SE1550646A1 - Heat exchange device - Google Patents

Abstract

The present invention relates to a heat exchange device for heat transfer between a first fluid and a second fluid, the heat exchange device comprising. a housing with an inlet and an outlet and a flow direction between them, a plurality of plate elements, each plate element comprising at least two ridges and the plurality of plate elements being arranged in a stack inside the housing so that the ridges run in the flow direction and so that the ridges of a plate element lie against corresponding ridges of adjacent slab elements ,. the ridges defining walls of at least three fluid chambers, so that each fluid chamber is bounded either by two ridges or by a ridge and an outer edge of the plate element. wherein each fluid chamber is arranged to be a first fluid chamber housing flux of a first fluid or a second fluid chamber housing flux of a second fluid. and wherein each first fluid chamber is adjacent to at least one second fluid chamber, and vice versa.

Description

TECHNICAL FIELD OF HEAT EXCHANGE DEVICE The present invention relates to a heat exchange device for transferring a subversive energy between a first and a second circuit.

KNOWLEDGE TECHNIQUE In the art, there are known methods and devices for passive protection transmission, which are driven by a temperature difference between two or two times. A common such device is a plate heat exchanger, which comprises a set of plates designed to form two separate channels for two outputs, each channel forming an intermediate pair of plates, and which allows a transfer of heat or cooling through the plates in their thickness direction. The plates are normally very thin to allow for efficient heat transfer, and in some cases may also be provided with surface enlargements, seed dents or nanoparticles, to increase the contact area against the surfaces. Plate heat exchangers are generally considered to be the best choice in liquid-to-liquid applications. For liquid-to-air applications, it is also known to solder a number of fl ends to a pipe, where the liquid fl the inside of the tube and the enlarged surface area with the fl interact with the surrounding air or gas.

One area of application for heat exchangers is in ventilation systems for buildings, in which indoor air is replaced by outdoor air. By performing a heat exchange between an outgoing and an incoming air fl desert, the temperature of that incoming air will be brought closer to the indoor temperature, which results in a passive heating and / or cooling in order to avoid costs. A common form of heat exchanger pre-ventilation system utilizes a liquid carrier to transport thermal energy from one ventilation stream to another.

SUMMARY OF THE INVENTION An object of the present invention is to provide a new form of heat exchanger which is inexpensive to manufacture, has low operating costs and which is reliable.

According to a first aspect of the invention, at least one of these objects is achieved with the heat exchange device according to the preamble of claim 1, which is further arranged in accordance with the characterizing part of the same claim.

The heat exchanger according to the present invention differs from existing heat exchangers in that heat transfer takes place along a plurality of plate elements which form accumulator plates and which pass through each chamber and can be located at a very small distance from each other. This means that in the same space as one can have a single accumulator plate prior art, with the present invention one can have a significant number of disturbances, for example ten, and thus the new technology has within the same space in one such an embodiment ten times as much heat transfer capacity as the prior art, which thus gives a significantly higher efficiency.

This results in a heat exchange device which has good heat transfer properties and thus high efficiency, and which provides a very large accumulator surface for heat transfer between a first chamber and a second chamber and vice versa. Due to the fact that the plate elements comprise at least two ridge sheets, a plurality of outer chambers are formed at a short distance from each other, which improves the transmission between them and enables the placement of plate elements at a very short distance from each other.

According to one aspect of the present invention, the ridges comprise a recessed portion and a protruding portion, the protruding portion of the ridge of a plate member being shaped to pass into the recessed portion of the ridge in an adjacent plate member, and the ridges also comprising a bending angle of at least 45 °. preferably at least 55 °, more preferably at least 65 °. Thanks to the bending angle, the distance between adjacent plate elements can be controlled so that a larger bending angle means a shorter distance without the need to resort to accepted fixing methods such as soldering, welding or screw joints. Thanks to this, the accumulator surface of the heat exchange device can be increased dramatically compared to previously known heat exchangers, while keeping the assembly of the device simple, inexpensive and fast. In this case, the distance between two adjacent plate elements is less than 0.5 mm, preferably less than 0.2 mm, more preferably less than 0.1 mm, which gives a very large accumulator surface and a high efficiency. The transport distance of the heat energy through the ridges is substantially shorter than with similar, previously known constructions, which also gives a higher power and efficiency for the technique according to the present invention.

According to another aspect of the present invention, the heat exchange device comprises guide plate having a plurality of control means arranged to control the flow of a first fluid to or from the first outer chambers and to control the flow of a second outer chamber to or from the outer outer chambers. Thereby, the fate of a first discharge can be controlled from a single supply device to a plurality of first discharge chambers spaced apart from each other and then after passage through the heat exchange device reassembled into a single discharge device, and thanks to this a high efficiency and good efficiency can be obtained without risking both. fl uid currents are mixed.

