CH658119A5 - VENTILATION DEVICE FOR A ROOM WITH TWO SEPARATE FLOW PATHS FOR VENTILATION AND VENTILATION. - Google Patents

Description

The present invention relates to a ventilation device for a room with two separate flow paths for ventilation in an elongated cuboid housing, which are operatively connected to one another for recuperative heat recovery from the ventilation air flow via a heat exchanger enclosed in the housing and with inevitable air delivery in the two flow paths by a radial blower, this radial blower with its impeller divided by a radial partition into two independently conveying halves protruding into both flow paths, and with the two halves of the impeller being assigned an air inlet on axially opposite sides of the housing, while there are two end chambers each having an air outlet and separated from one another by an installation body in the length region of the housing adjoining the heat exchanger.

It is known to use self-heating fans in order to preheat the incoming air entering the building without using external energy through multiple use of the enthalpy of the exhaust air leaving the building. In these self-heating fans, supply air and exhaust air flow past each other in channels in opposite directions, the two flow paths being separated from each other only by a thin sheet. These self-heating fans act as recuperative heat recovery units. They are constructed in such a way that they can be operated with different working methods for summer and winter operation.

Practical experience has shown that self-heating fans of such a simple design can be used in winter operation

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heat recovery from the exhaust air and transfer of the return heat to the outside or supply air can be achieved, which accounts for at least 30% of the thermal energy contained in the exhaust air.

In the known self-heating fans, the air is conveyed by two fans driven by a common motor, the fan taking over the supply of air in winter being designed as a radial fan, while the fan used to convey the exhaust air is formed by an axial fan.

For summer operation, the self-heating fans can be converted so that both fans can handle the extraction of exhaust air together.

The structure of the self-heating fans is such that both fans (radial blowers and axial blowers) are located at the end of the two flow paths on the room side, such that the fan (radial blower) that takes over the supply of air during winter operation has to overcome a long suction path, but a short pressure path has, while vice versa, the ventilating fan (axial fan) has a short suction path, but must overcome a long pressure path.

Another ventilation device, which has become known from DE-OS 2 717 462, is constructed in such a way that one and the same radial fan with its impeller and its fan housing protrudes into both flow paths, with a spatial separation between the two flow paths both within the impeller and also outside the impeller in the blower housing is formed by transverse walls. Here, the fan wheel, the transverse walls and the fan housing are made of a highly conductive material, for example sheet metal, and the fan wheel can be designed as an additional heat exchanger between the two flow paths by being equipped with fan blades that are continuous throughout its length.

In this known ventilation device, the partition wall provided in the fan housing protrudes with its inner boundary edge into a gap between two partition walls of the impeller which are spaced apart in the axial direction, so that practically only the blading of the impeller has the effect of a heat exchanger, during which both partition walls are necessary due to the function gap between them cannot participate in the heat exchange. In order to nevertheless achieve a reasonably good heat exchange, the impeller blades are either provided with so-called heat pipes, or else they are designed as hollow bodies in which a refrigerant, for example Frigen, is enclosed. However, it is obvious that a ventilation device with such a radial fan requires considerable technical effort.

However, a disadvantage of this known ventilation device is that a complete separation between the two flow paths is brought about by the partition wall of the fan housing protruding into the gap between the two partition walls of the fan wheel, so that moisture exchange between the two air streams cannot take place and thus one Impairment of heat recovery results.

In the ventilation device according to DE-OS 2 717 462, the radial fan, which projects into both flow paths with its impeller and also acts as a heat exchanger, also works together with a main heat exchanger. One half of the radial fan is on the suction side with one flow path of the main heat exchanger and the other half of the radial fan is on the pressure side with the second flow path of the main heat exchanger.

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Heat exchanger in connection and the latter is designed for operation according to the counterflow principle. As with the known self-heating fans mentioned at the outset, the disadvantage of the ventilation device according to DE-OS 2 717 462 is that the two halves of the radial fan have reversed operating conditions relative to the main heat exchanger, so that they have the same construction have different air flow rates relative to the main heat exchanger.

The aim of the invention is to create a ventilation device for rooms of the generic type which, with little technical effort, enables a noticeably improved multiple use of the enthalpy of the exhaust air flow leaving a room and accordingly a higher heat recovery, but at the same time also ensures that the simultaneous air supply radial blowers serving in both flow paths have practically identical conveying capacities for both flow paths.

