heat conducting strips are attached to the outer parts of the radiating fins, the heat conducting strips extend from the lower ends of the radiating fins to the upper ends of the radiating fins, and the height of each heat conducting strip is equal to that of each radiating fin;

each radiating fin forms an included angle with the horizontal line;

the distance between the adjacent radiating fins is 7-8 mm;

the width of the lower end of the radiating fin is 23-24mm, the width of the upper end of the radiating fin is 9-10mm, and the height of the radiating fin is 257-258 mm;

the width of the lower end of the heat conducting strip is 33-34, the width of the upper end of the heat conducting strip is 17-19mm, the length of the lower end of the heat conducting strip is 164-165mm, the length of the upper end of the heat conducting strip is 124-125mm, and the height of the heat conducting strip is 257-258 mm;

the heat-absorbing coating is adhered to the inner side of the base body, and a plurality of heat-radiating salient points are arranged on the outer side of the base body and between the adjacent heat-radiating fins.

The utility model discloses a solve the further technical scheme that its technical problem adopted and be:

further, the distance between the adjacent radiating fins is 7.81 mm.

Further, the angle of the included angle is 45 °.

Further, the width of the lower end of the radiating fin is 23.97mm, the width of the upper end of the radiating fin is 9.26mm, and the height of the radiating fin is 257.96 mm.

Further, the width of the lower end of the heat conduction strip is 33.3mm, the width of the upper end of the heat conduction strip is 18mm, the length of the lower end of the heat conduction strip is 164.59mm, the length of the upper end of the heat conduction strip is 124.8mm, and the height of the heat conduction strip is 257.96 mm.

Further, the upper end of the heat sink is rounded.

Further, the heat conducting bars are made of copper powder.

Furthermore, the base body and the radiating fins are both formed by aluminum alloy extrusion casting.

Further, the heat dissipation bump is a graphene bump.

Further, the heat conducting strips are distributed on the heat radiating fin at intervals.

The beneficial effects of the utility model are that following several points have at least:

1. the radiating fins on the radiator of the utility model are distributed in parallel at equal intervals, the heat conducting strips are attached to the outer parts of the radiating fins, the heat absorbing coating is pasted on the inner side of the base body, a plurality of radiating salient points are arranged on the outer side of the base body and between the adjacent radiating fins, the structural design can lead the heat generated by the communication equipment to the radiating fins in time, the heat is radiated quickly and efficiently, and the radiating effect of the communication equipment is improved;

2. the included angle is formed between the radiating fins and the horizontal line, the radiating fins are flat radiating fins with wide lower parts and narrow upper parts, the radiating fins have novel structures and less material consumption, and the effects of saving energy, reducing consumption and reducing cost are achieved;

3. the utility model discloses wholly have good moulding and processing property, have good casting performance.

Drawings

Fig. 1 is a schematic perspective view of the present invention;

fig. 2 is a top view of the present invention;

FIG. 3 is an enlarged view of portion B of FIG. 2;

fig. 4 is a side view of the present invention;

FIG. 5 is one of enlarged views of portion A of FIG. 4;

FIG. 6 is a second enlarged view of the portion A of FIG. 4;

the parts in the drawings are marked as follows:

the heat radiating fin comprises a base body 1, heat radiating fins 2, heat conducting strips 3, an included angle α, a distance d1 between adjacent heat radiating fins, a lower end width w1 of the heat radiating fins, an upper end width w2 of the heat radiating fins, a height h1 of the heat radiating fins, a lower end width w3 of the heat conducting strips, an upper end width w4 of the heat conducting strips, a lower end length d2 of the heat conducting strips, an upper end length d3 of the heat conducting strips and a height h2 of the heat conducting strips.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so as to enable those skilled in the art to more easily understand the advantages and features of the present invention, and thereby define the scope of the invention more clearly and clearly.

Example (b): a radiator for communication equipment is disclosed, as shown in fig. 1-6, and comprises a base body 1 and a plurality of radiating fins 2 formed on the outer side of the base body, wherein the plurality of radiating fins are distributed in parallel at equal intervals, the radiating fins are flat radiating fins with wide lower parts and narrow upper parts, heat conducting strips 3 are attached to the outer parts of the radiating fins, the heat conducting strips extend from the lower ends of the radiating fins to the upper ends of the radiating fins, and the height of the heat conducting strips is equal to that of the radiating fins;

each radiating fin forms an included angle α with the horizontal line;

the distance d1 between the adjacent radiating fins is 7-8 mm;

the width w1 of the lower end of the cooling fin is 23-24mm, the width w2 of the upper end of the cooling fin is 9-10mm, and the height h1 of the cooling fin is 257-258 mm;

the width w3 of the lower end of the heat conducting strip is 33-34, the width w4 of the upper end of the heat conducting strip is 17-19mm, the length d2 of the lower end of the heat conducting strip is 164-165mm, the length d3 of the upper end of the heat conducting strip is 124-125mm, and the height h2 of the heat conducting strip is 257-258 mm;

The distance between adjacent radiating fins is 7.81 mm.

