DE2947432A1 - Air-to-air heat exchanger - comprises flat heat conductive elements between fresh and stale air passages - Google Patents

Abstract

The heat exchanger has fixed surfaces transmitting sensible heat, and is mounted between an air inlet and outlet passage so as to recover heat from the stale air, e.g. in a private house. The exchanger (1) comprises a large number of adjacent flat heat-conductive elements extending in the direction of the air currents and forming partitions which are airtight and heat- conductive and connected together. Thus two separate air passages (3,4) for fresh and stale air, are formed by them. The exchanger can be in one piece and of copper sheet in a meander pattern.

Description

Uwe Klix 721 Rottweil, November 15, 1979

Eisenbahnstrasse 16

Heat exchangers, their design and arrangement in a facility for heat recovery through air exchange, especially for Residential houses and comparable facilities.

The invention relates to heat exchangers with fixed exchange surfaces Transfer of sensible heat as well as its formation and arrangement in Facilities with a supply air and an exhaust air lock, between which such heat exchangers can be arranged for the largest possible Heat recovery that is higher in temperature than the supply air and in the opposite one Direction of flowing exhaust air, especially for use in residential buildings and comparable systems.

The known such heat exchangers and their design and arrangement in a device for heat recovery, the highest possible Have a degree of heat recovery, use the so-called countercurrent process or the, somewhat lower degree of heat recovery, so-called cross-flow process. With both methods, the two air mass flows, the supply air and the exhaust air flow, are passed through one solid wall separated from each other, through which the heat transfer takes place.

The known institutions using these two methods are however, for the arrangement for use in residential buildings or similar Systems so far have been extremely complex, spatially large and relatively expensive.

The invention is based on the object using in particular to create so-called plate heat exchangers using the countercurrent process, those in a supply air aortic duct with a spatially relatively small one Arranged cross-section, the two air mass flows separate such that the largest possible surface adjacent to the two air mass flows this is opposed to achieving the greatest possible degree of heat recovery. It should be ensured that one or more such heat exchangers are arranged in a shaft-like air lock

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can uierden. In addition, it should be ensured that the air locks, in particular using standardized, commercially available pipe elements, built up, equipped with a heat exchanger and installed A further object of the invention is that heat exchangers of this type can be manufactured in a technically simple manner as well as efficiently and economically are.

These objects are achieved according to the invention in that such heat exchangers from a plurality of mutually adjacent and in the direction of Air mass flows of running, heat-conducting surface elements are formed, which are arranged there in the air mass flows and in the manner of a partition are connected airtight to one another, so that two shaft-like inlet and exhaust air locks, formed at least by the surfaces of a heat exchanger and separated from one another, are created.

Such heat exchangers can in particular be made in one piece Sheet copper or another, sufficiently thermally conductive, material, in particular folded in a meander-like manner, in particular produced in a self-supporting manner be and either directly penetrating a mounting or installation wall or indirectly guided by a particularly commercially available plastic pipe, penetrating a wall for air exchange of the interior air Exhaust air equal to outside air equal to supply air with simultaneous heat recovery of the exhaust air installed at a higher temperature than the supply air be. The side walls of the air locks for the supply air and the exhaust air can in particular exclusively from the side surfaces of a specially shaped heat exchanger be formed. However, it is also possible there that some of the side surfaces can also be formed by a so-called support tube made of plastic, which also supports the whole Facility can be.

In a further development of the invention it is provided that there directly in the area of the heat exchanger, especially installed in a support tube, Fans can be provided that per airlock directly

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can be arranged in the Trag-Rahr by desueiteren also if necessary so-called bypasses can be provided for each air lock.

Furthermore, it is thought according to the invention that the, in the direction the air mass flows running, heat-conducting surface elements of such Heat exchangers move in the direction of the air mass flows per lock narrow each spatially, so that before the air outlet from the respective Lock a so-called backwater or turbo effect in the jeueiligen Air locks are created to improve and increase the degree of heat recovery .