The ventilation device according to the invention is characterized by the features of the characterizing part of patent claim 1.

From the magazine "techno-tip", Volume 10, No. 6 from June 1980, page 10, it is known to install a heat exchanger for heat recovery in ventilation systems that is designed in a cross-flow or cross-flow design and has zigzag consecutive length sections in the flow direction, each of which has a channel-free deflection area between two exchanger areas which are successive at an acute angle and which are formed by sheet metal channel stacks. In this case, too, the ventilation air flow and the ventilation air flow are guided through the heat exchanger in opposite directions, and in order to achieve the same air flow rates in the opposite directions, the supply air fan and the extract air fan are each assigned to the opposite ends of the heat exchanger.

The supply air fan and the extract air fan can therefore not be operated as an additional heat exchanger. The ventilation device according to the invention has the essential advantage over the previously known ventilation devices that it can not only be produced with little technical effort, but at the same time also enables a compact construction. It has also proven to be advantageous that the radial fan, which acts as an additional heat exchanger, works in a chamber common to both air streams in the area of the greatest temperature differences, namely in the common inlet area for the exhaust air stream and the outside air stream, because in addition to an optimal heat exchange there is also a good air humidity exchange can take place without there being any noticeable impairment with regard to the separation of the two air streams before they enter the heat exchanger.

A particularly simple constructional development of the ventilation device can be achieved according to claim 2 in that the insert body delimiting the chamber of the radial fan consists of sound-absorbing material, for example foam plastic or foam rubber. In this case, according to claim 3, on the insert body on one side there is a holding plate arranged inside the housing, to which the stator of the radial fan is fastened, the insert body being fixed in the housing by the holding plate.

It would also be advantageous according to claim 4 if the impeller and its partition made of a good heat-conducting material, e.g. Copper sheet, exist and the surfaces of the

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Insert body with a film made of thermally conductive material, e.g. Copper or aluminum foil are covered in order to form an additional heat exchanger between the two flow paths over the two halves of the radial fan.

The optimal exchange of air humidity between the exhaust air flow and the outside air flow is particularly useful if, according to claim 5, the apex edge of the plate stack closest to the radial fan is at a distance from the fan wheel, while for reliable separation of the supply air flow from the exhaust air flow, the apex edge of the plate stack most distant from the fan wheel is located directly adjoins the longitudinal partition located between the two end chambers. A particularly expedient and simple configuration for the heat exchanger is obtained if, according to claim 6, a plurality of adjacent, cross-sectionally C-shaped individual plates in each plate stack alternately form first air flow paths and second air flow paths, the second air flow paths extending transversely to the first air flow paths and are separated from them.

According to claim 7, the stack of plates can be arranged between two side plates and fixed in position against rotation by cross-connecting rods acting on their corner regions.

In order to optimize the operation of the ventilation device, the heat exchanger between soundproofing coverings, e.g. made of foam plastic, the longitudinal walls of the housing.

A secure separation between the two flow paths in the area of the heat exchanger can be achieved according to claim 9 in a simple manner if the apex edges of the plate stack reach as far as the soundproofing coverings. So that the ventilation device can be operated in summer without heat recovery effect between the supply air flow and the exhaust air flow, it has proven to be expedient if at least one actuator is arranged between at least one of the two longitudinal walls and its soundproofing covering, as a result of which the distance between the soundproofing covering and the Vertex edges of the plate stack is adjustable and the deflection areas between the plate stacks can be brought into flow connection directly with one another. Since the outside air and the exhaust air within the housing move through the heat exchanger in the same direction, but in a cross-flow or cross-flow, a short circuit between the two air flows is created when the longitudinal wall is removed from the apex edges of the plate stack, which causes mixed-air operation of the ventilation device between the exhaust air and the outside air. If only the longitudinal wall of the housing facing the interior is made variable in relation to the apex edges of the stack of plates, there is a short-circuit connection between the two air streams in such a way that the greater proportion of the air volume conveyed jointly by both halves of the radial fan through the supply air opening in the interior of the room is conveyed, while the smaller part of the air exits through the exhaust air opening.

It is particularly expedient if, according to claim 11, the actuator is a regulating plate which is movable, for example displaceable, pivotable or foldable, transversely to itself.

