SU553413A1 - The method of thermal stabilization of the object - Google Patents

Description

environment. The graph illustrates the advantages of the proposed method in comparison with the known. In the case of a temperature gradient between the object and the environment, a change in the value of thermal conductivity (curve 1) is provided by the thermopile when the power supply is on. At the required temperature level, the value of which, for example, is lower than the ambient temperature, the thermopile is switched to the "heat generator" mode, i.e. the negative heat transfer mode (section 1-2), while the object is heated to the required temperature of statisation.

In order to reduce heat leakage to the temperature-controlled object (section 2-3) as the temperature of the object increases, when it is put into operation, the current of the power supply of the corresponding polarity is reduced. When the temperature at which the heat emitted by the object begins to prevail over the heat removed by solid heat from the radiators of the battery, the latter switches to the mode of the cold generator, i.e., to the mode with positive thermal conductivity (section 3-4).

The heat removal process is carried out until the maximum cooling capacity of the thermopile is reached (point 4). Changes in the thermal conductivity of the object-thermopile system and temperature, according to curve 1, are equal to Ki K4 - (- K2) and Ti T4-TI, respectively.

Since the ambient temperature, as well as the temperature-controlled object, can vary over a wide range, the heat removal only by a thermopile is inefficient. When a thermopile is connected to a massive body, the thermal resistance of the system "object - thermopile - medium" decreases, i.e. the thermal conductivity of the system on curve II in the initial state will be greater than in the case of curve I (point 5). Due to the low thermal resistance of the system with the same thermopile supply current in the mode of "negative thermal conductivity, the object receives a greater amount of heat, as the heat sink to the cold side decreases, due to the almost constant temperature of the massive body (point 6). As a consequence, the decrease in thermal conductivity, depending on the temperature of the surrounding medium, will be carried out along a flatter curve (segment 6-7). When the thermal equilibrium is reached, the thermometer is turned off and the system returns to the initial thermal conductivity (point 8), after which the thermostating process proceeds without additional costs.

0 energy (cut 8-9).

The thermostating process proceeds (segment 8-9) until the moment when the thermal resistance of the system: “the thermostatting object — the thermopile — the massive body — the environment cannot maintain the temperature of the object at the required level.

At this moment, the thermopile is switched on in the mode of the "cold generator" in the mode of positive thermal conductivity (segment 9-10). When the maximum cooling capacity is reached, the system loses the possibility of thermostating the object. Maximum change in thermal conductivity

5 systems, as well as the temperature is:

(-K6)

ATii Tio-tb So

Claims (1)

1. Copyright certificate number 333645, H 01V 1/02, 1970. Oj / 7