DK176292B1 - Sealing device for a heat recovery cell - Google Patents

Description

in DK 176292 B1

The invention relates to a sealing device according to the preamble of claim 1 for a heat recovery cell.

By a heat recovery cell, in this connection is meant, for example, a device used in a ventilation device or in a similar ventilation machine, in which the supply air blowing into a room and the exhaust air sent out of the room are circulated through a heat recovery seal. The supply air to be blown into the room is heated in the heat recovery cell by means of the hot exhaust air sent out of the room, so that the heating of the supply air does not require an excessive amount of energy. Thus, impure exhaust air and pure supply air circulate through the same heat recovery cell, but in such a way that the extract air and supply air cannot contact each other in the cell and thus cannot mix with each other. Furthermore, it is important that the heat recovery cell is sealed to the ventilation device or to a similar structure so that the exhaust air and the supply air are not allowed to mix with each other in the device itself.

In present devices in, for example, ventilation devices, a space defined by walls or the like is arranged. a heat recovery screen in which space the heat recovery screen can be removably mounted. The easy removal of the heat recovery cell is important as it should be possible to clean the cell from time ten! other. The cells are usually nearly square, and are usually fixed obliquely in the ventilation device so that the corners of the square cell are pointing upwards and downwards, and to both sides of the ventilation device. It is also common for the cell to be shaped so that they are cornered. 25 sides pointing to the sides have been "cut off, so that vertical walls define the cell against the sides. In addition to this shape, the cell has a certain depth. Today, the sealing of such a cell has been mainly provided such that in the mounting space of the ventilation device first, seals which seal the heat recovery cell at its downward and upward-facing corners are to the mounting compartment or to support structures located in the mounting compartment. , it is thus pushed flour loosen the seals, and since the seals are relatively "narrow" to provide sufficient airtightness, it is relatively difficult to put the cell in place and remove it.

Another even very significant disadvantage of current designs is that the relatively high weight of the heat recovery cell causes the cell's lower seal to compress over time and become ineffective, resulting in weakening the sealing effect of the cell's upper seal and even opening at the upper seal, from which opening can flow air from the exhaust air side to the supply air side. The weakening of the seal may in some cases already appear in fairly new designs, since in many cases a ventilation device is transported from the factory to the place, where it needs to be installed, as a complete unit. During transport, the shaking can cause one of the transport in this connection to cause the lower seal of the cell to flatten and the upper seal to begin to leak. In this case, instantaneous leakage occurs in a new device.

It is an object of the present invention to provide a new type of sealing device for a heat recovery cell whereby the disadvantages associated with the known devices are avoided. However, in order to achieve this objective, the sealing device according to the invention is mainly characterized by the description in the characterizing part of claim 1.

The invention provides a considerable advantage over the known devices, and the most important of these advantages is that the sealing device according to the invention substantially eliminates the possibility of escape in the heat recovery cell. In the invention, this is based on the fact that sealing on a mite is effected by the weight of the heat recovery cell so that the sealing properties themselves do not deteriorate over time. Moreover, it improves rather than weakens the sealing of the shakes during transport. Another significant advantage is that it is significantly easier than before to put the heat recovery cell in place. The other advantages and features of the invention will become apparent from the following detailed description of the invention. In the following, the invention will be described in detail with reference to the figures in the accompanying drawings.

FIG. 1 is a schematic front view of a ventilation machine in which is mounted a heat recovery cell, provided with a sealing device according to the invention.

FIG. 2, 3 and 4 show in greater detail upper and lower seals and side seals belonging to the sealing device according to the invention.

The sealing device according to the invention for a heat recovery cell is intended to be used particularly in connection with a ventilation device and especially in connection with a ventilation device used to blow air into a room and, on the other hand, draw air out of the room. One such ventilation device is shown in FIG. 1, and in this figure it is generally indicated by the reference numeral 10. The ventilation device 10 is shown in FIG. 1 with its front wall open so that the attachment of the hot self-extracting cell 20 inside the ventilator can be seen better. The upper wall of the ventilation device 10 is provided with the necessary openings and ducts 31 - 34 for circulation of incoming air L1 - L2 and exhaust air L3 - L1. The ventilation device 10 is further provided with the necessary 5 fans 12, 13 for circulating air and with filters 14, 15 ti in cleaning of air flows. In the ventilation device frame 11 in the middle part of the ventilation device, a mounting compartment for the heat recovery cell 20 is formed, which mounting space is defined by vertical side walls 16, 17.