Finally, it is also expedient if, according to claim 12, the regulating plate is actuated, e.g. Actuators that can be actuated.

Exemplary embodiments of the ventilation device according to the invention are described below with reference to the drawing.

1 shows an overall ventilation view of a ventilation device according to the invention seen from the room side,

FIG. 2 shows an overall spatial view of the ventilation device according to FIG. 1, but viewed from the outside,

3 shows a horizontal section along the line III-III in FIGS. 1 and 2,

Fig. 4 shows a vertical section along the line IV-IV in Fig. 3,

Fig. 5 shows a section along the line V-V in Figs. 3 and 4,

Fig. 6 shows a section along the line VI-VI in Figs. 3 and 4,

7 shows a section along the line VII-VII in FIGS. 3 and 4,

8 shows in a spatial representation a plate stack of the main heat exchanger shown in FIGS. 3 and 4,

FIG. 9 shows a representation corresponding to FIG. 8 of a plate stack for the main heat exchanger with a modified design of the individual plates,

FIG. 10 shows a horizontal section corresponding to FIG. 3 through a modified embodiment of a ventilation device and

FIG. 11 shows a section along the line XI-XI in FIG. 10.

1 and 2 show that the ventilation device for ventilating rooms has an elongated, rectangular housing 1, which consists of a channel profile 2 which is essentially U-shaped in cross section, a front profile 3 which closes the open longitudinal side thereof, and two end plates 4 and 5 are composed.

While the end plates 4 and 5 can be fixedly connected to the channel profile 2 or at least difficult to detach, it is advantageous to releasably attach the front profile 3 to the channel profile 2 so that the interior of the housing 1 can also be made accessible from the room side. if it is fixed to a wall or window.

The channel profile 2 and the front profile 3 of the housing 12 can consist of light metal, while the end plates 4 and 5 are preferably made of plastic.

In its wall part 6 forming the profile web, the channel profile 2 has an air passage 7 or 8 in the vicinity of its two ends, which can have, for example, a round or rectangular outline shape. On the other hand, the front profile 3, also in the vicinity of its two ends, is each equipped with an air outlet grille 9 or 10.

The air outlet grilles 9 and 10 can expediently be opened and closed as needed with the aid of sliders or pressure plates of known design which are arranged movably within the housing 1 in order to enable or prevent air passage. The air passages 7 and 8 can be guided to the outside by means of tubular extension pieces 11 and 12 through openings in a wall or in the window and end there behind so-called weather protection covers, likewise of a type known per se.

Where the housing 1 in FIGS. 3 and 4 has the air outlet 7 on the one hand and the air outlet grille 9 on the other hand, a radial fan 13, which has an axial suction on both sides, is built into this and has a single impeller 14 which is divided into two by a transverse wall 15 Halves

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14 'and 14 ". The suction side 16 of the impeller half 14' faces the air passage 7, while the suction side 17 of the impeller half 14" faces the air passage grille 9. This arrangement of the impeller 14 of the radial fan 13 can be seen in FIG. 3. 3 that the stator 18 of the impeller 14, which can be seen in FIG. 4, is anchored via several, for example three, support arms 19 to a holding plate 20 which extends parallel to the longitudinal direction of the housing 1 and is detachably fastened therein. This holding plate 20 has e.g. Passage opening 21 arranged concentrically to the suction side 17 of the impeller half 14 ″, which creates a flow connection between the air passage grille 9 and the suction side 17 of the impeller half 14 ″. In the housing 1 of the ventilation device are in the area of the radial fan

13 insert bodies 22 and 23 introduced, which consist of sound-absorbing material, for example foam plastic or foam rubber, and are fixed in position by the holding plate 20 for the stator 18 of the radial fan 13 in the housing 1. The insert body 22 forms the casing spiral for the fan wheel 14, while the insert bodies 23 are straight-line connecting pieces running in the blow-out direction of the fan wheel halves 14 'and 14 ". With the wall part 6 of the housing 1 and the holding plate 20 running parallel thereto, limit the Insert bodies 22 and 23 within the housing 1 have a common chamber 24 for the two fan wheel halves 14 'and 14 "of the fan wheel 14, which is divided longitudinally exclusively in the area of the fan wheel 14 by its transverse wall, but otherwise has no longitudinal division.

