SU777362A1 - Heat exchange ventilation system - Google Patents

Description

one

The invention relates to means of heating and ventilation and can be used to provide a microclimate in industrial buildings.

A known heat exchange ventilation system for industrial buildings containing an air-air recuperative heat exchanger, a fresh-air and four exhaust fans, and dispensing air ducts (1.

The disadvantage of such a system is the complexity of its design due to the presence of four exhaust fans.

The closest in construction to the invention is a heat exchange ventilation system comprising a heat exchanger with utilization of distribution and collecting manifolds of supply and exhaust air, fans, supply and exhaust ducts 2.

A disadvantage of the known system is the low efficiency due to the overlap of the annular space of the heat exchanger with a layer of snow-ice formed at outdoor temperatures below -10 ° C. - improving the efficiency of the invention of the heat exchange ventilation system.

The goal is achieved by the fact that the heat exchange system of the ventilation system is equipped with an additional fan connected to the exhaust air distribution manifold, and the exhaust air collector is connected to the exhaust air duct.

The drawing shows schematically the proposed heat exchange system for ventilating.

The system contains a counter-current heat exchanger-heat exchanger 1, which includes the outer 2 and inner 3 pipes-air ducts, the distribution 4 and the collection 5 of 5 cold air collectors, the distribution 6 and the collecting 7 warm air collectors; exhaust duct 8 connected to distribution 6 and collecting 7 collectors

20 warm air and equipped with hooks 9, 10 with actuators; a supply fan 11, the outlet of which is connected to the cold air distribution manifold 4,

25 main 12 and additional 13 exhaust fans, whose inlets are equipped with gates 14, 15 with actuators; the main 16 and additional 17 discharge pipes;

30 snow-ice layer thickness sensor 18 installed in the collecting manifold 7 and connected to the controller 19, the output of which is connected to the actuators of the gates 9, 10, 14, 15, as well as to the electric motors of the main 12 and additional 13 exhaust fans ; fresh air distribution duct 20 connected to the collecting manifold 5 of the heat exchanger. The discharge pipe 16 is connected to the outlet of the exhaust fan 12 ,. the inlet of which is connected to the collector 7 of the heat exchanger thermal air, and the additional exhaust pipe 17 connects to the outlet of the additional exhaust fan 13, the inlet of which is connected to the distributor 6 of the warm air of the heat exchanger.

The heat exchange ventilation system operates as follows. The main operating mode of the heat exchanger 1 is countercurrent. At the same time, the intake fan 11 supplies fresh air to the room through the manifold 4, duct pipes 3, the manifold 5 and the distribution duct 20;

The exhaust fan 12 removes the waste warm air from the room through the exhaust duct 8, the manifold 6, the air duct 2, the manifold 7 and the exhaust air outlet 16. At the same time, the gates 10 and 14 are open, the gates 9 and 15 are closed.

At external temperatures below -10 ° C, the condensate formed on the surface of the duct 3 turns into a snow-ice layer, the maximum thickness of which takes place in the zone of the collector 7, as the coolest area. When a layer of snow and ice exceeds a predetermined thickness, at the command of sensor 18, the regulator 19 turns off the fan 12, closes the gates 10 and 14, opens the gates 9 and 15, and turns on the additional exhaust fan 13. In addition, the additional exhaust fan 13 removes warm air from the room through the air duct 8, collector 7, pipe - air duct 2, collector 6, exhaust pipe 17. In this case, the heat exchanger-heat exchanger operates in the right-hand mode, the collector 7 receives uncooled air having

the temperature of the room, and the resulting snow-ice layer melts. The operation of the heat exchanger in this mode continues until the thickness of the snow-ice layer is reduced to a predetermined value. After this, the controller 19, at the command of sensor 18, stops the additional exhaust fan 13, opens the gates 10 and 14, closes the spheres; .9 and 15, turns on the main exhaust fan 12, and the heat exchanger-utilizer starts work in backflow mode again. Further, the operation of the system is repeated. Thus, the equipment of the heating system of the ventilation system with an additional exhaust fan connected to the exhaust air distribution manifold and the connection of the exhaust air collector with the exhaust air duct allow to change the snow-ice layer by changing the operating mode of the heat exchanger-utilizer heat exchanging surfaces x of the heat exchanger, as a result of which

5 system performance.

p-formula

Heat exchange ventilation system containing heat exchanger with

0 distribution manifolds of supply and exhaust air, fans, inflow and exhaust ducts, characterized in that, in order to increase efficiency, it

5 is provided with an additional fan connected to the exhaust air distribution manifold, and the exhaust air collector is connected to the exhaust air duct.

0

Information sources,

taken into account in the examination

1. Temporary instructions for the calculation and design of automated heat exchange ventilation systems for unheated stockbreeding premises. Minsk, Gosstroy BSSR, 1970, p. 27-40.

2. Instructions on the calculation and design of automated heat-battered

0 ventilation systems for utility rooms. Minsk, Gosstroy BSSR, 1972, p. 73-78, fig. 3

Claims (1)

A heat exchange ventilation system comprising a heat exchanger-heat exchanger with 30 distribution collecting collectors of supply and exhaust air, fans, supply and exhaust ducts, characterized in that, in order to increase efficiency, it is provided with an additional fan connected to the distribution manifold of the exhaust air, and collecting the exhaust air manifold is connected to the exhaust duct.