According to a further aspect of the invention, said guide means comprise a plurality of openings in the guide plate. Thereby, the advantage described above can be obtained in a simple and inexpensive manner but still with high reliability and low risk of the mixed air streams.

Additional advantages of the invention are described in the following detailed description, as will be readily apparent to those skilled in the art.

DRAWING FIGURES The invention will now be described in more detail with reference to the accompanying drawings.

Fig. 1 spring gearing device according to the present invention; shows a perspective view of a plate element according to a preferred embodiment of Fig. 2 shows a side view of the ridge of the plate element in Fig. 1; Fig. 3 shows the embodiment of Fig. 1; shows a perspective view of a number of plate elements according to the preferred one Fig. 4 shows a side view of the plate elements in Fig. 3 when these stacked one on top of the other; 5 shows a perspective view of a spring gear device according to the preferred one the embodiments of the present invention with a housing enclosing a stack of plate members; and Fig. 6 shows an exploded view of the spring exchange device in Fig. 5 together with pipe sockets for incoming and outgoing air and a guide plate for controlling air flow to and from the respective pipe socket.

DETAILED DESCRIPTION Fig. 1 shows a plate element 1 according to a preferred embodiment of the present invention. The plate element 1 comprises a substantially rectangular plate, for example avaluminum, which comprises at least two ridges 2 made by bending, pressing or the like. The ridges 2 extend substantially parallel to an edge of the hose plate element 1 and run substantially parallel to each other. Fig. 1 shows a plate element 1 with three ridges 2, but the number can thus vary from two and upwards, as will be explained in the following.

In Fig. 2 the plate element 1 is seen from the side with a ridge 2 which comprises a projecting part 2a and a sunken part 2b. The width b1 of the ridge in this example is 2 mm, with the width b of the recessed part2b; 0.7 mm and the height of the ridge h 2 mm. The thickness of the plate element is 0.15 mm, and for this plate element 1 the distance between two ridges is about 10 mm. It should be pointed out that these figures are given only as an example in connection with this preferred embodiment and that the plate elements 1 according to the invention can of course have different dimensions without deviating from the invention as defined by the appended claims. Depending on the thickness of the plate element, different dimensions can in themselves give different advantageous designs, and for plate elements formed of very thin sheet metal, a very short distance between ridges, in the order of 5-8 mm, can give a high efficiency and good efficiency. The ridge 2 further has a bending angle ot which determines the distance between adjacent plate elements 1 when these are stacked together. In this connection, the connection generally applies that the narrower the bending angle, the shorter the distance between adjacent plate elements 1. The bending angle ot is thus at least 45 °, preferably at least 55 °, more preferably at least 65 °. A bending angle of about 65 ° would in this exemplary embodiment mean that the distance between adjacent plate elements 1 is about 0.2 mm, and that maneuvering plate elements of this thickness can thus stack plate elements 1 per centimeter, which means a very large accumulator surface in the heat exchanger.

In Fig. 3 a plurality of plate elements 1 are shown together in height, so that the ridges 2 of a plate element lie opposite the corresponding ridges 2 of adjacent plate elements 1. In this case the shape of the ridges is such that the recessed part 2b of a ridge 2 fits into the protruding part 2a of the corresponding ridge 2 of adjacent plate elements 1. When the plate elements are stacked on top of each other, the ridges 2 will be pressed together so that they abut each other, as shown in Fig. 4, and the ridges 2 together form a wall 3 delimiting two outer chambers (see Fig. 5 -6). The wall 3 thereby forms a heat-conducting and airtight delimitation which has made heat energy transferred from an fl outlet chamber to adjacent fl outlet chambers.

Thanks to the shape and stacking of the plate elements 1 on each other, the plate elements 1 are very simple and inexpensive to manufacture, for example with an eccentric press, and fl outer chambers can be formed and delimited from each other without having to attach the plate elements 1 to each other in any other way. by stacking. This is a great advantage of the invention, since the installation of a plate heat exchanger is otherwise a very time-consuming task and it can be difficult to get a large accumulator surface, i.e. to mount the plate elements at a short distance from each other. Because the distance here can be kept constant throughout the stack and the plate elements 1 are maintained by gravity and friction between the plate elements 1, a very cheap and efficient heat exchanger with high efficiency is obtained which is at the same time fast and easy to assemble. Thanks to the fact that several ridges 2 are provided in each plate element 1, a plurality of outer chambers can also be formed, which also contributes to a higher efficiency and simplifies the fixing of the plate elements relative to each other.