The fan wheel 14 is overall, i.e. with its blades 14 '"which extend over the entire width, the end rings (not shown) holding these at their ends, and the transverse wall 15 made of blades 14'" and made of a good heat-conducting material, for example blackened thin sheet metal, preferably copper sheet, while the surface of the insert bodies 22 and 23 delimiting the casing spiral for the impeller 14 is also coated with a material which is also a good heat conductor, for example a copper or aluminum foil.

The fan wheel thus forms within the chamber 24

14 and the metal foil of the insert bodies 22 and 23 of the radial fan 13 a heat exchanger between the two air flows conveyed by the fan wheel halves 14 'and 14 ".

Following the common chamber 24 for the two fan wheel halves 14 'and 14 "of the fan wheel 14, namely at a distance 25 from the circumference of the fan wheel 14, a heat exchanger 26 is inserted into the housing. This heat exchanger 26 is in cross-flow or Cross-flow type executed and has an odd number of plate stacks 27 ', 27 ", 27'", which are clamped between two mutually parallel side walls 28 'and 28 ".

With the front profile 3 removed, the heat exchanger 26 can be used as a structural unit in the middle length region of the housing 1 and can also be removed from it at any time for carrying out maintenance work.

Each plate stack 27 ', 27 ", 27"' of the heat exchanger 26 consists, as can be seen particularly clearly in FIGS. 8 and 9, of a larger number of individual plates 27, each of which has an approximately C-shaped cross section and an approximately square one Has floor plan. The individual plates 27 are made of relatively thin, good heat-conducting material, for example aluminum or copper sheet, and are placed directly on top of one another in the same layering layer to form the individual plate stacks 27 ', 27 ", 27'".

It can be seen from FIGS. 8 and 9 that the individual plates 27 in each plate stack 27 ', 27 ", 27'" are mutually mutually rotated 90 ° relative to one another about an axis directed to their plane, so that flow channels lie between them for the air, which are alternately in a position rotated by 90 ° with respect to one another, so that the air flows each intersect in the flow channels which follow one another in the stratified position.

3 that the plate stacks 27 ', 27 ", 27"' are held between the two side walls 28 'and 28 "in such a way that they each rest with their two diagonally opposite vertex edges 29' within the housing 1 lie on a plane which coincides with the transverse wall 15 of the impeller 14, while the other two, also diagonally opposite apex edges 29 "face on the one hand the wall part 6 and on the other hand the front profile 3 of the housing 1.

The apex edges 29 ″ of the plate stack 27 ′, 27 ″, 27 ′ ″ touch on the one hand the inner surface of a sound insulation covering 30, which sits on the rear of the front profile 3, and on the other hand the inner surface of a sound insulation covering 31, which faces the rear of the wall part 6 on the channel profile 2 is laid.

The plate stacks 27 ', 27 ", 27'" therefore form two separate air flow paths between the side walls 28 ', 28 "and the soundproofing linings 30, 31 within the housing 1, which have an odd number of length sections which follow one another in zigzag fashion in the flow direction One flow path is identified by closed arrows 32, while the other flow path is indicated by open arrows 33.

In each of the longitudinal sections of these flow paths 32 and 33, which follow one another in zigzag fashion, there is a lamella-free or plate-free deflection area 34 and 35, respectively, between two exchanger areas which are formed at an acute angle by the plate stacks 27 ', 27 ", 27'" and which have a uniform distribution which ensures air flows onto the individual flow channels within the plate stack 27 ', 27 ", 27'".

So that there are no short circuits between the two flow paths 32 and 33 within the heat exchanger 26, the mutually adjacent plate stacks 27 ', 27 ", 27'" each abut one another with the apex edges 29 'facing one another and are also fixed there against one another by transverse rods 36 which also connect the two side walls 28 ', 28 "with one another and thus ensure the correct position allocation between these and the plate stacks 27', 27", 27 '".

In the length region of the housing 1 adjoining the last plate stack 27 '' 'there is a longitudinal partition 37 which lies on the same plane with the apex edges 29' of all the plate stack 27 ', 27' ', 27' 'and thus two end chambers 38 in the housing 1 and 39 separates from one another, the end chamber 38 being provided with the air passage 8 and the end chamber 39 being provided with the air passage grille 10.

