CN216721909U - Staggered type radiating fin structure - Google Patents

Abstract

The utility model provides a staggered radiating fin structure, relates to the technical field of radiating fins, and aims to solve the problems that the existing radiating fin structure is not flexible enough in use, inconvenient to transport, incapable of freely adjusting the expansion value of a radiating fin, inefficient in radiating and poor in adaptability; a row of telescopic heat dissipation parts are fixedly connected to the mounting heat absorption plate; the installation heat absorption plate is connected with a movable opposite insertion part in a sliding way; the bottom of the movable opposite-inserting part is provided with a self-locking driving part; the inside difference fixedly connected with setting element of one row of flexible radiating part sets up the installation absorber plate, the flexible radiating part that the cooperation set up can effectively accelerate heat absorption efficiency, can practice thrift the equipment volume more, the transportation of being convenient for, the heat dispersion of being convenient for of absorbed heat that can be better, can freely adjust and lock heat radiating area, the staff of being convenient for more of the flexible radiating part of setting can adjust according to the in-service use scene, use more in a flexible way.

Description

Staggered type radiating fin structure

Technical Field

The utility model belongs to the technical field of radiating fins, and particularly relates to a staggered radiating fin structure.

Background

The heat dissipation is widely applied to a plurality of fields, the heat dissipation efficiency of equipment or components can be effectively improved, and a flexible and good heat dissipation plate structure is particularly important in the heat dissipation process of actual equipment; the existing radiating fin structure is not flexible enough in use, can not realize dislocation telescopic installation, is inconvenient to transport, is poor in installation adaptability, is poor in overall heat absorption effect, can not realize freely adjusting the telescopic value of the radiating fin, is not efficient enough in heat dissipation, is inconvenient to use for different installation scenes, and is poor in adaptability.

Therefore, in view of the above, research and improvement are made on the existing structure and defects, and a staggered heat sink structure is provided to achieve the purpose of higher practical value.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides a staggered radiating fin structure to solve the problems that the existing radiating fin structure is not flexible enough in use, inconvenient to transport, incapable of freely adjusting the expansion value of the radiating fin, inefficient in radiating and poor in adaptability.

The purpose and the effect of the staggered radiating fin structure are achieved by the following specific technical means:

a staggered heat sink structure comprises an installation heat absorption plate; a row of telescopic heat dissipation parts are fixedly connected to the mounting heat absorption plate; the installation heat absorption plate is connected with a movable opposite insertion part in a sliding way; the bottom of the movable opposite-inserting part is provided with a self-locking driving part; positioning pieces are respectively and fixedly connected inside the row of telescopic radiating parts; the mounting absorber plate includes: the mounting support plate is provided with a row of heat conducting slotted holes; two mounting foot plates are arranged and are fixedly connected to two sides of the bottom of the mounting support plate respectively; the telescopic heat dissipation part includes: the fixed heat dissipation plate is fixedly connected to the mounting support plate; the fixed heat dissipation plate is of a hollow structure; a row of positioning holes are formed in the fixed heat dissipation plate; the side surface of the fixed heat dissipation plate is provided with a through slot; the sliding heat dissipation plate is sleeved inside the fixed heat dissipation plate; the inside of the sliding heat dissipation plate is of a hollow structure.

Further, the positioning member includes: the positioning cylinder is fixedly connected inside the sliding heat dissipation plate; the positioning pin is inserted on the positioning cylinder in a sliding manner; the front end of the positioning pin is of an arc structure; the positioning pins are aligned with a row of positioning holes formed in the fixed heat dissipation plate; the positioning spring is sleeved in the positioning cylinder; the positioning spring is fixedly connected with the tail part of the positioning pin.

Further, the mounting heat absorbing plate further comprises: the heat absorption copper blocks are arranged in a row, and the row of heat absorption copper blocks are respectively and fixedly connected to the bottom of the mounting support plate; the row of mounting support plates are respectively positioned between the row of heat conducting slotted holes.

