CS264749B1 - Regenerative heat exchanger - Google Patents

Abstract

Regenerative heat exchanger with air flow distribution using flaps, in which there is no mixing of exhaust air into the fresh air flow. Two rotating accumulation cartridges, made of circular plates and placed next to each other, are connected on one side to a common fresh air inlet duct and two separate exhaust air outlet ducts, and on the other side to a common exhaust air inlet duct and two separate fresh air outlet ducts, while the axes of rotation of the rotating accumulation cartridges and the axes of rotation of three planar double-winged flaps, one of which is placed between the accumulation cartridges and the other two on their outer sides, lie in the same plane and are parallel to each other.

Description

The invention relates to a regenerative heat exchanger.

A characteristic feature of the known regenerative heat exchangers with flap distribution of fresh and exhaust air is the imperfect separation of the two air streams. The mixing of the exhaust air into the fresh air stream takes place both when the flaps are adjusted, and because the accumulation charge after the exhaust air is not flushed with the exhaust air or into the open air before the fresh air flows into the ventilated space.

This drawback is remedied by the regenerative heat exchanger, which consists in the fact that two rotating accumulators formed from circular discs and arranged side by side are connected on one side by a common fresh air inlet duct and two separate exhaust air ducts and on the other side a common exhaust air inlet duct and two separate fresh air outlet ducts, with the rotational axes of the rotating accumulators and the rotational axes of the three double-leaf flaps, one of which is located between the accumulators and the other two on their outer sides lying flat and parallel to each other .

Alternate supply of fresh and exhaust air streams to two rotating accumulation charges from common inlet ducts and their removal through separate outlet ducts by means of an internal planar double-wing flap, located between rotating accumulators and two outer planar double-flap flap, parallel axis of rotation, lying in one plane, makes it possible to eliminate the mixing of exhaust air into the fresh air stream.

In the accompanying drawings, a regenerative heat exchanger is shown schematically; 1 is a view thereof; FIG. 2 is a plan view thereof and FIG. 3 to FIG. 9 shows the sequence of movement of planar double-wing flaps in the distribution of air streams.

The regenerative heat exchanger consists of two rotating accumulation cartridges 11, 2 formed of circular discs which are placed side by side. To the rotating accumulators 1, 2, a common fresh air duct 13 and two separate exhaust air ducts 4, 5 are connected from one side. On the other hand, a common exhaust air duct 6 and two separate air ducts 7, fresh air, are connected. The axes of rotation 9, 10 of the rotating accumulators 1, 2, the axis of rotation 11 of the inner planar double-wing flap 12, which is located between the rotating accumulators 1, 2 ^and ° 1 of rotation of two outer planar double-wing flaps 15, 16 are located on the outer sides of the rotating storage cartridges 1, 2 lying in a plane and parallel to each other.

The regenerative heat exchanger operates as follows. Suppose that in the basic position all three planar double-leaf flaps 12, 15, 16 form an angle of 45 ° with the positive direction of the horizontal coordinate axis (Fig. 3). In this position, the planar double-wing flaps 12, 15, 16 ensure the connection of the common fresh air inlet duct 2 through the rotating accumulation cartridge 7 to the separate fresh air duct a and at the same time connect the common inlet air duct. air.

At this stage, the fresh air, indicated by the light arrow, flows through the heated rotating storage charge J. and the rotating storage charge 2 is heated with warm exhaust air indicated by the full arrows. In the first order, the outer double-wing flap 15, which is located on the outside of the rotating storage air cooled by fresh air, starts to tilt counterclockwise.

During the tilt (FIG. 4) the separate outlet duct ^{2, the} fresh air is close, while opening the outlet duct 2 separate exhaust air.

In the extreme position corresponding to its 90 ° swivel (Fig. 5), the entire fresh air flow will be discharged to a separate exhaust air duct 4. In the second order, the inner planar double-wing flap 12 will be tilted in the same direction. During its tilting (FIG. 6), fresh air and exhaust air will be discharged together by both separate exhaust air ducts 4, exhaust air. When tilted by 90 ° to the extreme position (Fig. 7), the exhaust air flow from the common exhaust air inlet duct through the rotating accumulator charge 1 to the separate exhaust air duct 4 is restored and the heated rotating accumulator charge 2 is flushed fresh. air flowing from a common fresh air inlet duct 3 with an exiting separate exhaust air duct 5.

The outer planar double-wing flap 16, located on the outside of the flushed rotating storage charge 2, will be tilted in the same direction in the same direction. During its tilting (Fig. 8), the separate exhaust air duct 5 will close while simultaneously opening a separate outlet duct it fresh air. Upon tilting it 90 ° to its extreme position (Fig. 9), the entire fresh air flow will pass from the common fresh air inlet duct 2 through a heated and rinsed rotating accumulation cartridge 2 to a separate fresh air outlet duct 2. In the following cycle, the sequence of tilting the planar double-wing flaps 12, 15, 16 is repeated in the order described, i. j. the outer planar double-wing flap 16 will be tilted first

Claims (1)

3, 264749, the inner planar double-leaf flap 12 will lean in the same direction. During its folding (FIG. 6), fresh air and exhaust air will be discharged together by the two separate outlet ducts 4 to the exhaust air. On tilting it 90 ° to the outermost position (FIG. 7), the flow of waste air from the common intake air air inlet through the rotating storage charge 1 to the separate exhaust air outlet 4 is restored, and a heated rotating accumulation charge is flushed. 2. fresh air flowing from a common fresh air inlet air duct 3 with a separate exhaust air outlet duct 5. In the last order, the outer planar double-leaf flap 16, which is located on the outside of the rinsed rotating storage container 2, will be tilted in the same direction. During its tilting (Fig. 8), the separate exhaust air outlet duct 5 will be closed while opening the separate outlet air duct to fresh air. Accepting the tilting by 90 ° to the extreme position (Fig. 9), the entire fresh air flow will pass from the fresh air intake duct 2 through the heated and rinsed rotary accumulator cartridge 2 into the fresh air fresh air outlet duct. In the following cycle, the flip-flop sequence of the planar double-wing flaps 12, 15, 16 is repeated as described, ie, the outer planar double-leaf flaps 16 will be tilted in the first place. dampers, characterized in that a common fresh air inlet duct (3) and two separate outlet ducts (4, 5) are connected to the two rotating accumulator cartridges (1, 2) which are located one on top of the other; ) of the exhaust air, and a common exhaust air inlet duct (6) and two fresh air outlet ducts (7, 8) are connected to the other side, the rotational axes (9, 10) of the rotating storage cartridges (1, 2), the rotation axis (11 ) of an inner planar double-wing flap (12) located between the rotating storage cartridges (1, 2) and the axes Cani (13, 14) of two-leaf outer planar flaps (15, 16) disposed on the outer stranáchrotujúcich storing-cartridge (1, 2) lie in one plane and are mutually parallel. 2 drawings