The two air streams 32 and 33 sucked in by the impeller 14 of the radial fan 13 through the air passage 7 and the air passage grille 9 move in the longitudinal direction through the housing 1 with the same main flow direction and pass after they have flowed through the heat exchanger 26 in cross or cross flow in the two separate end chambers 38 and 39, from which they then through the air passage 8 and the

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Exit air outlet grille 10. Due to the fact that an odd number of successive lengths of zigzag in the flow direction is formed in the heat exchanger 26, the air flow sucked in by the air passage 7 from the fan half 14 ′ is blown out at the air passage grille 10, while the air flow sucked in by the fan half 14 ″ through the air passage grille 9 Area of the air outlet 8 is blown out.

If it is assumed that the air flow sucked in through the air passage grille 9 is the exhaust air flow AB from the room, while the air flow sucked in through the air passage 7 is the outside air flow AU, then it is the air flow exiting the air passage 8 around the exhaust air flow FO, while the air flow emerging from the air outlet grille 10 is the supply air flow ZU.

The warm exhaust air flow AB passes through the radial fan acting as an additional heat exchanger

13 and through the heat exchanger 26 the heat energy inherent in it for the most part, namely at least 70%, from the outside air flow AU sucked in via the air passage 7 and flowing in the same direction through the additional heat exchanger 13 and the heat exchanger 26, so that the supply air flow CLOSED enters the interior of the room at a temperature that is higher than that of the outside air AU, while the exhaust air flow FO emerges outdoors at a temperature that is lower than that of the exhaust air AB. In this way, not only is a favorable ventilation effect achieved, but at the same time a high degree of heat recovery, and thus an energy saving, is achieved.

It should also be mentioned that by working the radial blower 13 with its two blower wheel halves 14 'and 14 "in the common chamber 24 between the two air streams conveyed simultaneously and in the same direction, an optimal air moisture exchange can take place, which not only transfers heat from the exhaust air stream AB in the outside air flow AU, but also prevents frost or ice formation which could result if parts of the temperature of the radial fan 13 acting as an additional heat exchanger fall below the dew point of the exhaust air flow AB and this temperature is simultaneously below the freezing point.

It has been shown that in spite of the presence of the common chamber 24 for conveying the exhaust air AB and the outside air AU, there is no excessive mixing of the two air flows, because these air flows also occur in the distance region 25 between the circumference of the impeller at the high speed inherent in them

14 and the heat exchanger 26 do not mix. The transverse wall 15 of the impeller 14 and the apex edge 29 'of the plate stack 27' act indirectly over this distance region 25 as air guiding elements, which create an imaginary separation zone between the two air flows.

The particularly simple and maintenance-friendly design of a ventilation device of the type described above can also be seen in FIGS. 5 to 7. This is because they make it clear that all functional elements of the ventilation device working as heat recovery devices are readily accessible from the room side after the front profile 3 has been removed.

In addition, it follows from FIG. 3 that the position of all functional elements relative to one another in the longitudinal direction of the cuboid housing 1 is ensured simply by holding the holding plate 20 for the stator 18 of the impeller 14 on the one hand and the

The longitudinal partition 37 between the two end chambers 38 and 39 is supported with its outer end against the end plates 5 and 4 of the housing 1, while its inner ends are detachably fastened to the heat exchanger 26 by screws 40. Since the heat exchanger 26 is elastically clamped between the sound insulation coverings 30 and 31 on the inside of the housing, the inner ends of the holding plate 20 and the longitudinal partition wall 37 also have a correspondingly defined position within the housing. The position definition of the outer end of the holding plate 20 in the housing 1 is obtained by elastically clamping it between a stop web 41 of the end plate 5 and the insert 22 of the radial fan 13, while a corresponding elastic clamping of the outer end of the longitudinal partition 37 between a stop web 42 of the end plate 4 and an elastic insert 43 is maintained.

The air passage grille 9 can either be closed by a pressure plate 44 which is movable transversely to its plane in the housing 1 or can be released for the air passage, while a corresponding pressure plate 45 is also assigned to the air passage grille 10. Both pressure plates 44 and 45 can be moved in the same direction by a common drive.

In connection with the plate stacks for the heat exchanger 26 shown in FIGS. 8 and 9, reference should also be made to possible variations in design for the individual plates 27. 8 is provided with flat edge webs 46 which are directed at right angles to the main plane of the individual plates 27 and act as baffles in the respective inflow direction of the air, the edge webs 47 of the individual plates 27 according to FIG. 9 are counter to the inflow direction of the Air tapered in a wedge shape so that it acts as an inflow surface and thus better direct the air into the individual flow channels of the plate stack while avoiding excessive eddy formation.

