SU1035400A1 - Transphoton heat pipe and its operation method - Google Patents

Abstract

1. A transphoton heat pipe, comprising a housing with evaporation and condensation zones, equipped with a fiber-optic wick, coupled with a thermal converter and a light plant located at the end of the housing, so that launching the heat pipe from the frozen state, the fiber-optic wick contains light-conducting cores of a phtoto-chromic material, and the photothermal transducer is designed as a modular block of optical diameters installed at the ends of the light-conducting light in the condensation zone and having a thermal contact between. 2. A method for operating a photophoton heat pipe by receiving and transmitting a light flux through a fiber-optic wick to a heat release section in the evaporation zone, converting the light energy in this section to heat with evaporation of the coolant and subsequent condensation of vapors in the condensation zone. and with the fact that, in order to ensure the launch of the heat pipe from the frozen state, the heat release section is preliminarily shifted to the condensation zone and only then with a gradual heating of the wick and a decrease in its light-path This ability moves this site to the evaporation zone.

Description

This invention relates to technology and can be used in solar probes. A heat pipe is known, comprising a casing with Evaporation, Transport and Condensation Zones and a light guide. A pipe deficiency is unsatisfactory performance. A photophoton heat pipe is known, comprising a housing with zones. evaporation and condensation, equipped with a fiber-optic wick, conjugated with a photothermal transducer and a light guide located at the end of the body, and how it works by receiving and transmitting light flux through the fiber-optic wick to the heat release section in the evaporation zone, converting light energy in this area to heat with evaporation of the coolant and subsequent condensation of vapors in the condensation zone,. . A disadvantage of the known device of its method of operation is the impossibility of restarting the pipe into operation from the frozen state without an auxiliary heat pipe. The purpose of the invention is to provide for starting the heat pipe from the frozen state. This goal is achieved by the fact that in a photophoton heat pipe containing a body with evaporation zones to condensation, equipped with a fiber-optic wick conjugated with a photothermal converter and a light guide located at the end of the body, the fiber-optic wick contains light-conducting wires of photochromic material and the photothermal converter is made in the form of a modular block of optical diaphragms installed at the ends of the light-conducting veins in the condensation zone and having a thermal contact between them, In addition , according to the method of operation of a photophoton heat pipe by receiving and transmitting a light flux through a fiber-optic wick to the heat release section in the evaporation zone, converting the light energy on this site into heat with evaporation of the heat carrier and subsequent condensation of the vapors in the condensation zone. preliminarily, the heat release section is shifted to the condensation zone and. Only then, with a gradual warming up of the wick and a decrease in its light transmission ability, does this site move to the evaporation zone. FIG. 1 schematically shows the proposed heat pipe; in fig. 2 — node 1 in FIG. 1. Transfoto thermal pipe contains a housing. with evaporation zones 2. and condensation 3, equipped with an optical fiber wick containing a saprotective core 5 of photochromic material, the net conducting capacity of which decreases with increasing temperature, and fiber optic filament 6 with a reflective sheath. At the same time, the optical fiber wick k is coupled to the light guide 7 located at the end 8 of the housing 1 and the photothermal converter made in the form of a modular unit 9 (for example, of porous glass, glass ceramics) including optical apertures 10 of the light absorbing material , installed in thermal contact with the ends of the sapontractive veins 5 in the evaporation zone 3. For example, glass with additives of sulfur, cadmium sulfide, additives of europium, cerium, silver halogens, etc. is used as the material of the light-conducting veins 5, the proposed heat pipe is as follows. one. . The light flux through the light guide 7 is transmitted by the adjacent end of the light-conducting veins 5, through which it is transported to the condensation zone 3, where the optical diaphragms 10 are converted to thermal energy. in the direction of the evaporation zone 2, which leads to a decrease in the light transmittance of the light-conducting veins 5 and further melting of the coolant. The portion of the heat input, initially shifted to the condensation zone 3, is transferred to the evaporation zone 2, where with the onset of the nominal mode of operation of the heat pipe, the coolant begins to evaporate.

JOSE OO4

its vapors move along the vapor channel. Thus, the invention allows condensation zone 3, from where it condenses to ensure the start of the heat pipe, returned with the help of phyto from the frozen state and increase the reliability of its operation to zone 2.

Claims (2)

1. Transfoton heat pipe containing a housing with zones of evaporation and condensation, equipped with an optical fiber wick, paired with a photothermal converter and a light guide located at the end of the housing, so that with the aim of to ensure that the heat pipe starts from a frozen state, the fiber optic wick contains light-conducting conductors of optical optic diaphragms, ends of light-condensation and thermal contact. of chromochromic material, and the photothermal transducer is made in the form of a modular block installed on the living veins in the zone 2. The method of operation of the trans-photon heat pipe by receiving and transmitting the light flux through the fiber optic wick to the heat release section in the evaporation zone, converting the light energy in this area. heat with evaporation of the coolant and subsequent condensation of vapors in the condensation zone, except that in order to ensure that the heat pipe starts from the frozen state, the heat release section is preliminarily displaced into the condensation zone and only then with gradual warming the wick and reducing its light transmittance move this section to the evaporation zone.