SU1673824A1 - Flat thermal pipe - Google Patents

Abstract

The invention relates to the field of heat engineering and can be used in heat pipes. The purpose of the invention is to simplify the technology of manufacturing heat pipes. The flat heat pipe comprises a housing 1, on the opposite walls of which a capillary-porous structure 2 is located. The latter is located with a slot in the central part, in which a grid 3 is installed in contact with the structure, forming steam discharge channels. In the manufacture, the connection of the housing 1 with the capillary-porous structure 2 and the structure with the grid 3 is made simultaneously by diffusion welding, which simplifies the manufacturing technology without reducing the rigidity of the structure. 1 il.

Description

The invention relates to heat engineering, namely to heat pipes, and can be used for cooling large-sized printed circuit boards of electronic equipment. !

The purpose of the invention is the simplification of manufacturing technology.

The drawing shows a heat pipe. general form.

The heat pipe contains a housing 1 with capillary-porous | structure 2. The capillary-porous structure 2 can be presented in various versions. It can be a porous metal obtained by sintering a metal powder, several layers of meshes of various sizes and t .d. The working fluid can be acetone, water, alcohol, etc., as in any heat pipe. The capillary structure 2 on the opposite walls of the casing is installed with 2 the formation of a gap in its central part, in which there is a layer of a coarse mesh 3. forming vapor channels. The mesh 3 with the capillary-porous structure 2 and the capillary-porous structure 2 with the housing 1 can be connected by diffusion welding in vacuum, which allows to maintain the rigidity of the entire structure. In this case, the ratio of the mesh cell size to the average pore diameter of the capillary-porous structure satisfies the ratio: 20 <a / dcKc <dtt / dcKc, where a is the mesh cell size: dcxc is the average pore diameter of the capillary-porous structure. dut is the thickness of the heat pipe. 3

The heat pipe works as follows.

Heat is supplied through the housing 1. The coolant, evaporating on the liquid-vapor interface (from the capillary-porous structure 2 saturated with liquid), is removed in the form of steam through the voids of the grid 3 and condenses in the heat removal zone. The heat carrier is returned to the evaporation zone due to the capillary-4 forces of the capillary-porous structure 2.

The presence of mesh layer 3 instead of many small channels makes it possible to simplify the technology of manufacturing a heat pipe due to the absence of operations for the production of channels in the capillary-porous structure. The connection of the coarse mesh layer, which is also a rigid skeleton with a capillary-porous structure, preserves the rigidity of the entire structure.

To test the design of the heat pipe, a flat heat pipe was made of stainless steel with dimensions: length 235 mm, width 50 mm, thickness 3.5 mm. As a heat carrier, 5 acetone was used. The case was made of 0.8 mm thick sheets, the capillary-porous structure was made of meshes with mesh sizes of 40 μm, and the mesh layer in the gap was 1.8 mm thick (mesh size 2.3 mm). Tests were carried out by mixing the heat supply zone with an area of 195 cm ² in the middle part and the heat removal zone with an area of 40 cm ² at the ends of the casing. The temperature difference between the zones of supply and removal of heat amounted to

3.5 and 5.8 ° C with heat input 25 and 50 W, respectively.

Claims (1)

Claim A flat heat pipe containing a casing, the opposite walls of which are provided with a capillary-porous structure with a system of steam channels in the central part of the casing, characterized by heme, which, in order to simplify the manufacturing technology, the capillary-porous structure is located with the formation of a gap in the central part of the casing, and the system of vapor channels is formed by a mesh layer installed in this slot and adjacent to the capillary-porous structure, and the ratio of the mesh cell size a to the average capillary pore diameter dcxc -poristoy structure satisfies the relation 20 <~~ <—-, lawsuit lawsuit where όπ ^{_ is the} thickness of the heat pipe. Compiled by S. Bugorskaya Editor A. Dolinich Tehred M. Morgenthal Corrector O. Kundrick Order 2908 Circulation 376 Subscription VNIIIPI of the State Committee for Inventions and Discoveries under the State Committee for Science and Technology of the USSR 113035. Moscow, Zh-35, Raushskaya nab., 4/5 Production and Publishing Plant ^ Patent ', Uzhgorod, 101 Gagarina St.