Further, the self-locking driving part includes: the thread moving frame is fixedly connected to the bottom of the sliding opposite-inserting frame; the front end of the thread moving frame is provided with a threaded hole; the driving screw rod is rotationally connected to the bottom of the mounting support plate; the driving screw rod is in threaded connection with a thread moving frame.

Further, the telescopic heat dissipation part further includes: two fixed sliding strips are arranged and are respectively and fixedly connected to two sides of the sliding heat dissipation plate; the two fixed sliding strips are respectively connected to the fixed heat dissipation plate in a sliding manner; the lifting handle is fixedly connected to the sliding heat dissipation plate; the lifting handle penetrates through the fixed heat dissipation plate.

Further, the mobile docking station includes: the bottom of the sliding opposite-inserting frame is provided with a row of sliding strips, and the row of sliding strips are respectively connected to the mounting support plate in a sliding manner; two stabilizing shafts are arranged and are respectively and fixedly connected to the sliding opposite insertion frame; the two stabilizing shafts are respectively connected on the mounting support plate in a sliding manner; the moving plates are arranged in a row, and the moving plates in the row are respectively and fixedly connected to the sliding opposite-inserting frames; the row of moving plates are all of a hollow structure; radiating water is arranged inside the row of moving plates; a row of moving plates is arranged between the gaps of the row of fixed radiating plates.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model can effectively accelerate the heat absorption efficiency by arranging the heat absorption plate and the telescopic heat dissipation part which is matched with the heat absorption plate, simultaneously the telescopic heat dissipation part can be more convenient for workers to adjust the telescopic value of the sliding heat dissipation plate according to the actual use scene, the adaptability is stronger, the heat dissipation efficiency is enhanced, the arranged positioning piece can be positioned by the positioning pin and clamped into the fixed heat dissipation plate for positioning in real time under the extrusion of the positioning spring, the structure is simple and efficient, the practicability can be effectively improved, the utility model is more suitable for different equipment installation environments, the integral use is more convenient, the arranged fixed heat dissipation plate and the sliding heat dissipation plate adopt the hollow structural design, the better heat dissipation effect can be achieved, only the lifting handle is needed to be stirred when the sliding heat dissipation plate is adjusted, the volume is smaller, and the normal heat dissipation work can not be influenced, the sliding heat dissipation plate capable of independently sliding in a staggered mode is more practical, stronger in adaptability and more efficient in heat dissipation.

2. The utility model can effectively improve the flexibility of the structure by arranging the self-locking driving part which is matched with the movable opposite-inserting part, can be more conveniently and freely adjusted according to the heat dissipation area required by equipment, is more practical, simultaneously, the arranged row of movable plates adopts a hollow irrigation mode, can better absorb heat to be convenient for heat dispersion, can be freely adjusted and locked the heat dissipation area, is more simple in practical use, can drive the screw thread moving frame to move by rotating the driving screw rod, in the process, the screw thread moving frame can drive the movable opposite-inserting part to integrally slide, in the sliding process, the row of movable plates can be inserted between the intervals of the row of fixed heat dissipation plates to assist the heat dissipation of the fixed heat dissipation plates, and simultaneously, the cross extension mode is adopted, the equipment volume can be more saved, the transportation is convenient, the structure is ingenious, and the structure is more practical, the cost of the device for individually customizing the radiating fins is reduced.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the internal structure of the present invention.

Fig. 3 is a schematic bottom structure of the present invention.

Fig. 4 is a schematic view of the structure of the telescopic heat dissipating unit of the present invention.

Fig. 5 is a schematic view of the positioning member of the present invention.

Fig. 6 is a schematic structural diagram of the mobile plug-in unit of the present invention.

