SU1265734A1 - Electrohydraulic constant-temperature cabinet - Google Patents

Abstract

The invention relates to temperature control systems designed for thermostating heat-generating objects, and can be used in radio-electronic devices with variable magnitude and time heat release of individual components of the design elements operating under conditions of a continuously varying field of mass forces, in particular, the gravitational floor. The purpose of the invention is to demonstrate the effectiveness of thermostating by extending the range of regulation by the maximum heat flux. The electrohydrodynamic thermostat contains a thermostatically controlled chamber, a heat insulating jacket, a jacket filled with a dielectric fluid. Blade-shaped electrodes are placed in the jacket, one of the edges of which is insulated, the electrodes have a high-voltage lead, and they are connected to a high voltage source. The outer wall of the casing includes a heat-conducting fin. The curved area opposite to which is a mesh electrode fixed on bimetallic plates in a jacket. The shirt's space is divided into channels by dielectric chambers. On the outer wall of the casing on a dielectric support, a needle corona electrode is attached, which is connected to an adjustable source of high voltage. An insulating section is provided on one of the edges of the electrodes. The system of blade electrodes with one insulated edge, installed in pairs in a shirt in the channels formed by dielectric partitions, allows to create directed velocity flows of the heat-transfer fluid, their even number organizes the most optimal flow type, which allows to expand the range of regulated; nor by the maximum heat flux. 2 h, para. f-ly. 2 Il.

Description

The invention relates to temperature control systems designed for thermostating heat generating objects, and can be used in radio electronic devices with variable size and temporal heat release of individual constituent elements of the structure operating under conditions of a continuously varying field of mass forces in particular a gravitational field. . The aim of the invention is to increase the efficiency of thermostating by extending the control range to maximum heat flux. Fig, 1 shows a thermostat, a general view; Fig. 2 shows blade-shaped electrodes and their placement in thermostat channels. The electrohydrodynamic thermostat contains a thermostatically controlled chamber 1 placed in a heat insulating jacket 2 and surrounded by a jacket 3 filled with a dielectric fluid. The jacket contains blade-like electrodes 4 and 5, one of the edges of which is isolated, the electrodes are connected via a high voltage input 6 to a high voltage source. The outer wall of the casing 2 includes a heat-conducting finned section 7, opposite to which a grid electrode 8 is placed in the jacket, mounted on bimetallic plates 9 through insulating elements 10 on the surface of a thermostatted chamber 1, the Electrode 8 is connected to a high-voltage current source through a bushing insulator 11, The space of the jacket is divided into channels by dielectric partitions 12. On the outer wall of the casing 2 on the dielectric support 13, a needle corona electrode 14 is fixed, connected to a controlled source iku high voltage on one of the edges of the electrodes 4 and 5 vsholnen insulating portion 15 Elektrogidrodinamichosky thermostat operates as follows. When applying voltage to electrodes 4, 5, 8, and 14 and variable external and internal thermal conditions (temperature, humidity, pressure, air velocity, heat generation of a thermostatted object, orientation, chi, acceleration in the field of mass forces, etc., etc.) electrode 8 is installed at a certain distance from the heat-conducting finned-off section 7. This sets the internal thermal resistance in the heat source zone due to the intensity of electro-convective heat transfer, at which dissipated energy g; the electrode pumping system of electrodes 4 and 5 and the heat removed from the thermostatted object; from the ribbed area to the surrounding environment. A change in the orientation of the needle corona electrode 14 and the voltage across it makes it possible to regulate the external thermal resistance of the heat-conducting portion and of the electrohydrodynamic (EDG) thermostat as a whole. The regulation of the internal thermal resistance in the heat discharge zone is carried out by moving the grid electrode 8 by bimetallic plates 9, which are bent by temperature. The approach and removal of the grid electrode 8 to the heat-conducting section 7 changes the field strength in the gap and, consequently, the intensity of the induced electroconvective heat transfer. The system of blade electrodes 4 and 5 with one insulated edge, installed in pairs in the jacket in the channels formed by dielectric partitions, allows to create directional velocity flows of the heat-transfer fluid. An even number of channels and the orientation of the electrodes in them organize the most optimal type of flow. The grid electrode, fixed on bimetallic plates, allows in the automatic mode by means of feedback to change the heat transfer in the zone of heat conduction. the water section due to the displacement of the grid electrode with variations in the temperature of the coolant. Placing the needle corona electrode of the electrode over the finned part of the heat-conducting portion allows the thermostat's external thermal resistance to be adjusted. formula 1, an electrohydrodynamic thermostat containing a thermally insulated housing, a thermostatted chamber surrounded by a jacket, filled with a dielectric liquid, and electrodes installed in the jacket connected to a power source connected to a temperature sensor, characterized in that in order to extend the range of regulation by the maximum heat flow, in it the electrodes are made with a blade and installed in pairs, than one of the edges of the electrodes is insulated a The temperature sensor is made in the form of bimetallic plates mounted on insulating plates mounted on the wall of a thermostatically controlled chamber and interconnected by a grid electrode placed in a jacket on the side of a heat conductor section made on one of the walls of A needle corona electrode connected to an adjustable high voltage source is installed. 2, Thermostat pop, 1, is different from the fact that dielectric partitions are installed in the shirt with a clear number of longitudinal channels in which blade-shaped electrodes with an insulated edge, oppositely oriented in adjacent longitudinal channels, are placed. 3.Thermostat on PP. 1 and 2, ..., which is characterized by the fact that the heat-conducting portion of the heat insulating casing is finned on the outside.

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Claims (3)

Claim 1. Electrohydrodynamic thermostat containing a heat-insulating casing, a thermostatic chamber, surrounded by a jacket filled with dielectric fluid, and electrodes installed in the jacket, connected to a power source connected to a control unit connected to a temperature sensor, characterized in that, with the purpose of expanding the range of regulation of the maximum heat flux, * 0 'in it, the electrodes are blade-shaped and mounted in pairs, with-j than one of the edges of the electrodes is isolated, and the temperature sensor The tours are made in the form of bimetallic plates 15 mounted on insulating elements fixed to the wall of the thermostatically controlled chamber and interconnected by a mesh electrode placed in a shirt from the side of the heat-conducting section, made on one of the walls of the heat-insulating casing, on the outer side of which there is a needle a corona electrode connected to an adjustable high voltage source. 2, Thermostat pop, 1, characterized in that the dielectric partitions are installed in the shirt; forming a clear number of longitudinal ⁴ channels, in which blade-shaped electrodes with an insulated edge are placed, oppositely oriented in adjacent longitudinal channels. 3. Thermostat according to paragraphs. 1 and 2 _liters of t Leach in that the thermally conductive portion of the heat-insulating casing with a ribbed outer side. Figure 2