How the invention is intended in detail will be different on hand Embodiments explained in more detail. Show it

1 shows a cross section through a meander-like shaped heat exchanger arranged in a square tube,

Fig. 2 shows a cross section through a meandering shaped, laterally indirectly guided heat exchanger arranged in a square tube,

3 shows a cross section through a sawtooth-shaped heat exchanger arranged in a square tube,

Fig. 1 * shows a cross section through a meandering shaped heat exchanger arranged in a circular cylindrical tube,

5 shows a cross section through an endlessly corrugated heat exchanger arranged in a circular cylindrical tube,

6 shows a longitudinal section through a pipe arrangement with a heat exchanger arranged there according to one of FIGS. 1 to 5,

Fig. 7 is a view of a pipe arrangement according to FIG. 6 on one of the Sides with an air inlet or air outlet duct,

Fig. Β is a longitudinal section through a pipe arrangement with one of the previous ones Heat exchangers with assigned by-passes with air inlet bzui directed parallel to one another. Air outlet ducts, '

9 shows a longitudinal section through a pipe arrangement with one of the previous ones Heat exchangers with assigned by-passes and to each other

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opposing air inlet or air outlet ducts, 10 shows a cross section through a meandering hollow body heat exchanger arranged in a square tube and 11 shows a longitudinal section through a heat exchanger design with, Heat exchanger surfaces directed like a nozzle towards the respective air outlet.

Fig. 1 shows a meandering shaped heat exchanger 1 made of a thermally conductive sheet, for example made of a copper alloy, which extends coaxially and can be spatially of any length and is arranged in a pipe 2 that there the pipe cross-section is coaxially divided, in particular in two, so that two, Completely separate, chamber-like, coaxially extending locks 3 and ι * are formed. The lock 3 can be provided for the supply air and the lock k for the exhaust air transport. A surface of the heat exchanger 1 that is relatively large for the respective air lock cross section is adjacent to the two air mass flows running in opposite directions. The pipe 2 can be thermally insulated from the outside and consist of a standard plastic pipe that conforms to the standards. However, it can also be made of any other material than plastic, if this should be advantageous.

Such a heat exchanger 1 can expediently have any shape beyond the embodiment shown. What is essential is his Surface that separates the two air mass flows over a large area. This means that the two air mass flows should ideally only come from the surfaces of the heat exchanger.

According to the embodiment according to FIG. 2, the heat exchanger 1 is laterally delimited and guided in the area of the meander reversal radii by an axially extending guide element 5, which is particularly poorly thermally conductive or thermally insulated, so that the air mass flows in the respective locks 3 and h predominantly only come from the surfaces or Side surfaces of the heat exchanger 1 are performed. 2 shows the actual support tube of the device

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3 shows a sawtooth-shaped heat exchanger 1 in one Tube 2, where in turn the two chamber-like longitudinal locks and U for guiding the two air mass flows through the heat exchanger are shared with each other.

Fig. U shows a shape of the heat exchanger 1, for its arrangement in a tube 2 with a circular cross-section. With the present shape and arrangement of the heat exchanger 1 in the tube 2, a particularly large-area design of the heat exchanger relative to the remaining inner surface of the tube 2 is achieved. 3 and U again show the two coaxially extending chamber-like locks for guiding the two air mass flows.

In Fig. 5, the heat exchanger 1 is made of a radially extending corrugated, in particular endlessly manufactured sheet metal part running coaxially to the tube 2.

The heat exchangers 1 described in the preceding figures can be arranged relatively easily, in particular in a pipe system, as FIG. 6 shows. There it can be seen how the heat exchanger 1 can be arranged in one of the shapes described above to run coaxially in a tube 2 in such a way that two chamber-like, coaxially extending sluices 3 and U are formed, which are hermetically separated from one another, for guiding the two air mass flows , the exhaust air flow a 5 and the supply air flow 6, if 7 denotes the outside air area and B denotes the inside air area, and 9 represents a wall separating the two air areas, in particular of a residential building or a comparable system. There, the inside air, which is relatively higher in temperature than the outside air, is to be exchanged, with the greatest possible part of the thermal energy contained in the inside air being directly recovered via the heat exchanger 1 by heating the supply air supplied from the outside air area 7.

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The pipe 2 arrangement can be designed there in such a way that it is made from customary, standards-compliant plastic tubes and joined together. The straight pipe section penetrating the wall can be assigned a 90 T-piece on both sides · This arrangement with a heat exchanger in between guides the two air mass flows running parallel to each other in an excellent manner, with an influence on the respective inlet and outlet openings or channels ^ being opposite to each other, is avoided. To promote and, if necessary, regulate the A fan 10, which can be regulated if necessary, can be provided for each lock for the respective air mass flows.