From FIG. 9 it can also be seen that the individual plates 27 shown there each have step-shaped shoulders 48 at their corner regions with two edges directed at right angles to one another. With these shoulders 48, the individual plates 27 and thus also the plate stacks 27 ′, 27 ″, 27 ″ ″ in total can each be supported on two surfaces of the transverse connecting rods 36 that are oriented at right angles to one another and thus obtain improved positional security.

An advantageous further development of the ventilation device according to FIGS. 3 to 7 is also shown in FIGS. 10 and 11. The deviation from the embodiment according to FIGS. 3 to 7 lies in the installation area of the heat exchanger 26.

In the exemplary embodiment according to FIGS. 10 and 11, the soundproofing covering 30 is not fastened directly to the inside of the front profile 3, but on a regulating plate 49 arranged behind it, which is arranged transversely to its plane in the housing 1 or on the front profile 3. The regulating plate 49 can either be folded around its upper longitudinal edge or held tiltable about its lower longitudinal edge; but it can also be guided so that it can be moved transversely to itself. For the purpose of adjusting the regulating plate 49, an actuating member 50 supported on the front profile 3 can be provided, which can be moved either manually or by power drive. 10 and 11, for the sake of simplicity, manually adjustable actuators are shown in the form of set screws.

With the aid of these actuating members 50, the distance between the sound insulation covering 30 and the apex edges 29 ′ of the plate facing it can be adjusted via the regulating plate 49.

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Change the stacks 27 ', 21 ", 21"' of the heat exchanger 26 in such a way that the apex edges 29 "either lie close to the inside of the soundproofing covering 30 or are at a more or less large distance from them. 5

If the soundproofing covering 30 bears against the apex edges 29 ″, the ventilation device according to FIGS. 10 and 11 acts as a heat recovery device in the same way as that according to FIGS. 3 to 7. However, the soundproofing covering 30 takes up a spacing position the apex edges 29 "facing her, then a short-circuit connection is made between the deflection regions 34 and 35 of the two flow paths 32 and 33 adjacent to the sound insulation covering 30, so that the two are conveyed separately from the fan wheel halves 14 'and 14" per se Air currents flow together there - at least for the most part - as a result of which the majority of the air conveyed together by the fan wheel halves 14 'and 14 "enters the end chamber 39 and from there through the air outlet grille 10 into the interior of the room. The consequence 20 of this is that not only does the outside air AU conveyed by the blower wheel half 14 'get into the interior of the room, but also most of the exhaust air AB conveyed by the blower wheel half 14 "again enters the room in recirculation mode

In this way, mixed-air operation of the ventilation device can be brought about, in which the fresh outside air AU combines with most of the exhaust air AB extracted from the room and thus an increased amount of supply air CLOSED into room 30

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reached, which is improved in quality compared to the exhaust air AB by the large proportion of outside air AU.

Such operation of the ventilation device can prove to be particularly advantageous in summer, because it is usually not a question of heat recovery from the exhaust air AB. '

3 to 7 can also be designed so that the movable pressure plates 44 and 45 consist of one piece and extend behind the front profile 3 over the entire length of the housing 1. In this case, however, the soundproofing covering 30 must then be made thinner than that shown in FIGS. 3 and 7 and placed on the back of the one-piece pressure plate 44, 45 in the middle length range. In the closed position of the pressure plate 44, 45, the inside of the sound insulation covering 30 is at a distance from the apex edges 29 "of the plate stack 27 ', 27", 27' "facing it. However, the pressure plate 44, 45 is in the open position according to FIG. 3 , 5 and 6 moves, then the inside of the sound insulation covering 30 bears against the apex edges 29 "of the plate stack 27 ', 27", 27' ", so that the deflection regions 34 and 35 of the separate flow paths 32 and 33 and the heat exchanger become effective 26 transfers the heat from the exhaust air flow AB to the outside air flow AU.

In this embodiment of a ventilation device, it is expedient to fix the heat exchanger 26 within the housing 1 in the transverse direction by means of special bridge elements which are independent of the sound insulation covering 30.