In another embodiment, the ridges 2 can be designed in a different way, for example by means of metal wire being fastened along the plate element 1 in place of the ridge 2. The plate elements 1 can then be stacked without a protruding part fitting into a recess, but simply by the height of the raised ridges which are then formed by an elongate object lying on the surface of the plate element itself giving the distance between two plate elements 1 in a stack.

Having a large number of ridges, as shown in Fig. 3, provides a large number of ridges 3, 4 at a short distance from each other and thereby improves the heat exchange between the two ridges. It should be noted, however, that the number of ridges may vary depending on the application and that even a lower number can provide good efficiency and satisfactory efficiency.

Fig. 5 shows a heat exchange device 10 with a housing 11 which has a first end 12 and a second end 13 and which encloses a number of plate elements 1 which are arranged in a single stack as described above. The ridges 2 form walls 3 which run along a fl direction of fate. is traversed by a second fl uid. In this exemplary embodiment, there are 29 ridges 2 in each plate element 1 and each first or second outer chamber 4, 5 is thereby delimited by two adjacent ridges 2 which form walls 3 or by an axis 2 and an outer edge hose plate element 1.

In a preferred embodiment where only two ridges 2 are present, a first fl discharge chamber 4 and two second fl discharge chambers 5 are formed instead, or vice versa, and in another embodiment a larger or smaller number of ridges 2 can of course be present at each plate element1.

When the heat exchange device is used in, for example, a ventilation system, the first kan uiden may be heated air from inside a building and the second fl uiden may be colder air outside the building.

Fig. 6 shows the heat exchange device 10 together with further components which can be mounted together to carry the first fluids to and from the heat exchange device 10 on one side thereof. It is then advantageous for mounting-corresponding components also on the other side in the direction of fate to move id from the outside and from this side as well.

The first and second discharge chambers 4, 5 are thereby extended by supplying a truss 6 which also forms air ducts and simplifies the conduction of the first and second discharge to and from a supply device and a discharge device in the form of pipe sockets 8a, 8b. In order to carry the first mellan outlet between the first id outlet chambers 4 and the supply device in the form of an upper pipe socket 8a and the second fl outlet between the second fl outlet chambers 5 and a single-discharge device in the form of a lower pipe outlet 8b, there is also a guide plate 7. which prevents the uidema from coming into contact with the wrong pipe socket. The control plate 7 thereby functions as an air distributor as control incoming and outgoing air flows to and from the atmospheric air and to and from the indoor air in two closed systems, which means that the outgoing, spoiled air cannot come into contact with the incoming, fresh air. The supply device 8a and the discharge device 8b can of course be designed in a different way than through pipe sockets and the control means 71 have a different design than as openings in a guide plate 7, for example pipelines with nozzles or the like. In another embodiment, the supply device and / or the drainage device may comprise a number of nozzles and pipes which provide inlet or outlet in a number of different places.

The invention is not limited to the examples and embodiments shown but can be freely varied within the scope of the appended claims. For example, the shaft housing plate elements can be designed in different ways and the components around the self-defense exchanger are designed in different ways as long as they move a first and a second till uid to and from fl uid chambers in the heat exchanger. Furthermore, features shown exclusively for one example or another embodiment of the specification may equally well be used in another embodiment and example.

Claims (1)

Heat exchange device for heat transfer between a first surface and a second fluid, the heat exchange device comprising - a housing e with a first end (12) and a second end (13) and a flow direction between them, - a number of plate elements, each plate element comprising at least two ridges and the plurality of plate elements are arranged in a stack inside the cavity so that the ridges run in the flow direction and so that the ridges of a plate element abut corresponding ridges of adjacent plate elements, the ridges defining walls of at least three outer chambers, so that each fluid chamber is bounded by either two ridges. or of a ridge and an outer edge of the hose plate member, - wherein each outer chamber is arranged to be a first fluid chamber housing a desert of a first outer chamber or a second fluid chamber housing a desert of a second outer chamber, and wherein each first outer chamber adjoins at least one second and a second fluid chamber. vice versa. The heat exchange device according to claim 1, wherein the ridges comprise a recessed part and a projecting part, wherein the projecting part of the ridge of a plate element is shaped to fit into the recessed part of the ridge in an adjacent plate element, and the ridges also comprise a bending angle which is at least 45 ° , preferably at least 55 °, more preferably at least 65 ° Heat exchange device according to claim 1 or 2, wherein the distance between two adjacent plate elements is less than 0.5 mm, preferably less than 0.2 mm, more preferably less than 0.1 mm. Heat exchange device according to any one of claims 1-3, further comprising a control plate (7) having a number of control means (71) arranged to control the fate of a first fluid to or from the first fluid chambers and to control the fate of a second fluid to or from the second fluid chambers. Heat exchange device according to claim 4, wherein said guide means (71) comprises a plurality of openings in the guide plate (7).