CN110662401B - Distance adjustable type's inside and outside double-deck high-efficient radiator between radiating fin - Google Patents

Abstract

The inner and outer double-layer efficient radiator comprises a fixture base, a fixture sleeve and a fixture rotating part, and comprises an inner-layer radiating fin mounting plate, an outer-layer radiating fin mounting plate, a group of first radiating fins and a group of second radiating fins with adjustable intervals, wherein a group of first radiating fins are arranged between the inner-layer radiating fin mounting plate and the outer-layer radiating fin mounting plate, and the second radiating fins with adjustable intervals are arranged on the outer wall of the outer-layer radiating fin mounting plate. The inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins is provided with the inner and outer double-layer radiating fins I and the radiating fins II, the distance between the radiating fins II can be flexibly adjusted according to the heat productivity of a heating body, and the distance between the radiating fins can be flexibly adjusted through the radiating fin interval adjusting device, so that the radiator is higher in applicability, greatly improved in cooling performance, safe and reliable to use, greatly improved in radiating efficiency and high in popularization value.

Description

Distance adjustable type's inside and outside double-deck high-efficient radiator between radiating fin

Technical Field

The invention belongs to the technical field of radiators, and particularly relates to an inner and outer double-layer efficient radiator with adjustable distance between radiating fins.

Background

The heat sink is used to prevent the device from overheating and to conduct heat generated by the electrical or electronic components connected to the heat sink to the air. The larger the surface area of the heat sink in contact with the air, the greater the amount of heat transferred to the air and thus the better the cooling effect of the device. Other factors that affect the heat dissipation efficiency of a heat sink are the flow rate of air, the design structure, the materials used, the surface treatment performed, the manner in which the electrical or electronic device is connected to the heat sink, and so forth.

One of the most common design features in the manufacture of heat sinks is the placement of fins around an axis. Heat sinks of this type typically have a central body for absorbing heat dissipated by one or more electrical or electronic components, and a plurality of fins extending from the body and radially distributed about an axis to dissipate the heat absorbed by the body into the air. To enhance the heat absorption of the core and the heat transfer to the fins, materials with high thermal conductivity are often used, such as aluminum or copper, among others.

These heat sinks usually have geometrically uniform fins distributed around the central body in given positions equal to each other. To facilitate the fabrication of the heat sink using an extrusion process, the heat sink must have a fixed cross-section along the extrusion axis. For this reason, the walls constituting the fins are arranged parallel to each other, and there is no inclination between any adjacent fins. In other words, all the fins are parallel to each other along the extrusion axis, the air flow channels defined between the fins having a constant cross section. Generally, the extrusion process requires large machinery and high maintenance costs, which can be slow when high impact forces are required to pass the material through the die, leave impurities and defects on the surface of the extruded material, and severely limit the geometry of the component since it must have a constant cross-section along the extrusion axis. On the other hand, manufacturing processes using injection molding are more flexible in terms of the variety of shapes and geometries that can be obtained, and they are generally faster to produce, less costly, and generally more finished in the surface finish of the resulting component.

However, in all the existing heat sinks, the heat dissipation fins and the base body are connected together, so that the heat dissipation performance of the heat sink is determined, and the heat dissipation performance cannot be flexibly adjusted according to the heat productivity of the heat generating equipment.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to provide an inner and outer double-layer efficient radiator with adjustable distance between radiating fins, which solves the problem that the radiating fins are fixed and cannot be flexibly adjusted according to the heat productivity in the radiator with the traditional structure.

The technical scheme is as follows: the invention provides an inner and outer double-layer efficient radiator with adjustable distance between radiating fins, which comprises an inner radiating fin mounting plate, an outer radiating fin mounting plate, a group of first radiating fins and a group of second radiating fin assemblies with adjustable distance.

Further, in the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins, the second radiating fin assembly with the adjustable distance comprises a second radiating fin distance adjusting device and a second group of radiating fins, the second group of radiating fins are connected through the second radiating fin distance adjusting device, and the distance between the adjacent second radiating fins can be adjusted through the second radiating fin distance adjusting device.

Furthermore, the distance adjustable type inner and outer double-layer efficient radiator between the radiating fins is characterized in that a radiating fin sliding groove is formed in the outer wall of the multi-surface of the outer radiating fin mounting plate, the second radiating fin is in a rectangular flat plate shape with a convex cross section, extending parts are arranged on two opposite side edges of the lower end part of the second radiating fin, the extending parts are arranged in the radiating fin sliding groove, and the extending parts can slide in the radiating fin sliding groove.