10 The circulation of supply air and exhaust air in the ventilation device 10 is arranged as follows. A first fan 12 draws air from outside Llf which enters the ventilation device 10 from a first duct 31 and passes through the heat recovery cell 20. The first fan 12 blows the air through a first filter 14 and blows the air further into the space from a second duct 32 such as supply air l2. A second fan 13 15 draws exhaust air L3 from the room, which exhaust air enters the vent 10 through a third duct 33 and passes through a second filter 15. The second vent 13 blows the air through the heat recovery cell 20 and further from the vent 10 through a fourth duct. 34 as the exhaust air L ,, The supply air and exhaust air flow through the heat recovery cell 20 so isolated from each other that the 20 cannot mix with each other. The heat recovery cell 20 takes heat from the hot exhaust air and transfers it to the supply air flowing through the heat recovery cell 20.

As already described above, the supply air and the exhaust air cannot mix with each other in the heat recovery cell 20. It is, of course, quite clear that the supply air and the exhaust air must also not be able to mix anywhere else in the ventilation device. For this reason, the heat recovery cell 20 is provided with seals and is thus mounted in a sealed manner in the space reserved for it in the ventilation device 10. The sealing device is shown in more detail in FIGS. 2-4. For the purpose of sealing the heat recovery cell 20, an upper support 18 is fixed in the upper part of the frame in the ventilation device frame 11 and a lower support 19 is secured in the lower part thereof, the upper and lower part of the heat recovery cell 20 is supported on the frame 11 of the ventilation device through these supports. As shown in FIG. 2, the upper support 18 is a T-shaped piece, with sealing strips 21a attached to the T-branches 18a of the piece. The sealing strips 21a can be attached to the upper support T-branches 18a, for example by gluing or a similar means. Attached to the upper portion of the heat recovery cell 20 is a shaped profile 21b, the shape of which is substantially similar to a C-shape. The shaped profile 21b can be attached to the upper part of the heat recovery cell 20, for example by gluing, welding or a similar means.

4 DK 176292 B1

For example, the material of the shaped profile 21b is aluminum. As shown in FIG. 2, once the heat recovery cell 20 has been inserted, the shaped profile 21b surrounds the upper support T-branches 18a and the sealing strips 21a attached to them so as to form an upper seal 21 of the heat recovery cell.

5 Similarly, a T-shaped lower support 19 is attached to the lower part of the ventilation device frame 11, with an elastic sealing strip 22a being placed on the lower support T-branches 19a. For example, the elastic seal strip 22a is a hollow seal as shown in FIG. 3, which allows a fairly large compression. A U-shaped profile 10 22b with the arms pointing downwards is attached to the lower part of the heat recovery cell 20. The shaped profile 22b can be attached to the heat recovery cell 20 in the same way that the shaped profile 21b is attached to the upper part and it can be made of the same material. Once the heat recovery cell 20 has been put in place, the resilient sealing strip 22a remains between the lower support T-branches 19a and the shaped 15 profile 22b so that the U-branches of the shaped profile 22b vi! be in the lateral direction on both sides of the resilient sealing strip 22a and the lower support 19, thereby ensuring that the heat recovery cell 20 is mounted in the proper place. Thus, the U-branches of the shaped profile 22b serve as guide when the heat recovery cell is inserted. Thus, the lower seal 22 is formed by the resilient sealing strip 22a and the shaped 20 profile 22b. The shape of the lower support 19 itself may be different from that of FIG. 3 so that it does not have to be T-shaped.

The heat recovery cell 20 also includes side seals 23, which are shown in more detail in FIG. 4. First, support strips 16a, 17a are formed on the vertical side walls 25 16, 17 defining the heat recovery cell mounting space, with elastic sealing strips 23b attached to the support strips. . Similarly, angular strips 23b are attached to the side walls of the heat recovery cell 20, which angular strips are arranged such that the resilient sealing strip 23a remains between the support strips 16a, 17a and the angle strip 23b each time the heat recovery cell 20 is inserted. The angular moldings 30 23b are also advantageously an aluminum material. In the same way as with the lower seal, the structure of the resilient sealing strip 23a of the side seal 23 allows a large compression, for example being a hollow seal as shown in FIG. 4. FIG. 1 shows that there is one side seal 23 on both sides of the heat recovery cell 20. However, there may be several side seals.