Fig. 7 is a schematic structural view of the self-locking driving portion of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. mounting a heat absorbing plate;

101. mounting a support plate; 1011. a heat-conducting slot; 102. mounting a foot plate; 103. a heat absorbing copper block;

2. a telescopic heat dissipation part;

201. a fixed heat dissipation plate; 202. a sliding heat dissipation plate; 203. fixing a slide bar; 204. lifting the handle;

3. moving the opposite insertion part;

301. sliding opposite insertion frames; 302. a stabilizing shaft; 303. moving the plate;

4. a self-locking driving part;

401. a screw thread moving frame; 402. driving the screw rod;

5. a positioning member;

501. a positioning cylinder; 502. positioning pins; 503. and positioning the spring.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the utility model but are not intended to limit the scope of the utility model.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 7:

the utility model provides a staggered radiating fin structure, which comprises an installation heat absorption plate 1; a row of telescopic heat dissipation parts 2 are fixedly connected to the mounting heat absorption plate 1; the installation heat absorption plate 1 is connected with a movable inserting part 3 in a sliding way; the bottom of the movable inserting part 3 is provided with a self-locking driving part 4; the insides of the row of telescopic heat dissipation parts 2 are respectively and fixedly connected with positioning pieces 5; the installation absorber plate 1 comprises: a row of heat conducting slotted holes 1011 are formed in the mounting support plate 101; two mounting foot plates 102 are arranged, and the two mounting foot plates 102 are respectively and fixedly connected to two sides of the bottom of the mounting support plate 101; the telescopic heat dissipation portion 2 includes: a fixed heat dissipation plate 201, wherein the fixed heat dissipation plate 201 is fixedly connected to the installation support plate 101; the fixed heat dissipation plate 201 is a hollow structure; a row of positioning holes are formed in the fixed heat dissipation plate 201; a through slot is arranged on the side surface of the fixed heat dissipation plate 201; a sliding heat dissipation plate 202, wherein the sliding heat dissipation plate 202 is sleeved inside the fixed heat dissipation plate 201; the interior of the sliding heat dissipation plate 202 is hollow.

As shown in fig. 3 to 5, the installation absorber plate 1 further includes: the heat absorption copper blocks 103 are arranged in a row, and the heat absorption copper blocks 103 are fixedly connected to the bottoms of the mounting support plates 101 respectively; the row of mounting support plates 101 are respectively positioned between the row of heat conducting slotted holes 1011; the telescopic heat dissipation portion 2 further includes: two fixed sliding strips 203 are arranged, and the two fixed sliding strips 203 are respectively and fixedly connected to two sides of the sliding heat dissipation plate 202; the two fixed sliding bars 203 are respectively connected on the fixed heat dissipation plate 201 in a sliding manner; a lifting handle 204, wherein the lifting handle 204 is fixedly connected to the sliding heat dissipation plate 202; the lifting handle 204 passes through the fixed heat dissipation plate 201; the positioning member 5 includes: a positioning cylinder 501, wherein the positioning cylinder 501 is fixedly connected inside the sliding heat dissipation plate 202; the positioning pin 502 is inserted on the positioning cylinder 501 in a sliding manner; the front end of the positioning pin 502 is of an arc-shaped structure; the positioning pins 502 are aligned with a row of positioning holes formed in the fixed heat dissipation plate 201; the positioning spring 503 is sleeved inside the positioning cylinder 501, and the positioning spring 503 is sleeved inside the positioning cylinder 501; the positioning spring 503 is fixedly connected to the tail of the positioning pin 502; the heat absorption efficiency can be effectively accelerated by arranging the heat absorption plate 1 and the telescopic heat dissipation part 2 which is arranged in a matched manner, the telescopic heat dissipation part 2 can be more convenient for workers to adjust the telescopic value of the sliding heat dissipation plate 202 according to actual use scenes, the adaptability is stronger, the heat dissipation efficiency is enhanced, the arranged positioning piece 5 can be positioned by the positioning pin 502, and the positioning piece is clamped into the fixed heat dissipation plate 201 in real time for positioning under the extrusion of the positioning spring 503, so that the structure is simple and efficient, the practicability can be effectively improved, the sliding heat dissipation plate is more suitable for different equipment installation environments, the whole use is more convenient, the arranged fixed heat dissipation plate 201 and the sliding heat dissipation plate 202 adopt a hollow structural design, the better heat dissipation effect can be achieved, the sliding heat dissipation plate 202 can be adjusted only by pulling the lifting handle 204, the volume is smaller, and the normal heat dissipation work cannot be influenced, the sliding heat dissipation plate 202 capable of sliding independently and staggeredly is adopted, so that the heat dissipation device is more practical, stronger in adaptability and more efficient in heat dissipation.