Furthermore, the distance adjustable type inner and outer double-layer efficient radiator comprises a push rod, a first locking bolt, a second locking bolt, a first linear optical axis, a second linear optical axis, a group of upper distance adjusting blocks, a group of lower distance adjusting blocks and a mounting substrate, wherein the mounting substrate is fixedly arranged on the outer wall of the outer-layer radiating fin mounting plate, the lower end parts of the group of second radiating fins are sleeved on the first linear optical axis and the second linear optical axis, the push rod is arranged on the mounting substrate, the two ends of the push rod extend out of the mounting substrate, one end of the push rod is fixedly connected with the end surface of the second radiating fin close to the mounting substrate in the group of second radiating fins, the first locking bolt and the second locking bolt are in threaded connection with the push rod, the first locking bolt and the second locking bolt are respectively positioned on two sides of the mounting substrate, and the second radiating fins are connected with the group of lower distance adjusting blocks through the group of upper distance adjusting blocks, and the upper spacing adjusting blocks and the lower spacing adjusting blocks are arranged at intervals, and the adjacent upper spacing adjusting blocks and the lower spacing adjusting blocks are lapped.

Further, the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins comprises a group of upper radiating fins and a group of lower radiating fins, wherein the group of upper radiating fins and the group of lower radiating fins are arranged at intervals, the height of the upper radiating fins is greater than that of the lower radiating fins, the group of upper radiating fins and the group of lower radiating fins form a height fluctuation structure, two opposite vertical side walls of the upper radiating fins are provided with first grooves, the side wall of the upper distance adjusting block close to the upper radiating fins is provided with first bulges, the first bulges are arranged in the first grooves, the upper distance adjusting block is fixed on the side wall of the upper radiating fins through screws, two opposite vertical side walls of the lower radiating fins are provided with second grooves, and the side wall of the lower distance adjusting block close to the lower radiating fins is provided with second bulges, the second protrusion is arranged in the second groove, and the lower interval adjusting block is arranged on the second lower radiating fin through a screw.

Furthermore, in the internal and external double-layer efficient radiator with the adjustable distance between the radiating fins, the upper spacing adjusting block is provided with two first extending parts, the first extending parts are symmetrically arranged at two ends of the lower end surface of the upper spacing adjusting block, and the cross section formed by the upper spacing adjusting block and the two first extending parts is concave.

Furthermore, the above-mentioned double-deck high-efficient radiator inside and outside of adjustable distance type between radiating fin, be equipped with two second extensions on the interval regulating block down, the second extension symmetry sets up the both ends at interval regulating block up end down, the cross-section that interval regulating block and two second extensions formed down is "concave" style of calligraphy, the first extension of adjacent last interval regulating block and the second extension of interval regulating block down can laminate, first extension is located between two second extensions on the interval regulating block down, the second extension is located between two first extensions on the interval regulating block.

Furthermore, according to the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins, the end part of the push rod, which is far away from the group II of radiating fins, is provided with the knob, and the knob is provided with the anti-skidding ribs.

Further, in the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins, the first group of radiating fins has different lengths.

The technical scheme shows that the invention has the following beneficial effects: the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins is provided with the first radiating fins and the second radiating fins, the distance between the second radiating fins can be flexibly adjusted according to the heat productivity of a heating body, the distance between the radiating fins can be flexibly adjusted through the first radiating fin distance adjusting device, so that the radiator is higher in applicability and greatly improved in cooling performance, meanwhile, the arranged first radiating fin distance adjusting device is fast in adjustment, the distance between the second radiating fins can be fast adjusted only by pushing and pulling the push rod, and the first locking bolt are arranged, so that the position of the push rod is firstly determined, namely the distance between a group of second radiating fins is limited, the radiator is safe and reliable to use, the radiating efficiency is greatly improved, and the radiator has high popularization value.

Drawings

FIG. 1 is a schematic structural view of an internal and external double-layer efficient heat sink with adjustable distance between fins according to the present invention;

FIG. 2 is a front view of a second heat sink fin and a device for adjusting the distance between the heat sink fins according to the present invention;

FIG. 3 is a top view of the second heat sink fin and the device for adjusting the distance between heat sink fins according to the present invention;

FIG. 4 is a schematic structural diagram of a device for adjusting the spacing between fins according to the present invention;

fig. 5 is a schematic structural diagram of the outer heat sink mounting plate of the present invention.