35

As shown in FIG. 1, the heat recovery cell 20 is located in the ventilation device 10 on the suction side of the first fan 12 and on the pressure side of the second fan 13. If the flow paths of supply air and exhaust air are not insulated from each other with sufficiently good seals, the risk of mixing is thus high. . In the device 5 DK 176292 B1 according to the invention, this risk is minimized by the fact that each seal is compressed by the effect of the weight of the ventilation device's warm self-recovery cell 20, with the result that even any shaking does not cause solution and possible leakage of the seal. place In the same direction. As shown in the figures in the drawings, the upper and lower seals 21, 22 and side seals 23 of the heat recovery cell extend in the depth direction of the heat recovery cell 20. In addition to these seals, the heat recovery cell 20 is also sealed to the back wall and the front wall of the ventilation device 10, but the seals therein. directions can be provided in a conventional manner and are therefore not described in more detail herein, 10

Above, the invention has been described by way of example with reference to the figures in the accompanying drawings. However, the invention is not limited solely to the examples shown in the figures, but the various embodiments of the invention may vary prior to the inventive idea defined in the appended claims.

Claims (5)

6 DK 176292 B1 A sealing device for a heat recovery cell in a ventilation device (10) or the like, provided with the necessary duct systems for clean supply air (U - 5 L2) and impure exhaust air (L3 - L), which duct systems are arranged to pass, insulated from each other, through the heat recovery cell (20), in which connection is formed in a frame (11) of the ventilation device (10) or the like. a heat recovery cell mounting compartment (20), which is defined by substantially vertical side walls (16, 17) and upper and lower supports (18, 19), in which the recoverable compartment (20) mounting compartment can be removably sealed. ! a front and rear wall of the ventilation device (10) or the like and provided with seals (21, 22, 23) extending in the depth direction, which seals the heat recovery cell (20) to the upper and lower supports (18, 19) ) and to sidewalls (16, 17) so as to define flow paths for the supply and exhaust air and to prevent the supply air 15 and exhaust air (Li - L2, L3 - U) from mixing with each other, which sealing device is characterized by each sealing (21, 22, 23) of the heat recovery cell is provided with resilient sealing strips (21a, 22a, 23a), the bottom surfaces of which are supported on a load-bearing structure of the ventilation device (10) or similar, and on whose upper surfaces the heat recovery cell ( 20) is supported by the effect of gravity, 20 so that each sealing strip (21a, 22a, 23a) is subjected to a parallel compression directed from top to bottom. Sealing device according to claim 1 for a heat recovery cell, characterized in that the sealing device comprises an upper seal (21) disposed in the upper part of the heat recovery cell (20), a lower seal (22) disposed in the lower portion, and at least one side seal (23) disposed on both sides of the heat recovery cell, A sealing device according to claim 1 or 2 for a heat recovery cell, the sealing device being characterized in that a shaped profile (21b, 22b) or a corresponding angle strip (23b) is attached to the heat recovery cell (20) at each seal (21, 22, 23), through which shaped profile or angle in the heat recovery cell (20) is supported on the sealing strip (21a, 22a, 23a) and pressed against it from above. 35 Sealing device according to any one of the preceding claims for a heat recovery seal, characterized in that the shaped profile (21b) belonging to the structure of the upper seal (21) is substantially C-shaped and opens and that the upper support (18) comprises a T-shaped structure which hangs from the frame of the ventilation device (10) or the like, the sealing strips (21a) being fixed to the upper surface of the T-branches of the structure. (18a) such that the C-branches of the shaped profile (21b), when inserted, surround the T-branches (18a) of the upper support (18) while being supported on the upper surface by the sealing strips (21a). Sealing device according to any of the preceding claims for a heat recovery cell, characterized in that the shaped profile (22b) belonging to the structure of the lower seal (22) is substantially U-shaped. and opens downwardly, and that the sealing strip (22a) is attached to the lower support (19) so that the U-branches of the shaped profile (22b), when inserted, we! be on both sides 10 of the sealing strip (22a) and the lower support (19). Sealing device according to any of the preceding claims for a heat recovery cell, characterized in that a branch of the angular strip (23b) belonging to the structure of the side seals (23) is directed horizontally outwards from a 15 side surface of the heat recovery cell (20) and support strips (16a, 17a) formed on the substantially vertical side walls (16, 17) defining the mounting space, with sealing strips (23a) attached to the support inserts so that the angular frame (23b) ) branch, when inserted, will be on the sealing strip (23a).