As shown in fig. 6 and 7, the mobile mating part 3 includes: the bottom of the sliding opposite-inserting frame 301 is provided with a row of sliding strips, and the row of sliding strips are respectively connected to the mounting support plate 101 in a sliding manner; two stabilizing shafts 302 are arranged, and the two stabilizing shafts 302 are respectively and fixedly connected to the sliding opposite insertion frame 301; the two stabilizing shafts 302 are respectively connected on the mounting support plate 101 in a sliding manner; a row of moving plates 303 is arranged, and the row of moving plates 303 are respectively and fixedly connected to the sliding opposite-inserting frame 301; the row of moving plates 303 are all of a hollow structure; a row of moving plates 303 are positioned between the gaps of the row of fixed radiating plates 201; the self-lock drive portion 4 includes: the thread moving frame 401 is fixedly connected to the bottom of the sliding opposite-inserting frame 301; the front end of the thread moving frame 401 is provided with a threaded hole; the driving screw rod 402 is rotatably connected to the bottom of the mounting support plate 101; a thread moving frame 401 is connected to the driving screw rod 402 in a threaded manner; the self-locking driving part 4 which is matched with the moving opposite insertion part 3 is arranged, so that the flexibility of the structure can be effectively improved, the heat dissipation area can be more conveniently and freely adjusted according to the equipment requirement, the structure is more practical, the one row of moving plates 303 which are arranged at the same time adopt a hollow water filling mode, the heat can be better absorbed, the heat can be conveniently dispersed, the heat dissipation area can be freely adjusted and locked, the structure is more simple and practical, the screw thread moving frame 401 can be driven to move by the driving screw rod 402 through rotating the driving screw rod 402, in the process, the screw thread moving frame 401 can drive the moving opposite insertion part 3 to integrally slide, in the sliding process, the one row of moving plates 303 can be inserted between the intervals of the one row of fixed heat dissipation plates 201, so that the heat dissipation of the fixed heat dissipation plates 201 can be assisted, meanwhile, the cross telescopic mode is adopted, the equipment volume can be more saved, the transportation is convenient, and the structure is ingenious, more practical, reduce the independent customization fin cost of equipment.

The specific use mode and function of the embodiment are as follows:

in the utility model, the structure is firstly installed on equipment needing heat dissipation through the installation foot plate 102, then the equipment can be put into use, the driving screw rod 402 is rotated, at the moment, the driving screw rod 402 can drive the thread moving frame 401 to move, in the process, the thread moving frame 401 can drive the moving opposite insertion part 3 to integrally slide, in the sliding process, a row of moving plates 303 can be inserted between the intervals of a row of fixed heat dissipation plates 201 to assist the fixed heat dissipation plates 201 in heat dissipation, and meanwhile, the self can be flexibly adjusted according to the equipment, only a lifting handle 204 needs to be pulled when the sliding heat dissipation plates 202 are adjusted, in the process, the positioning piece 5 can be positioned through the positioning pin 502, and can be clamped into the fixed heat dissipation plates 201 for positioning in real time under the extrusion of the positioning spring 503, the adjustment stability is improved, when the equipment is used, a row of heat absorption copper blocks 103 can assist in heat conduction, and the heat dissipation efficiency is accelerated, and finally finishing the use process of the staggered radiating fin structure.