In the figure: the heat radiation device comprises an inner-layer heat radiation plate mounting plate 1, an outer-layer heat radiation plate mounting plate 2, a heat radiation fin sliding groove 21, a heat radiation fin 3, a heat radiation fin assembly II 4 with adjustable spacing, a heat radiation fin spacing adjusting device 41, a push rod 411, a locking bolt I412, a locking bolt II 413, a linear optical axis I414, a linear optical axis II 415, an upper spacing adjusting block 416, a first protrusion 4161, a first extending portion 4162, a lower spacing adjusting block 417, a second protrusion 4171, a second extending portion 4172, a mounting base plate 418, a knob 419, a heat radiation fin II 42, an extending portion 421, a first groove 4211, an upper heat radiation fin II 422, a second groove 4221 and a lower heat radiation fin II 423.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Examples

The inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins comprises an inner-layer radiating fin mounting plate 1, an outer-layer radiating fin mounting plate 2, a group of radiating fins I3 and a group of radiating fin assembly II 4 with the adjustable distance, wherein the inner-layer radiating fin mounting plate 1 is a cylinder with two open ends, the outer-layer radiating fin mounting plate 2 is of a positive body type, the outer-layer radiating fin mounting plate 2 is sleeved outside the inner-layer radiating fin mounting plate 1, a group of radiating fins I3 is arranged between the inner-layer radiating fin mounting plate 1 and the outer-layer radiating fin mounting plate 2, and the radiating fin assembly II 4 with the adjustable distance is arranged on the multi-surface outer wall of the outer-layer. And the length of the group of first radiating fins 3 is different.

The second spacing-adjustable heat sink fin assembly 4 shown in fig. 2 and 4 includes a second heat sink fin spacing adjustment device 41 and a second set of heat sink fins 42, the second set of heat sink fins 42 are connected by the second heat sink fin spacing adjustment device 41, and the second heat sink fin spacing adjustment device 41 can adjust the distance between the adjacent second heat sink fins 42.

As shown in fig. 5, the outer-layer heat sink mounting plate 2 has a heat sink runner 21 on the multi-surface outer wall, the second heat sink 42 is a rectangular flat plate with a cross section in a shape of a Chinese character 'tu', and the two opposite sides of the lower end of the second heat sink 42 are provided with extension portions 421, the extension portions 421 are disposed in the heat sink runner 21, and the extension portions 421 can slide in the heat sink runner 21.

The heat dissipation fin spacing adjustment device 41 shown in fig. 4 comprises a push rod 411, a first locking bolt 412, a second locking bolt 413, a first linear optical axis 414, a second linear optical axis 415, a group of upper spacing adjustment blocks 416, a group of lower spacing adjustment blocks 417 and a mounting base plate 418, wherein the mounting base plate 418 is fixedly arranged on the outer wall of the outer-layer heat dissipation fin mounting plate 2, the lower end parts of the group of second heat dissipation fins 42 are sleeved on the first linear optical axis 414 and the second linear optical axis 415, the push rod 411 is arranged on the mounting base plate 418, two ends of the push rod 411 extend out of the mounting base plate 418, one end of the push rod 411 is fixedly connected with the end surface of the second heat dissipation fins 42 close to the mounting base plate 418 in the group of second heat dissipation fins 42, the first locking bolt 412 and the second locking bolt 413 are in threaded connection with the push rod 411, and the first locking bolt 412 and, the second group of radiating fins 42 are connected through a group of upper spacing adjusting blocks 416 and a group of lower spacing adjusting blocks 417, the upper spacing adjusting blocks 416 and the lower spacing adjusting blocks 417 are arranged at intervals, and the adjacent upper spacing adjusting blocks 416 and the lower spacing adjusting blocks 417 are overlapped.

In the above structure, the group of second heat dissipating fins 42 includes a group of second upper heat dissipating fins 422 and a group of second lower heat dissipating fins 423, the group of second upper heat dissipating fins 422 and the group of second lower heat dissipating fins 423 are arranged at intervals, and the height of the second upper heat dissipating fins 422 is greater than that of the second lower heat dissipating fins 423, the group of second upper heat dissipating fins 422 and the group of second lower heat dissipating fins 423 form a height fluctuation structure, two vertical side walls opposite to the second upper heat dissipating fins 422 are provided with first grooves 4211, the side wall of the upper spacing adjusting block 416 close to the second upper heat dissipating fins 422 is provided with first protrusions 4161, the first protrusions 4161 are arranged in the first grooves 4211, the upper spacing adjusting block 416 is fixed on the side wall of the second upper heat dissipating fins 422 by screws, two vertical side walls opposite to the second lower heat dissipating fins 423 are provided with second grooves 4221, the side wall of the lower spacing adjusting block 417 close to the second lower heat dissipating fins 423 is provided with second protrusions 4171, the second protrusion 4171 is disposed in the second groove 4221, and the lower interval adjustment block 417 is disposed on the lower heat dissipation fin 423 by a screw.

