SU1536166A2 - Installation for utilization of heat energy - Google Patents

Abstract

The invention relates to a technique of ventilation and air conditioning. The aim of the invention is to prevent the exhaust air heat exchanger from freezing at negative supply air temperatures. The installation for utilization of thermal energy contains supply and exhaust air ducts 1 and 2 with heat exchangers 3 and 4. The tank accumulator 5 is filled with heat accumulating substance to form gas space 7 and has additional movable heat exchangers 8 and 9 connected by circuits of the intermediate heat carrier respectively to heat exchangers 3 and 4 with the possibility of simultaneous opposing movement relative to each other in the storage tank 5 and changing their degree in the gas space 7 it. 2 Il.

Description

The invention relates to techniques for ventilation and air conditioning and is an improvement on the invention by ed. No. 1455161.

The purpose of the invention is to prevent freezing of the exhaust air heat exchanger at negative temperatures of the supply air.

Figure 1 presents a schematic diagram of an installation for the utilization of thermal energy; figure 2 - view And figure 1 "

Installation for utilization of thermal energy contains supply and exhaust ducts 1 and 2, in which heat exchangers 3 and 4 are located.

The storage tank 5 is filled with heat-accumulating substance 6 with the formation of a gas space 7 and has additional movable heat exchangers 8 and 9 connected respectively to the supply air heat exchanger 3 and the exhaust air heat exchanger 4.

The hydraulic cylinder 10 with the rod 11 is hydraulically connected to the tank 12 with a heater 13 filled with a liquid with a high coefficient of thermal expansion.

The additional heat exchanger 8 is connected with the rod 11 of the hydraulic cylinder 10, and the additional heat exchanger 9 connected to the exhaust air heat exchanger 4 is kinematically connected with the rod 11 of the hydraulic cylinder 10 with the possibility of simultaneous opposed movement relative to the other additional heat exchanger'8 and alternately changing the degree of finding additional heat exchangers 8 and 9 in the gas space 7 of the storage tank 5.

The additional heat exchanger 9 can be kinematically connected with the additional heat exchanger 8 by means of a mechanism consisting of a lever 14, a sleeve 15, a housing 16, a piston 17, a spring 18 and a cup 19 (FIG. 2).

Supply and exhaust ducts 1 and 2 are connected to room 20.

The installation for the utilization of thermal energy works as follows.

Warm exhaust air is taken from the room 20 through the exhaust duct 2, giving off heat to the intermediate heat medium circulating in the heat exchanger 4.

The heated intermediate heat carrier then passes through the heater 13 to the additional heat exchanger 9 of the storage tank 5, where it transfers heat to the accumulating substance 6. Heat is transferred from the heat storage substance through the additional heat exchanger 8 to the intermediate heat medium circulating in it.

The intermediate heat carrier heated in the optional heat exchanger 8 then enters the heat exchanger

3, in which the supply air is heated.

In the transition period, with an excess of heat in the room 20, an increase in the temperature of the exhaust air in the duct 2 occurs, which causes a corresponding increase in the temperature of the intermediate coolant and an increase in the temperature of the liquid in the tank 12. A corresponding increase in the volume of liquid and its flow into the hydraulic cylinder 10 causes the rod 11 of the hydraulic cylinder 10 to move upward and kinematically associated with an additional heat exchanger 8, while reducing the surface area of the contact of the heat exchanger 8 with heat-accumulating substance 6 ohms and a heat exchanger outlet 8 increases in gas space 7 of the storage tank 5.

Thus, the amount of heat transferred to the intermediate coolant circulating in the heat exchanger 8 from the heat-accumulating substance 6 is reduced.

As a result of lowering the degree of heating of the intermediate coolant in the additional heat exchanger 8, a corresponding decrease in the amount of heat transferred in the heat exchanger 3 to the supply air, which then flows into the lower temperature room 20, which generally compensates for the increase in heat surplus in the room 20.

In the cold season, when the supply air temperature becomes negative, the temperature _{t of the} intermediate heat carrier circulating between the heat exchangers 3, 8 and

4, 9 is reduced and there is a danger of freezing of the exhaust air heat exchanger 4.

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When the temperature of the intermediate coolant in the heat exchangers 4 and 9 reaches a value corresponding to the possibility of freezing of heat. Mennik 4 _? there is a corresponding decrease in the volume of liquid located in the tank 12 and the hydraulic cylinder 10 and the flow 11 of the hydraulic cylinder J.0 is lowered, etc., and this additional heat; q exchanger 8 is more immersed in the heat-storage substance 6 of the storage tank 5

At the same time, there is a decrease in the degree of finding the additional 15 heat exchanger 9 in the heat-accumulating substance 6 of the storage tank 5 when it is moved up.

As a result of reducing the area 20 of the contact surface of the heat exchanger 9 with the heat-accumulating substance 6, the amount decreases

6 heat transferred from the exhaust air side, and increase to the required temperature level circulating between the heat exchangers 4 and 9 of the coolant, which eliminates the possibility of freezing of the heat exchanger 4.

Claims (1)

Claim Installation for utilization of thermal * energy according to ed. No. 1455161, characterized in that, in order to prevent freezing of the exhaust air heat exchanger at negative temperatures of the supply air, an additional heat exchanger connected to the exhaust air heat exchanger is kinematically connected to the rod; a hydraulic cylinder with the possibility of simultaneous opposed movement relative to another additional heat exchanger.