SU1148134A1 - Device for temperature stabilizing of electronic device - Google Patents

Abstract

1. DEVICE FOR THERMAL STAVILIZATION OF ELECTRONIC INSTRUMENT, containing a radiator with fins located on one side of its base, an element of thermal stabilization and a heat-removing plate for accommodating an electronic device, installed — on the basis of a radiator with the possibility of thermal contact with an element of thermal stabilization; e with the fact that, in order to increase the efficiency of the device, it is equipped with a flexible shell, one end surface is hermetically connected to the base of the radiator, and the other - with a plate to accommodate the electronic device, and the elements of thermal stabilization of the electronic device are made in the form of sealed tanks with a membrane and a spring-loaded rod and fixed to the base of the radiator on the side of its fins, and on the one side of the membrane part of the tank is filled with water, and on the other side is placed a spring-loaded rod connected by one the end with the membrane, and the other through the through-hole, which is at the base of the radiator, (L with a heat sink plate. 2. The device according to claim 1, characterized in that the flexible shell is made in the form of bellows.

Description

four

sc

00

4 1tU The invention relates to electronic technology and can be used to maintain the temperature of electronic devices operating in the conditions of the external atmosphere or unheated premises in the electronics industry, radio construction and communication equipment. A device for cooling an electronic device is known, which comprises a panel, having at least one through-hole and embedding tij elements on one of its sides. However, being constantly in direct contact with the electronic device, the device removes heat from it as at a positive ambient temperature, protecting it from overheating, r & and at negative temperature, when the need to remove heat from the electronic device disappears. In the latter case, it is possible to reduce the temperature of the electronic device to a temperature at which the device becomes inoperable. This forces to maintain the temperature of the electronic device at a negative ambient temperature, to use a heating device that maintains the positive temperature of the electronic device under the conditions of negative ambient temperatures, which leads to additional consumption of energy consumed. It is also known a device for maintaining the temperature of an electronic device, comprising a radiator with heat exchanging ribs on one side of its base, an element for maintaining temperature and a heat removing plate for accommodating the electronic device, while the element for maintaining temperature is in the form of a heater {2. The drawback of the device is a large power consumption, since most of the heat generated by the heater disperses unhindered into the environment, since the heater is in direct thermal contact with the heat transfer elements of the device through which heat is transferred to heat transfer elements. The purpose of the invention is to increase efficiency by reducing energy consumption. This goal is achieved by the fact that the device for thermal stabilization of an electronic device, containing a radiator with fins located on one side of its base, an element of thermal stabilization and a heat removing plate for accommodating an electronic device, mounted on the basis of a radiator with the possibility of thermal contact with a thermal stabilization element, is equipped with a flexible shell, one end surface is hermetically connected to the base of the radiator, and the other - with a plate for placing an electronic device, and The thermostabilization cops of the electronic device are made in the form of sealed tanks with a membrane and a spring-loaded stem and are fixed on the base of the radiator on the side of its fins, on one side of the membrane part of the tank is filled with water, and on the other hand a spring-loaded stem is connected to one end of the membrane, and the other through a through hole made at the base of the radiator with a heat sink plate. In addition, the flexible shell is made in the form of bellows. FIG. 1 shows a device for thermal stabilization of an electronic device, with a positive ambient temperature, a section; on ig. 2 - the same, when the ambient temperature is negative (its environment. A device for maintaining the temperature of an electronic device contains a radiator 1 s completed by & w on one of its sides by fins 2, a thermal stabilization element, a heat sink plate 3 for accommodating an electronic device, a flexible shell (bellows ) 4, while at the radiator t there is at least one through hole 5, and the thermal stabilization element contains at least one sealed water tank 6 fixed to the base side of the radiator 1 with ribs 2 and having a membrane 7 mounted therein and separating a cavity 8 for water therein, a spring-loaded rod 9 connected by one End to membrane 7, and through a scy 5 in the base of radiator 1 - the other end with a plate 31 3 for placing an electronic device, the bellows 4 is tightly connected with one end surface to the base of the radiator 1 and the other to the heat sink plate 3 for accommodating the electronic device. The surfaces of the radiator 1 and the plate 3 for accommodating the electronic device facing each other are processed in a manner consistent with ivayuschim their tight fit for conductus hydrochloric heat transfer at a positive temperature environment and high reflectivity at break in thermal contact conditions affecting negative ambient temperature. Depending on the size of the electronic device (s), it is possible to install several tanks to eliminate possible distortions and create large forces when the thermal contact is broken. In Figures 1 and 2, an electronic device is conventionally shown by a dash-dotted line. The device works as follows. A cavity 8 for water is completely filled with water. At a positive temperature of the surrounding medium (see Fig. 1), the radiator 1 and the plate 3 of the raft are pressed against each other by means of a spring-loaded rod 9, which ensures uninterrupted heat transfer in a conductive manner from the electronic instrument 10 through the plateless 3 and radiator 1 to the ribs 2, and then to the environment. When the ambient temperature drops below zero (see Fig. 2), water in cavity 8 freezes and takes up a larger volume after phase transition to a solid state. In this case, the membrane 7 is curved and, acting through the spring-loaded rod 9 on the heat-conducting plate 4, moves it in the direction from the radiator i. As a result, the thermal contact of plate 3 with radiator 1 is broken and between the radiator, a plate and bellows forms an airtight cavity, full of rarefied air, and the conductive form of heat transfer is replaced by heat transfer by radiation and by convection, which ensures a sharp reduction in heat transfer from the electronic device through heat transfer elements in a circulating medium, and this allows the heat emitted by the device to be used for self-heating, which, in turn, reduces energy consumption. When the ambient temperature changes from negative to positive, the heat-conducting plate returns to its original state, while the ice in the reservoir turns into water, water tends to occupy the original volume, and the spring moves the rod in the opposite direction and tightens the heat sink plate on it with an electronic device before direct contact with the radiator. If the heat provided by the device is not sufficient for self-heating at a negative ambient temperature, it is possible to use a heating device, but its power and, consequently, power consumption is much less than in the prototype. The proposed device, in comparison with the prototype device, reduces energy consumption by using the heat energy allocated by an electronic device to heat it at a negative ambient temperature, since the presence of a reservoir with a membrane and a spring-loaded stem creates a break in the thermal contact between the plate and the radiator, and the presence hermetic cavity with rarefied air formed by a radiator, a plate and a flexible sheath provides low heat transfer from the electronic instrument RA through the heat-transfer elements in the environment. Reducing power consumption results in lower operating costs.

Claims (2)

1. DEVICE FOR THERMAL STABILIZATION OF AN ELECTRONIC INSTRUMENT, containing a radiator with fins located on one side of its base, a thermal stabilization element and a heat sink plate to accommodate an electronic device, mounted on the base of the radiator with the possibility of thermal contact with the thermal stabilization element, distinguishing with the fact that, in order to increase the efficiency of the device, it is equipped with a flexible shell, one end surface hermetically connected to the base of the radiator, and the other with a plate for size the compartment of the electronic device, and thermostabilization elements of the electronic device are made in the form of sealed tanks with a membrane and a spring-loaded rod and are mounted on the base of the radiator from the side of its ribs, and on one side of the membrane part of the tank is filled with water, and on the other hand there is a spring-loaded rod connected by one the end with a ^ membrane, and the other through a through hole made in the base of the radiator, with a heat sink plate. 2. The device according to claim 1, characterized in that the flexible shell is made in the form of a bellows.