SU735902A1 - Heat pipe - Google Patents

Description

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The invention retreats to refrigeration technology, in particular, relates to adjustable low-intensity 1x heat pipes capable of operating in a thermo-diode mode.

A heat pipe is known, containing a hermetically enclosed tank filled with a heat-transfer fluid partially with a capillary tube inside and bellows, which are connected by means of a power electromagnet.

However, the existing device for regulating the flow of fluids in the shaft has a high thermal inertia, and also does not exclude the possibility of a rapid overheating of the thermoregulated object during the rise of the reverse heat flux. The magnitude of the heat inertia when the heat pipe is turned on depends on the time it evaporates the mass of the working fluid remaining in the fuel. Le between the connector and the evaporation zone. When in: Boss of a heat pipe, heat inflction, in its turn, depends on 1 strand of filling with the working fluid of the same part of a capillary porous wick. Thus, the regulation of thermal conditions of objects that require a clearer cutoff and restoration of the thermal flow, as well as the possibility of the appearance of reverse heat fluxes, using control devices located in the middle part of the skew zone, is difficult to prevent.

The purpose of the invention is to ensure the operation of the pipe in the heat flow switch mode and the reduction of inertia.

15

This is achieved by the fact that the capillary pump is installed in the form of an axial tube, the ends of which are closed by a capillary, porous material in the form of discs with ribs facing the ends of the silos of the backgrounds; bushings are attached to the housing outside, and the ends of the bellows are provided with rods passing through these sleeves and having movement stops. The drawing schematically shows a heat pipe. A heat pipe contains a hermetic body 1 partially filled with a heat-transfer fluid with a capillary pump 2 inside and bellows 3, the ends of which are connected by means of t 4 and 4 plugs 5, hinge b to the core; electromagnet 8. The capillary pump 2 is made in the form of an axial tube, the ends of which are closed by a capillary-porous material 9 in the form of discs with fins 10 facing the ends of the bellows. The sleeves 11 are attached to the housing 1 outside, and the ends of the bellows are provided with rods 12 passing through these sleeves and having travel stops 13. In the evaporation zone 14, there is a capillary-porous wick 15, consisting of capillary-porous rod elements, contacting one with its friction surfaces with a porous structure of the inner surface of the body 1, and others with a capillary-porous material 9. For the removal of steam from the evaporation zone 14 in the capillary-porous material 9 there are holes 16. The rods 12 serve to contact of the capillary-porous wick 15 with the inner surface of the body 1, and the ball stops 13 of movement serve to stop the inner surface of the body in the extreme positions .. 13 temperature-controlled object (shown in the drawing K9) of the evaporation zone 14 and The heat-dissipating surface of the condensation zone 18 is fitted with a thermal exponent 19. The working fluid, due to capillary forces 2, leads to the porous structure of the surface of the housing 1, forming a layer of working fluid on it. When nairpeBa shea surface of the housing 1 pair, the working fluid comes from the zone 14 of evaporation through the holes 16 of the material 9 into the zone of transfer and then into the zone 18 con. The delays, from where the condensate returns to the pump 2. When the signal comes from the temperature sensor 17 installed in the thermoregulated object, (for example, the object temperature has dropped below the permissible value), the device is activated and the core 7 moves, for example, along the arrows kam A; providing, by means of a simple mechanic, one-time water from the surface of the housing 1 and the heat transfer surfaces of the condensation zone 18 from the wick 15 (rod elements). In this case, the supply of working fluid from the capillary-porous material 9 to the surface structure of the housing 1 is stopped, thus cutting off the heat flow, and the heat pipe is turned off. In this case, the core elements of the wick remain constantly saturated with the working fluid. The heat pipe is turned on by applying a signal from the temperature sensor to the second winding of the electromagnet 8. In this case, the lever mechanism operates in reverse order, providing simultaneous supply of the inner surface of the housing 1 and the heat transfer surface of the condensation zone 18 to the wick rod 15 saturated with the working fluid. In the event that the flow of fluid oi to the surface of the housing 1 is resumed, the heat pipe is turned to the on position. In the event of the occurrence of return heat fluxes greater than or equal in size to the direct fluxes, it comes from the temperature sensor 19, which controls the temperature; The heat-transfer surface of the condensation zone 18, the electromagnet off winding, using the Kotiporo surface of the housing 1 and the heat transfer surface of the condensation zone 18 are simultaneously removed from the rod elements fitkl 15 and the heat pipe is switched to lolo :: the sleep is turned off, ensuring the cut-off of the reverse heat flux to the temperature controlled object . Cutting off the supply of working fluid to the evaporator's heat transfer surface directly at the place where the heat flow is supplied and keeping the fuse of the heat pipe constantly saturated with this fluid can significantly reduce the thermal inertia in the process of adjusting the heat flow and, thereby, increase the accuracy of the temperature control of the object . Formula and 3 about the shadows 1. A heat pipe, containing a hermetically sealed body, partially filled with a heat-transfer fluid, with a capillary pump inside and bellows;

Claims (2)

Formula and z o b rstsni I 1. A heat pipe containing a sealed housing partially filled with liquid heat carrier with a capillary pump inside and bellows, the ends of which 5 735902, 6 are connected by means of rods with a power electromagnetic drive, characterized in that, in order to ensure the operation of the pipe in mode, the thermal switch flow and reduce inertia, the capillary pump is made in the form of an axial pipe, the ends of which are closed by a capillary-porous material in the form of disks with ribs facing the ends of the bellows. 2. The pipe in π. 1, characterized in that, on the outside, bushings are attached to the housing, and the ends ι of the bellows are equipped with rods passing ₅ through these bushings and having movement limiters.