WO2018182449A1 - Heat sink - Google Patents

Abstract

The utility model relates to devices for dissipating heat from electronic components, and more particularly to heat sinks. The technical result is more efficient heat dissipation due to the development of a heat sink having a portion in the form of a platform with raised edges, formed by heat sink fins and heat-conducting strips, wherein an equalizing heat-conducting plate is fastened on top of the platform for more even distribution of heat across its surface and for the fastening thereto of a housing with heat emitting elements. The technical result is achieved in that the claimed heat sink comprises individual heat sink fins and heat-conducting strips, which are arranged successively and are rigidly connected to one another such that a heat-conducting strip is fastened between each adjacent heat sink fin, wherein a number of the inner heat sink fins are formed with a U-shaped recess which, together with the edges of the heat-conducting strips, forms a platform having raised edges along its perimeter, formed by portions of the heat sink fins, wherein an equalizing heat-conducting plate is fastened on top of the platform, said plate being capable of evenly distributing heat across its surface and of having a housing fastened thereto with heat emitting elements, and the length of each heat-conducting strip is less than or equal to the width of the adjacent heat sink fin.

Description

 Description

 Radiator

 The technical field to which the utility model relates.

The invention relates to devices for removing heat from electronic components, namely radiators.

State of the art

 Known radiator (RU 2217886 C2, publ. 11/27/2003), containing many individual radiator plates bonded to each other in their connecting part with the formation of a heat-absorbing part in contact with the heat-generating surface of the electronic component, while the parts of the radiator plates are opposite heat-absorbing parts are separated from each other and together form heat-removing parts; and fastening means for fastening together a plurality of radiator plates. The disadvantage of this analogue is the inefficient removal of heat from several distributed sources, since the heating of the radiator plates occurs unevenly. In addition, the installation of a radiator requires an additional housing, which impairs the compactness of the assembly of the product as a whole.

Utility Model Disclosure

 The technical result consists in more efficient heat dissipation, due to the development of a radiator, part of which is made in the form of a platform with sides from radiator plates and heat-conducting strips, and a heat-conducting leveling plate is fixed over the site for more even distribution of heat on its surface and fixing the body to it with heat-generating elements.

The technical result is achieved by the claimed radiator, which includes sequentially and rigidly interconnected individual radiator plates with heat-conducting strips, so that a heat-conducting bar is fixed between each adjacent radiator plates, and some of the internal radiator plates are made with p-shaped cutouts that form a platform with edges of heat-conducting strips, along the perimeter of which there are bumpers made of parts of radiator plates, and a heat-conducting leveling plate is fixed over the site, which is made with the possibility of uniform distribution of heat over its surface and fixing her body with the heat-generating elements, and the length of each heat conducting strips is less than or equal to the width of the adjacent fins.

 According to a useful model, the radiator plates and the heat-conducting strips are interconnected by means of at least one bolt with a nut, which is inserted into the common holes of the radiator plates and heat-conducting strips.

 According to a utility model, a heat-conducting leveling plate is fixed to the site by means of at least one bolt that is inserted into the common holes of the site and the heat-conducting leveling plate.

Brief Description of the Drawings

 The essence of the utility model is illustrated: FIG. 1, which shows a diagram of a preferred embodiment of the inventive radiator; FIG. 2, which shows the internal radiator plate with holes and a p-shaped neckline; FIG. 3, which shows a radiator plate with holes without a p-shaped notch; FIG. 4, which shows the heat-conducting strip of the radiator with holes.

Utility Model Implementation The figure 1 shows a radiator, comprising sequentially and rigidly connected to each other radiator plates 1 with heat-conducting strips 2, so that between each adjacent radiator plates 1 a heat-conducting bar 2 is fixed, and some of the internal radiator plates 1 are made with p-shaped cutouts, which form, with ribs, or with ends, of the heat-conducting strips 2, a platform 3, along the perimeter of which there are edges made of parts of the radiator plates 1, and a heat-conducting material is fixed over the platform leveling plate 4, which is made with the possibility of uniform distribution of heat on its surface and fixing on it a body with heat-generating elements, and the length of each heat-conducting strip 2 is less than or equal to the width of the adjacent radiator plate 1.

 In addition, in a private embodiment of the claimed radiator, scattered radiator plates that do not have complete thermal contact with each other are fed through ends perpendicular to the distribution of heat.

 The principle of operation of the claimed radiator is as follows.

 The heat from the case with the heat-generating elements is transferred to the heat-conducting leveling plate 4, which evenly distributes the heat on its surface and to the pad 3. Further, the pad 3 absorbs all the heat and is distributed simultaneously to the heat-conducting strips 2 and the radiator plates 1. Thus, by means of the pad 3, which is located inside and recessed in the design of the radiator, all heat-absorbing elements of the claimed radiator are more efficiently used for heat transfer.

 Industrial applicability

Modern technologies and equipment make it possible to implement a real utility model in large-scale production. In factories and s enterprises have all the necessary machines and equipment for the production of the claimed radiator.

Claims

Formula

 1. A radiator comprising in series and rigidly connected separate radiator plates with heat-conducting strips, so that a heat-conducting strip is fixed between each adjacent radiator plates, and some of the internal radiator plates are made with u-shaped cutouts that form a pad with the edges of the heat-conducting strips , along the perimeter of which there are bumpers made of parts of radiator plates, and a heat-conducting leveling plate is fixed over the site, which is made with the possibility of uniform distribution of heat on its surface and fixing on it a body with heat-generating elements, and the length of each heat-conducting strip is less than or equal to the width of the adjacent radiator plate.

 2. The radiator according to claim 1, characterized in that the radiator plates and heat-conducting strips are interconnected by at least one bolt with a nut that is inserted into the common holes of the radiator plates and heat-conducting strips.

 3. The radiator according to claim 1, characterized in that the heat-conducting leveling plate is fixed to the site by means of at least one bolt that is inserted into the common holes of the site and the heat-conducting leveling plate.