In Fig. 7 it can be seen how the heat exchanger 1 in the tube 2 or on the walls of the end T-pieces rests with its end faces and can be hermetically sealed. 11 denotes there on the front side Heat exchanger 1 provided sealing sleeves on the inner wall the T-pieces are in contact. 9 shows the separator.

The apparatus of Fig. 6, according to Fig. Θ with, extending on both sides to the air locks of the heat exchanger 1 coaxially, further air locks 12 and 13, so-called by-passes be provided continuously adjustable to-the particular special control flaps% and are switched off .

Another such training and arrangement of a device for Heat recovery is shown in FIG. 9. The difference to FIG. Β is that the FIG. Θ H-shaped design is equipped with an air outlet or inlet running parallel or in the opposite direction and the embodiment according to FIG. 9 facing away from one another air outlet or - has inlet channels. 11 denotes sealing collars there in each case between the heat exchanger 1 and the pipe 2 inner walls or by-pass walls.

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According to FIG. 10, a heat exchanger 1 can also be formed from a hollow body, in the interior of which a medium, in particular in liquid form Shape can completely or partially dissipate the recoverable heat, in particular in a controllable manner. This medium can in particular be part of a Liquid or gas circuit of a heat pump, i.e. it can be a Be coolant. This makes it possible to reduce the degree of heat recovery if necessary to increase significantly bzui. to control.

A further improvement of the degree of heat recovery is possible according to an embodiment according to FIG. 11, where the heat exchanger 1 is designed in such a way that at the respective, opposite exit point of the locks 3 and U, these locks narrow there like a nozzle, so that a so-called backflow or turbo effect arises.

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Claims (1)

- X- Claims 1.1 Heat exchangers with fixed exchange surfaces for the transfer of sensitive Heat as well as its design and arrangement in facilities, with a supply air and an exhaust air lock, between which such heat exchangers isind
arranged; for the greatest possible heat recovery of the exhaust air, which is higher in temperature to the supply air and flowing in the opposite direction, in particular for use in residential buildings and comparable systems, characterized in that the heat exchangers (1) are made up of a large number of adjacent and in the direction of the air mass flows running, heat-conducting surface elements are formed, which are arranged in the air mass flows like a partition wall and are connected to one another in an airtight and heat-conducting manner, so that two shaft-like air locks (3 and k) formed at least by the surfaces of a heat exchanger (1) and separated from one another are created will. 2. Heat exchanger according to claim 1, characterized in that the heat exchanger (1) is made in one piece from sheet copper meander formed · 3. Heat exchanger according to claim 1, characterized in that the heat exchanger (1) Shaped like a meander, closed in a ring, endless and one-piece is made. 1". Heat exchanger according to Claims 1 to 3, characterized in that the Two-walled heat exchanger (1) inside, forming a cavity for receiving and guidance in particular of a liquid or gaseous medium for energy transport and / or transmission is established. 5. Heat exchanger according to claims 1 to 4, characterized in that the heat exchanger (1) running in the direction of the air mass flows to the respective, opposite exit point, the air locks (3 and k) narrowing like a nozzle to achieve a so-called 130022/0562 ORIGINAL INSPECTED Turbo effect is formed in the air locks (3 and k) 6. Heat exchanger according to claims 1 to 5, characterized in that the heat exchanger (1) is built into a commercially available plastic pipe (2) and that sealing collars (11) are provided at the front between the heat exchanger and the pipe wall and, if necessary, coaxially running laterally between the heat exchanger (1) and the pipe inner wall ) are provided for hermetically sealing the two locks (3 and k) to one another. 7 · Heat exchanger according to claim 1 to 6, characterized in that the, Heat exchangers (1) built into a pipe (2) at the two pipe exit points, which are opposite one another, with T-shaped pipe ends is provided for the opposite spatial separation of the both air mass flows, specifically the supply air and the exhaust air B. Heat exchanger according to claim 1 to 7, characterized in that running parallel to the two air mass locks (3 and U) additional air locks (12 and 13), so-called by-passes, are provided, and that the air locks (12 and 13) and the locks (3 and U) can be switched on and off continuously via control flaps (1i *). 9. Heat exchanger according to claim 1 to Θ, characterized in that the air locks (3 and U) and / or (12 and 13) are each equipped individually or together with fans (10) for transporting the air masses. 130022/0562