The utility model is not described in detail, but is well known to those skilled in the art.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. The utility model provides a dislocation type fin structure which characterized in that: comprises a mounting absorber plate (1); a row of telescopic heat dissipation parts (2) are fixedly connected to the mounting heat absorption plate (1); the installation heat absorption plate (1) is connected with a movable inserting part (3) in a sliding way; the bottom of the movable opposite-inserting part (3) is provided with a self-locking driving part (4); positioning pieces (5) are respectively and fixedly connected inside the row of telescopic heat dissipation parts (2); the mounting absorber plate (1) comprises: the mounting support plate (101), wherein a row of heat conducting slotted holes (1011) are formed in the mounting support plate (101); two mounting foot plates (102) are arranged, and the two mounting foot plates (102) are respectively and fixedly connected to two sides of the bottom of the mounting support plate (101); the telescopic heat dissipation part (2) comprises: the fixed heat dissipation plate (201), the fixed heat dissipation plate (201) is fixedly connected to the installation support plate (101); the fixed heat dissipation plate (201) is of a hollow structure; a row of positioning holes are formed in the fixed heat dissipation plate (201); a through slot is arranged on the side surface of the fixed heat dissipation plate (201); the sliding heat dissipation plate (202), the sliding heat dissipation plate (202) is sleeved inside the fixed heat dissipation plate (201); the interior of the sliding heat dissipation plate (202) is of a hollow structure.

2. The cascade fin structure of claim 1, wherein: the mounting absorber plate (1) further comprises: the heat absorption copper blocks (103) are arranged in a row, and the heat absorption copper blocks (103) in the row are respectively and fixedly connected to the bottom of the mounting support plate (101); the row of mounting support plates (101) are respectively positioned between the row of heat conducting slotted holes (1011).

3. The cascade fin structure of claim 1, wherein: the telescopic heat dissipation part (2) further comprises: two fixed sliding strips (203), wherein the two fixed sliding strips (203) are respectively fixedly connected to two sides of the sliding heat dissipation plate (202); the two fixed sliding strips (203) are respectively connected on the fixed heat dissipation plate (201) in a sliding manner; a lifting handle (204), wherein the lifting handle (204) is fixedly connected to the sliding heat dissipation plate (202); the lifting handle (204) penetrates through the fixed heat dissipation plate (201).

4. The cascade fin structure of claim 1, wherein: the mobile docking portion (3) includes: the bottom of the sliding opposite-inserting frame (301) is provided with a row of sliding strips, and the row of sliding strips are respectively connected to the mounting support plate (101) in a sliding manner; two stabilizing shafts (302) are arranged, and the two stabilizing shafts (302) are respectively and fixedly connected to the sliding opposite insertion frame (301); the two stabilizing shafts (302) are respectively connected on the mounting support plate (101) in a sliding way; the moving plates (303), the moving plates (303) are arranged in a row, and the moving plates (303) in the row are respectively and fixedly connected to the sliding opposite-inserting frames (301); the row of moving plates (303) are all of a hollow structure.

5. The cascade fin structure of claim 4, wherein: the self-locking driving part (4) comprises: the thread moving frame (401), the thread moving frame (401) is fixedly connected to the bottom of the sliding opposite-inserting frame (301); the front end of the thread moving frame (401) is provided with a threaded hole; the driving screw rod (402), the driving screw rod (402) is rotatably connected to the bottom of the mounting support plate (101); the driving screw rod (402) is connected with a thread moving frame (401) in a threaded manner.

6. A shiftdown fin structure according to claim 1, wherein: the positioning member (5) comprises: the positioning cylinder (501), the positioning cylinder (501) is fixedly connected inside the sliding heat dissipation plate (202); the positioning pin (502), the positioning pin (502) is inserted on the positioning cylinder (501) in a sliding manner; the front end of the positioning pin (502) is of an arc structure; the positioning pins (502) are aligned with a row of positioning holes formed in the fixed heat dissipation plate (201); the positioning spring (503), the positioning spring (503) is nested inside the positioning cylinder (501); the positioning spring (503) is fixedly connected to the tail of the positioning pin (502).

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