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Claims (12)

658 119 PATENT CLAIMS 1. Ventilation device for a room, with two separate flow paths (32; 33) for ventilation in an elongated, rectangular housing (1), which is used for recuperative heat recovery from the ventilation air flow via a heat exchanger enclosed in the housing (1) (26) are in operative connection with one another, and with inevitable air conveyance in the two flow paths (32; 33) by a radial fan (13), this radial fan with its fan wheel (14 divided into two independently conveying halves by a radial partition (15) ) each protrudes into both flow paths (32; 33), and one air inlet (7; 9) is assigned to each of the two halves (14 '. 14 ") of the impeller (14) on axially opposite sides of the housing, while in the the length of the housing (1) adjoining the heat exchanger (26) has two end chambers (38; each having an air outlet (8; 10) and separated by an installation body). 39), characterized in that the impeller (14) is mounted in a chamber (24) common to both flow paths (32; 33), that the chamber (24) is delimited by an insert body (22) that the two flow paths (32; 33) in a length region of the housing (1) adjoining the chamber (24) are formed exclusively by the cross-flow type heat exchanger (26) into an odd number of length sections which follow one another in the flow direction and are in each case between two At right angles successive exchange areas formed by plate stacks (27 ', 27 ", 27'") have a plate-free deflection area (34; 35), the apex edge (29 ') of the plate stack (27') closest to the fan wheel (14), which separates the two flow paths (32; 33), in the same line as the partition (15) of the fan wheel (14) and that finally a longitudinal flow delimiting the two end chambers (38; 39) against each other nominal wall (37) lies on the same level with the apex edge (29 ') of the plate stack (27' ") which is the most distant from the radial fan (13). 2. Ventilation device according to claim 1, characterized in that the chamber (24) of the radial fan (13) delimiting insert body (22) made of sound-absorbing material, for example foam plastic or foam rubber. 3. Ventilation device according to claim 2, characterized in that on the insert body (22) on one side rests within the housing (1) arranged holding plate (20) on which the stator (18) of the radial fan (13) is fastened, the insert body (22) is fixed in the housing (1) by the holding plate (20). 4. Ventilation device according to claim 1, characterized in that the impeller (14) and its partition (15) made of thermally conductive material, e.g. Copper sheet exist, and the surfaces of the insert body (22) are covered with a film of heat-conducting material, for example a copper or aluminum foil. 5. Ventilation device according to claim 1, characterized in that the apex edge (29 ') of the blower wheel (14) closest plate stack (27') to the blower wheel (14) has a distance (25), while the apex edge (29 ') of the Blower wheel (14) of the most distant stack of plates (27 '") - directly adjoins the longitudinal partition wall (37) located between the two end chambers (38; 39). 6. Ventilation device according to claim 1, characterized in that in each plate stack (27 '; 27 "; 27'") several superimposed in cross-section C-shaped individual plates (27) between one another alternately first air flow paths (32) and second air flow paths (33) form, the second air flow paths (33) extending transversely to the first air flow paths (32) and being separated therefrom (FIG. 8). 7. Ventilation device according to claim 1, characterized in that the plate stack (27 '; 27 "; 27'") arranged between two side walls (28 '; 28 ") and thereon by cross-connecting rods (36 ) are secured against rotation. 8. Ventilation device according to claim 1, characterized in that the heat exchanger (26) between soundproofing coverings (30; 31), e.g. Foam plastic, the longitudinal walls (3; 6) of the housing (1). 9. Ventilation device according to claim 8, characterized in that the apex edges (29 ") of the plate stack (27 '; 27"; 27' ") reach up to the sound insulation coverings (30; 31). 10. Ventilation device according to claim 8, characterized in that at least between one (3) of the two longitudinal walls (3; 6) and its sound insulation covering (30), an actuator is arranged, whereby the distance between the sound insulation covering (30) and the apex edges (29 ") the plate stack (27 '; 27"; 27 "') is adjustable and the deflection areas (34; 35) between the plate stacks can be brought into flow connection directly with one another (FIGS. 10 and 11). 11. Ventilation device according to claim 10, characterized in that the actuator is a regulating plate (49) which is movable transversely to itself, for example displaceable, pivotable or foldable (Fig. 10 and 11). 12. Ventilation device according to claim 11, characterized in that the regulating plate (49) by actuators (50), e.g. Actuators can be actuated (Fig. 10 and 11).