The upper spacing adjusting block 416 is provided with two first extending portions 4162, the first extending portions 4162 are symmetrically arranged at two ends of the lower end surface of the upper spacing adjusting block 416, and the cross section formed by the upper spacing adjusting block 416 and the two first extending portions 4162 is concave.

In addition, two second extending portions 4172 are provided on the lower interval adjustment block 417, the second extending portions 4172 are symmetrically provided at both ends of the upper end surface of the lower interval adjustment block 417, the cross section formed by the lower interval adjustment block 417 and the two second extending portions 4172 is "concave", the first extending portion 4162 of the adjacent upper interval adjustment block 416 and the second extending portion 4172 of the lower interval adjustment block 417 can be attached, the first extending portion 4162 is located between the two second extending portions 4172 on the lower interval adjustment block 417, and the second extending portion 4172 is located between the two first extending portions 4162 on the upper interval adjustment block 416.

In addition, a knob 419 is arranged at the end part of the push rod 411 far away from the group of second radiating fins 42, and anti-slip ribs are arranged on the knob 419.

The working principle of the inner and outer double-layer efficient radiator with the adjustable distance between the radiating fins is as follows: when the extension part 421 is tightly attached to the inner wall of the heat dissipation fin sliding chute 21 and pushes the push rod 411 towards the direction of the group of two heat dissipation fins 42, the push rod 411 pushes the two lower heat dissipation fins 423 connected with the push rod 411 to move in the heat dissipation fin sliding chute 21, the adjacent upper spacing adjusting block 416 is driven to move by the lower spacing adjusting block 417, the upper spacing adjusting block 416 drives the two upper heat dissipation fins 422 to move, and so on, the spaced upper spacing adjusting block 416 and the spaced lower spacing adjusting block 417 move in sequence, so that the two upper heat dissipation fins 422 and the two lower heat dissipation fins 423 move, and the distance between the group of two heat dissipation fins 42 can be pulled open; when the distance between the group of second heat dissipation fins 42 is reduced, the push rod 411 is pulled, the push rod 411 pushes the second lower heat dissipation fin 423 connected with the push rod 411 to move in the heat dissipation fin sliding groove 21, and the second lower heat dissipation fin 423 is driven to move, so that the distance between the group of second upper heat dissipation fins 422 and the group of second lower heat dissipation fins 423 is reduced.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that modifications can be made by those skilled in the art without departing from the principle of the present invention, and these modifications should also be construed as the protection scope of the present invention.

Claims (7)

1. The utility model provides an inside and outside double-deck high-efficient radiator of distance adjustable type between radiating fin which characterized in that: the heat dissipation structure comprises an inner-layer heat dissipation plate mounting plate (1), an outer-layer heat dissipation plate mounting plate (2), a group of first heat dissipation fins (3) and a group of second heat dissipation fin assemblies (4) with adjustable intervals, wherein the inner-layer heat dissipation plate mounting plate (1) is cylindrical with openings at two ends, the outer-layer heat dissipation plate mounting plate (2) is of a regular polyhedral shape, the outer-layer heat dissipation plate mounting plate (2) is sleeved outside the inner-layer heat dissipation plate mounting plate (1), the group of first heat dissipation fins (3) are arranged between the inner-layer heat dissipation plate mounting plate (1) and the outer-layer heat dissipation plate mounting plate (2), and the second heat dissipation fin assemblies (4) with adjustable;

