SU1467355A1 - Thermal tube - Google Patents

Abstract

The invention relates to a heat-producing device 1M with a cooling effect. The purpose of the invention is to ensure the operation of the pipe with a refrigerating effect under conditions of cyclical change of the direction of the heat flow. A housing with a capillary-porous structure 2 on its inner surface is filled with a binary mixture of low- and high-boiling components. The absorption zone 4 combined with the evaporation zone, the condensation zone 5 and the refrigerating chamber 6 are arranged in series and separated from one another through the steam channel 3 by transverse partitions 7, 8. The zone 4 and the chamber 6 are interconnected by a pipeline 9 passed through the partitions 7, 8 The pipeline 9 in the area of the chamber 6 is provided with a check valve 11 and is connected, through another check valve 10, to channel 3 in zone 5. The partition 7, located at the boundary of zone 4, is located with the overlapping cross section CTpyKTyiMJ 2. When heat is applied to the zone Not 4 evaporates. A low boiling component, the vapor of which enters zone 5, where, evaporating, produces a cooling effect. In the second half of the cycle, heat is removed from zone 4, where the pressure is reduced and the vapor of the low boiling component from chamber 6 enters zone 4, where the binary cNKCbro is absorbed. 1 il. ABOUT)

Description

The invention relates to heat engineering, namely to heat transfer devices with a refrigerating effect.

The purpose of the invention is to ensure the operation of a pipe with a refrigerating effect under cyclic changes in the direction of the heat flow.

The drawing schematically shows a heat pipe, a longitudinal section. 10 The heat pipe contains a partially filled coolant in the form of a binary mixture of low and high boiling water! components housing 1 with capillary-on! a porous structure 2 on its internal 15 • surface, a vapor channel 3 and sequentially located the combined zone 4 of evaporation and absorption, zone 5 of condensation and a refrigeration chamber! measures 6, separated by 20 transverse walls 7 and 8, the first of which overlaps the steam channel 3 and the capillary-porous structure 2, and the second only the steam channel 3. Pipe-25 1 is passed through the walls 7 and 8, equipped with 9 in the condensation zone 5 and the refrigeration chamber 6 by check valves I0 and II, respectively.

The heat pipe works as follows, βθ as follows.

When heat is supplied in zone 4 of evaporation from a binary mixture (for example, water-ammonia), a predominantly low-boiling component is vaporized and its steam passes through pipeline 9 through the non-return valve 10 to the condensation zone 5 (non-return valve 11 is closed at this time), the liquid condenses the capillary-porous structure 2 passes into the refrigerating chamber 6, where, evaporating at a lower pressure, it produces a refrigerating effect. On this, the first half of the work cycle ends. In the second half of the cycle, heat is removed from zone 4 (due to a change in external conditions), which becomes an absorption zone, the vapor pressure of the binary mixture in this zone decreases, valve 10 closes, valve II opens and the vapor of the low-boiling component from the refrigeration chamber 6 enters zone 4, where it is absorbed by a binary mixture. On this working nickle ends.

Claims (1)

Claim A heat pipe containing a housing partially filled with a binary mixture of low and high boiling components with a capillary-porous structure on its inner surface, a vapor channel, an evaporation zone and successively located absorption, condensation and refrigeration zones separated from each other by transverse partitions along the vapor channel, the zone absorption and the refrigeration chamber are interconnected by a pipe passed through partitions, characterized in that, in order to ensure the operation of the pipe with cold Under the conditions of cyclic change in the direction of the heat flow, the evaporation zone is combined with the absorption zone, the pipeline in the section of the refrigerating chamber is equipped with a check valve and is additionally connected via another check valve to the steam channel in the condensation zone, and the transverse partition located at the boundary of the absorption zone is located with overlapping cross section of capillary-porous structure.