SU1278565A1 - Heat-transferring arrangement - Google Patents

Abstract

The invention relates to the field of heat engineering and can be used to cool and heat stabilize various devices. The aim of the invention is to increase the heat transfer ability. The device has a housing 1 with zones of supply and removal of heat. It is divided by partitions into cells 8, in each of which an additional sleeve 9 is installed, provided with a capillary-porous coating 10 and having an I-profile in two longitudinal sections. One of the bases of the sleeve is in contact with the capillary-porous coating 6 of the plate 4. On this basis, the coating 10 of the sleeve 9 is multi-layered, with mutually intersecting them with steam discharge channels in the adjacent layers of the coating 10. When heat load is applied to the plate 4, heating and evaporation occur heat carrier. The resulting steam through the vapor channels passes into the steam chamber 12. Next, O) the heat carrier is condensed on the side surfaces of the sleeves 9 and the condensate returns to the base C of the sleeve 9 facing the plate 6 by capillary forces. Each cell 8 works on the heat pipe principle. 4 il. 1ch oo ate 05 SL

Description

The invention relates to heat engineering and can be used to cool and heat stabilize various devices.

The purpose of the invention is to increase the heat transfer capacity.

FIG. 1 shows the proposed device, a longitudinal section; 2 is a section A-A in FIG. one; on fig.Z - section bb in figure 1; figure 4 - sleeve, isometric.

The device comprises a housing 1 with zones of supply 2 and heat removal 3, the first of which is made in the form of a plate 4 with grooves 5 on the inner surface provided with a capillary-porous coating 6. Moreover, the housing 1 is divided by partitions 7 into cells 8, in each of which additionally, a sleeve 9 is installed, provided with a capillary-porous coating 10 and having an I-beam profile in two longitudinal sections. In this case, sleeves 9 with side surfaces of bases 11 are installed in contact with partitions 7 and side walls of housing 1 with formation of steam chambers 12, and one of bases 11 with capillary-porous coating 6, and on this basis coating 10 of sleeve 9 is made with mutually intersecting steam tapping channels 13 in adjacent layers and on plate 4. Pore size in coating 6 MeHbQie of pore size in coating layers 10. The cooling system consists of inlet 14 and outlet 15 of the cooling medium collectors formed by the bases of the sleeves 9, partition 16 and the bottom 17. In the sleeves 9 there are made blind holes in which the tubes 18 are installed. For filling the heat transfer device, there are provided the filling caps 19.

Heat transfer device operates as follows.

When applying heat, the load to the plate 4 is heated and evaporation of the coolant. The resulting steam through the vapor discharge channels 13 passes into the steam chamber 12, creating in its volume a vortex motion due to the tangential exit of these channels. The coolant is then condensed on the side surfaces of the sleeves 9 and the condensate is under the action of capillary forces. returns to the base 11 of the sleeve 9 facing the plate 4, impregnating the coating 6. The cycle is repeated. The external cooling system is designed to cool the side surfaces of the sleeves 9. The cooling medium from the inlet manifold 14 passes through the tubes 18 into the annular gaps formed by the tubes 18 and the openings in the sleeves 9, and then goes to the output collector 15. Cooling the side surfaces of the sleeves 9 can be produced by other means, such as radiation, conductive heat exchange, etc.

The smaller pore size of the coating 6 as compared to the coating 10 improves the mass transfer of the heat carrier to the heat supply zone 2.

The invention makes it possible to increase the heating surface by arranging the necessary number of cells, each of which operates according to the heat pipe principle. The small size of each cell ensures an even distribution of the heat transfer medium in the heat supply zone and prevents the drying of a cap il l p porous coating.

Thus, the invention makes it possible to remove high specific heat loads from large heating surfaces while maintaining the isothermal and any orientation of the device.

Claims (1)

Invention Formula A heat transfer device comprising a housing with heat input and heat removal zones, the first of which is made in the form of a plate with grooves H; J of the inner surface provided with potassium: a transparent-porous coating, characterized by that. In order to reduce heat transfer capacity, the body is divided by partitions into cells, in each of which there is an additional sleeve, provided with a capillary-porous coating and having an I-beam profile in two longitudinal sections, with the sleeves lateral surfaces of the bases installed in contact. with partitions of the side walls of the hull with formation of steam chambers, and one of the bases - i. capillary-assisted coating of a layer of 1 part; on this layer, a capillary-porous coating of the sleeve was multi-layered with intersecting steam discharge channels in adjacent layers. Xl-xi (.g bb b / 13 7 Fig.Z