The angle of the included angle is 45 degrees.

The width of the lower end of each radiating fin is 23.97mm, the width of the upper end of each radiating fin is 9.26mm, and the height of each radiating fin is 257.96 mm.

The lower extreme width of heat conduction strip is 33.3mm, the upper end width of heat conduction strip is 18mm, the lower extreme length of heat conduction strip is 164.59mm, the upper end length of heat conduction strip is 124.8mm, the height of heat conduction strip is 257.96 mm.

The upper end of the radiating fin is processed by rounding.

The heat conducting strips are made of copper powder.

The base body and the radiating fins are both formed by aluminum alloy extrusion casting.

The heat dissipation salient points are graphene salient points.

The heat conducting strips are distributed on the heat radiating fin at intervals.

The working principle of the utility model is as follows:

the radiating fins on the radiator of the utility model are distributed in parallel at equal intervals, the heat conducting strips are attached to the outer parts of the radiating fins, the heat absorbing coating is pasted on the inner side of the base body, a plurality of radiating salient points are arranged on the outer side of the base body and between the adjacent radiating fins, the structural design can lead the heat generated by the communication equipment to the radiating fins in time, the heat is radiated quickly and efficiently, and the radiating effect of the communication equipment is improved; the radiating fins and the horizontal line form an included angle, the radiating fins are flat radiating fins with wide lower parts and narrow upper parts, the radiating fins are novel in structure, the material consumption is low, and the effects of saving energy, reducing consumption and reducing cost are achieved.

The above only is the embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structure changes made in the specification and the attached drawings or directly or indirectly applied to other related technical fields are included in the same principle as the present invention.

Claims

1. A radiator for communication equipment is characterized in that: the radiating fin structure comprises a base body (1) and a plurality of radiating fins (2) formed on the outer side of the base body, wherein the radiating fins are distributed in parallel at equal intervals, each radiating fin is a flat radiating fin with a wide lower part and a narrow upper part, a heat conducting strip (3) is attached to the outer part of each radiating fin, each heat conducting strip extends from the lower end of each radiating fin to the upper end of each radiating fin, and the height of each heat conducting strip is equal to that of each radiating fin;

each of the fins forms an included angle (α) with a horizontal line;

the distance (d1) between the adjacent radiating fins is 7-8 mm;

the width (w1) of the lower end of the cooling fin is 23-24mm, the width (w2) of the upper end of the cooling fin is 9-10mm, and the height (h1) of the cooling fin is 257-258 mm;

the width (w3) of the lower end of the heat conducting strip is 33-34, the width (w4) of the upper end of the heat conducting strip is 17-19mm, the length (d2) of the lower end of the heat conducting strip is 164-165mm, the length (d3) of the upper end of the heat conducting strip is 124-125mm, and the height (h2) of the heat conducting strip is 257-258 mm;

2. The heat sink for communication equipment according to claim 1, wherein: the distance between adjacent radiating fins is 7.81 mm.

3. The heat sink for communication equipment according to claim 1, wherein: the angle of the included angle is 45 degrees.

4. The heat sink for communication equipment according to claim 1, wherein: the width of the lower end of each radiating fin is 23.97mm, the width of the upper end of each radiating fin is 9.26mm, and the height of each radiating fin is 257.96 mm.

5. The heat sink for communication equipment according to claim 1, wherein: the lower extreme width of heat conduction strip is 33.3mm, the upper end width of heat conduction strip is 18mm, the lower extreme length of heat conduction strip is 164.59mm, the upper end length of heat conduction strip is 124.8mm, the height of heat conduction strip is 257.96 mm.

6. The heat sink for communication equipment according to claim 1, wherein: the upper end of the radiating fin is processed by rounding.

7. The heat sink for communication equipment according to claim 1, wherein: the heat conducting strips are made of copper powder.

8. The heat sink for communication equipment according to claim 1, wherein: the base body and the radiating fins are both formed by aluminum alloy extrusion casting.

9. The heat sink for communication equipment according to claim 1, wherein: the heat dissipation salient points are graphene salient points.

10. The heat sink for communication equipment according to claim 1, wherein: the heat conducting strips are distributed on the heat radiating fin at intervals.