RU115549U1 - HEAT DISCHARGE RADIATOR (OPTIONS) - Google Patents

Abstract

1. A radiator for removing heat in a source of thermal radiation, comprising a housing with plates, characterized in that it is type-setting, while the plates are longitudinally and freely located on the housing with a gap between them. ! 2. The radiator according to claim 1, characterized in that it further comprises spring rings located on the housing between the plates. ! 3. Radiator according to claim 2, characterized in that each of the rings is connected to at least one plate by means of mechanical contact without a gap. ! 4. Radiator according to any one of claims 1 to 3, characterized in that the plates are perforated. ! 5. Radiator according to any one of claims 1 to 3, characterized in that it is a radiator for an LED radiation source. ! 6. A radiator for removing heat in a heat radiation source, comprising a housing with plates, characterized in that it is type-setting, the plates are made L-shaped, and the seating surface of each subsequent plate is located in contact with the previous plate. ! 7. Radiator according to claim 6, characterized in that the plates are perforated. ! 8. Radiator according to claim 6, characterized in that it is a radiator for an LED radiation source.

Description

The utility model can be used to remove heat from the heating area of objects for various purposes, including radiation sources.

The modern designs of heat dissipation radiators in various devices (LED lamps and other semiconductor devices, computer equipment, etc.), indicate the movement of manufacturers in two main directions: aluminum radiators obtained by casting or extrusion of an aluminum alloy (see an example of such a design in particular, using the example of an LED lamp http://varton.ru/products/o-produktsii/), or plate radiators in the form of a plurality of plates installed on the body by soldering or hard-fitting (see, in particular STI, an example of a structure for radiators based on http://wap.fictionbook.ru heat pipes). Such designs proved to be quite well established as heat removal elements, however, their use is associated with the complexity of manufacturing such (the need for casting, soldering, high requirements for the construction of composite elements), which, as a result, leads to the high cost of such radiators and, as a result high total cost of the product as a whole.

The task set by the authors when creating the options for this utility model is to create an efficient and cheap radiator for removing heat from the heating area, while the technical result to be achieved when the task is achieved is to increase the manufacturability of the radiator design based on the requirements of mass and mass production, improving overall dimensions while maintaining the thermal mode of operation and, as a result, reducing the cost of the design of the radiator.

To achieve the set result in a radiator for heat removal in a heat radiation source according to the first of the claimed variants, comprising a body with plates, it is proposed to perform a heatsink with a heatsink, and place the plates longitudinally and freely on the body with a gap between them.

Preferred, but not required examples of the first embodiment include the presence of a spring ring located on the housing between the plates, each ring can have mechanical contact without a gap with at least one plate by mechanical connection, the plates can be made perforated to increase the efficiency of heat dissipation and reduce mass characteristics, and the radiator itself serves as a radiator of an LED radiation source.

In order to achieve the set result in a radiator for heat removal in a heat radiation source according to the second of the claimed variants, comprising a housing with plates, it is proposed to make the radiator type-setting and the plates L-shaped, with the landing surface of each subsequent plate being placed in contact with the previous plate.

Preferred, but not required examples of the second embodiment include perforated plates to increase heat sink efficiency and reduce mass characteristics, or use a radiator as a radiator of an LED radiation source.

The ability to achieve the desired result in the claimed designs is due to the maximum simplification of the assembly unit “body-plate heat dissipation” through their simple pairing without the use of any mechanical assembly operations (soldering, interference, etc.).

The utility model is illustrated by drawings, where:

Figures 1 and 2 show examples of designs of the first and second of the claimed options using them as an example in the composition of an LED radiation source, in a general form containing a light emitter, holder of a light emitter, connecting leads and a coating lens;

Figure 3 illustrates the use of perforated plates.

The radiator according to the first of the declared variants — with a horizontal spatial orientation of the heat removal plates — comprises a base body 2 and longitudinally and freely located on the body of the heat removal plates 1 in the form of disks. In a preferred, but not mandatory example of implementation, split rings 3 are located between the plates (Fig. 1). The radiator is assembled in the following sequence:

plates and rings are sequentially assembled onto the housing by their free placement (it is obvious that the number of rings and their outer diameter are selected from the requirement for effective heat removal in accordance with the characteristics of the product). At the end of the set, a cup 4 is placed on one of the ends of the casing, which is connected through the holder of the light emitter to the end of the casing by means of, for example, rivets 5. The efficiency of such a design of the radiator is due, in particular, to the fact that the split rings are due to the elastic properties of the material, on the one hand (radially), tightly (gaplessly) adjacent to the landing surface of the body, and on the other (in the axial direction) - tightly (gapless) adjacent to the surfaces of the plates, providing the necessary conditions for effective heat operedachi heat from the housing of the chain "casing-ring disc-air."

The radiator according to the second of the claimed variants is also made with the horizontal spatial orientation of the heat removal plates 1, made in the form of L-shaped disks (Fig. 2). The radiator case is essentially made integral, in the form of a cup 4 on one side and a stop 7 on the other. The assembly of the structure is as follows:

disc elements 1 seamlessly inserted into each other; the resulting structure is pulled together with a screed 8 through the holder of the light emitter and the cup 3 on one side and the stop 7 on the other, fixing the assembly obtained, for example, with rivets, a screw connection or the like. The principle of operation of the second variant of the radiator is identical to the first and consists in the transfer of heat from the holder of the light emitter, through the cup to the nearest disk and further along the chain to the following elements for dispersion.

Summing up, in the case of using the declared radiator options as a radiator of an LED radiation source, the plate area is determined by the power consumed by the LED lamp and is 20-30 cm ² per watt of power consumption.

Claims (8)

1. Radiator for heat dissipation in a source of thermal radiation, comprising a housing with plates, characterized in that it is made type-setting, while the plates are longitudinally and freely located on the housing with a gap between them. 2. The radiator according to claim 1, characterized in that it further comprises spring rings located on the housing between the plates. 3. The radiator according to claim 2, characterized in that each of the rings is connected to at least one plate by mechanical contact without a gap. 4. Radiator according to any one of claims 1 to 3, characterized in that the plates are perforated. 5. A radiator according to any one of claims 1 to 3, characterized in that it is a radiator of an LED radiation source. 6. Radiator for heat dissipation in a source of thermal radiation, comprising a housing with plates, characterized in that it is made type-setting, while the plates are L-shaped, and the seating surface of each subsequent plate is in contact with the previous plate. 7. The radiator according to claim 6, characterized in that the plates are perforated. 8. The radiator according to claim 6, characterized in that it is a radiator of an LED radiation source.