wherein the second interval-adjustable heat dissipation fin assembly (4) comprises a second heat dissipation fin interval adjusting device (41) and a second set of heat dissipation fins (42), the second set of heat dissipation fins (42) are connected through the second heat dissipation fin interval adjusting device (41), the second heat dissipation fin interval adjusting device (41) can adjust the distance between the adjacent second heat dissipation fins (42), the second heat dissipation fin interval adjusting device (41) comprises a push rod (411), a first locking bolt (412), a second locking bolt (413), a first linear optical axis (414), a second linear optical axis (415), a set of upper interval adjusting blocks (416), a set of lower interval adjusting blocks (417) and a mounting base plate (418), the mounting base plate (418) is fixedly arranged on the outer wall of the outer layer heat dissipation fin mounting plate (2), and the lower end parts of the second set of heat dissipation fins (42) are sleeved on the first linear optical axis (414) and the second linear optical axis (415), the push rod (411) is arranged on the mounting base plate (418), two ends of the push rod (411) extend out of the mounting base plate (418), one end of the push rod (411) is fixedly connected with the end face of a second heat radiating fin (42) which is close to the mounting base plate (418) in a second group of heat radiating fins (42), a first locking bolt (412) and a second locking bolt (413) are in threaded connection with the push rod (411), the first locking bolt (412) and the second locking bolt (413) are respectively located on two sides of the mounting base plate (418), the second group of heat radiating fins (42) are connected with a second group of lower spacing adjusting blocks (417) through a first group of upper spacing adjusting blocks (416), the upper spacing adjusting blocks (416) and the lower spacing adjusting blocks (417) are arranged at intervals, and the adjacent upper spacing adjusting blocks (416) and the lower spacing adjusting blocks (417) are overlapped.

2. The internal and external double-layer efficient heat sink with adjustable distance between cooling fins of claim 1, wherein: the multiaspect outer wall of outer fin mounting panel (2) is equipped with radiating fin spout (21), two (42) radiating fins are the rectangle flat-plate that the cross-section is "protruding" style of calligraphy to two (42) lower tip relative both sides edge is equipped with extension (421), extension (421) set up in radiating fin spout (21) to extension (421) can slide in radiating fin spout (21).

3. The internal and external double-layer efficient heat sink with adjustable distance between cooling fins of claim 1, wherein: the group of second radiating fins (42) comprises a group of second upper radiating fins (422) and a group of second lower radiating fins (423), the group of second upper radiating fins (422) and the group of second lower radiating fins (423) are arranged at intervals, the height of the second upper radiating fins (422) is greater than that of the second lower radiating fins (423), the group of second upper radiating fins (422) and the group of second lower radiating fins (423) form a height fluctuation structure, two opposite vertical side walls of the second upper radiating fins (422) are provided with first grooves (4211), the side wall, close to the second upper radiating fins (422), of the upper spacing adjusting block (416) is provided with first protrusions (4161), the first protrusions (4161) are arranged in the first grooves (4211), the upper spacing adjusting block (416) is fixed on the side wall of the second upper radiating fins (422) through screws, and two opposite vertical side walls of the second lower radiating fins (423) are provided with second grooves (4221), and a second bulge (4171) is arranged on the side wall, close to the second lower radiating fin (423), of the lower spacing adjusting block (417), the second bulge (4171) is arranged in the second groove (4221), and the lower spacing adjusting block (417) is arranged on the second lower radiating fin (423) through a screw.

4. The internal and external double-layer efficient heat sink with adjustable distance between cooling fins of claim 3, wherein: the upper spacing adjusting block (416) is provided with two first extending parts (4162), the first extending parts (4162) are symmetrically arranged at two ends of the lower end face of the upper spacing adjusting block (416), and the cross section formed by the upper spacing adjusting block (416) and the two first extending parts (4162) is concave.

5. The inner and outer double-layer efficient heat sink of the type having an adjustable distance between fins as claimed in claim 4, wherein: the lower interval adjusting block (417) is provided with two second extending portions (4172), the second extending portions (4172) are symmetrically arranged at two ends of the upper end face of the lower interval adjusting block (417), the cross section formed by the lower interval adjusting block (417) and the two second extending portions (4172) is concave, the first extending portion (4162) of the adjacent upper interval adjusting block (416) and the second extending portion (4172) of the lower interval adjusting block (417) can be attached, the first extending portion (4162) is located between the two second extending portions (4172) on the lower interval adjusting block (417), and the second extending portion (4172) is located between the two first extending portions (4162) on the upper interval adjusting block (416).

6. The internal and external double-layer efficient heat sink with adjustable distance between cooling fins of claim 1, wherein: and a knob (419) is arranged at the end part of the push rod (411) far away from the group of second radiating fins (42), and anti-skid edges are arranged on the knob (419).

7. The internal and external double-layer efficient heat sink with adjustable distance between cooling fins of claim 1, wherein: the lengths of the first group of radiating fins (3) are different.

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