ES2903236T3 - Plate element for a plate heat exchanger - Google Patents

Abstract

Plate element for a heat exchanger, which is an arrangement (1) of at least two layers, with a layer (2), by which enthalpy can be transferred between two fluid flows separated by the plate element (1), and at least one perforated layer (3, 4), characterized in that the plate element (1) is formed as a laminate arrangement (1), because the layer that serves for the transfer of enthalpy between the two fluid flows separated by the plate element (1) is formed as a plastic membrane layer (2), because the at least one perforated layer (3, 4) is formed as a support layer (3, 4) made of a perforated and deformable material, and because by means of the at least one support layer (3, 4) the plate element (1) can be provided with a predetermined mechanical resistance and a spatial structure and these are maintainable.

Description

DESCRIPTION

Plate element for a plate heat exchanger

The invention relates to a plate element for a plate heat exchanger.

Plate elements of this type are customary in a wide variety of shapes and made of countless different materials. EP-A-2053335 discloses a plate element according to the preamble of claim 1, i.e. a plate element for a heat exchanger, which is an arrangement of at least two layers, with one layer, by which enthalpy can be transferred between two fluid flows separated by the plate element, and at least one perforated layer.

US-A-20070151447, DE-A-102005003543, US-A-2012073791, US-A-2013233514 and GB-A-2417315 disclose other plate elements for a heat exchanger.

On this basis, the invention is based on the object of providing a plate element for a plate heat exchanger which, on the one hand, can be produced with low effort, has a comparatively low weight and yet has, Apart from the usual heat exchange properties, also excellent enthalpy exchange properties. Apart from sensible heat, respectively temperature, also moisture, respectively water vapour, must be transferred, respectively exchanged, between different fluid flows.

This object is achieved according to the invention by means of a plate element for a plate heat exchanger according to claim 1.

Such a plate element can be produced with low effort with the desired properties.

The membrane layer of the plate element according to the invention can advantageously be designed as a plastic membrane layer.

The at least one carrier layer of the plate element according to the invention can be formed with comparatively low effort as a woven fabric or non-woven fabric layer, the necessarily perforated structure of the carrier advantageously being obtained by the choice of the materials mentioned. support layer.

In order to provide the plate element according to the invention with the predeterminable mechanical strength and the desired spatial structure with low engineering-construction effort, it is advantageous if the at least one support layer of the plate element is made of a thermally deformable material.

In an advantageous form of production of the plate element according to the invention, it is formed as a three-layer laminate arrangement with an additional support layer, which is arranged on the side of the membrane layer facing away from the first support layer. and whereby predeterminable mechanical strength and spatial structure can also be provided to the plate element and are maintainable.

A full-surface, point-like, strip-shaped or grid-like connection of each support layer to the membrane layer can be achieved by means of material properties of each support layer and/or of the membrane layer. In this case, no additional connecting means, such as adhesives or the like, are then required.

Alternatively, however, it is also possible to realize the full-area, punctual, strip or grid-like and adherent bonding between the membrane layer and each support layer by means of a bonding agent, preferably by means of a hot-melt adhesive. melt.

The nonwoven fabric layers can advantageously be made of a polyester nonwoven fabric.

This polyester nonwoven fabric should conveniently have a weight between 20 and 80, preferably about 50 g/m2.

In order to ensure the permeability of the polyester nonwoven fabric for liquid and thus the evacuation of liquid to the membrane layer, it is advantageous if the polyester nonwoven fabric is hygroscopically adjustable.

This can be conveniently achieved in that the polyester nonwoven fabric has a coating made of a zeolite and a binding agent.

The enthalpy transfer properties of the plastic membrane layer can be realized with comparatively low effort if the plastic membrane layer is formed of a polymer or polyurethane material.

Conveniently, the above-described plate elements can be folded, welded or glued at their edges, so that they can be joined with extremely low engineering-construction effort to form a plate exchanger.

[0020] In a method according to the invention for producing a plate element for plate heat exchangers according to claim 1, a laminate arrangement is made, which is at least two layers, of one membrane layer, preferably one layer of plastic membrane, and at least one support layer, preferably in each case a layer of non-woven fabric on both sides of the plastic membrane layer, in a form, according to which this flat laminate arrangement is provided, by means of a single deformation step, of the spatial, load-bearing and maintainable structure provided for the plate element. In this deformation step, those tools can be used which are also used for plate elements made of materials known from the state of the art. Therefore, costly modifications etc. are not necessary. of existing production facilities.

Advantageously, an adhesive bond is simultaneously created between each support layer and the membrane layer in the deformation step. The effort to produce the plate element according to the invention can therefore be comparatively low.

The deformation that is accompanied by the establishment of the adhesive bond takes place by pressing at a maximum of 160 degrees C. This ensures that the enthalpy transfer properties of the membrane layer are not affected.

The hygroscopic adjustment of the support layers, respectively made of non-woven fabric, can be carried out with comparatively little effort, because the support layers, respectively made of non-woven fabric, are provided with a coating, which is made of a zeolite and a binding agent. , by means of an immersion or spray procedure.

Due to the hygroscopic adjustment of the support layers, respectively made of non-woven fabric, it can be achieved, provided that a hydrophilic adjustment of the support layers, respectively made of non-woven fabric, can be achieved, that water deposited on the support layers, respectively made of fabric non-woven, is evenly distributed on the surface of the support layers, respectively of non-woven fabric, whereby the permeability of the plate element is maintained overall.

In the following, the invention will be explained in detail on the basis of a manufacturing form with reference to the drawing, the sole figure of which shows a principle representation of a plate element according to the invention that can be joined to other plate elements of the same type to form a plate heat exchanger.

The plate element 1 shown in the single figure is not to scale in this figure, but is merely shown in principle. In the production example of the plate element 1 according to the invention, which is shown in the figure, it is formed as a three-layer laminate arrangement 1.

This three-layer laminate arrangement 1 includes a plastic membrane layer 2 arranged centrally in the laminate arrangement 1, a first non-woven fabric layer 3 arranged, in the figure, above the plastic membrane layer 2 and a second layer of non-woven fabric 4 arranged, in the figure, below the layer of plastic membrane 2.

Via the plastic membrane layer 2 enthalpy can be transferred between two fluid flows not shown in the figure, one of the fluid flows flowing above the plate element 1 and the other of the two fluid flows below the plate element 1 .

The plastic membrane layer 2 is made of a polyurethane material in the production example shown.

The first non-woven fabric layer 3 and the second non-woven fabric layer 4 are made of a thermally deformable non-woven material, a polyester non-woven fabric in the production example shown. The polyester non-woven fabric has a weight of 50 g/m2. In addition, the polyester nonwoven fabric is configured in a hygroscopically adjustable manner, the polyester nonwoven fabric being provided with a coating consisting of a suitable zeolite and a binder.

By means of the two non-woven fabric layers 3, 4 it is achieved that the plate element 1 obtains a predeterminable mechanical strength and a spatial structure. This mechanical resistance and this spatial structure can be maintained during the time of use of the plate element in a plate heat exchanger.

Between the plastic membrane layer 2 on the one hand and the nonwoven fabric layers 3, 4 on the other hand, a full-surface adhesive bond is provided. This can be realized in the production example, which is shown in the single figure, of the plate element 1 by material properties of the polyester non-woven fabric forming the non-woven fabric layers 3, 4 and/or by material properties. plastic membrane layer material 2.

Alternatively, it is possible to carry out this adhesive bonding by means of a bonding agent, preferably by means of a hot melt adhesive.

In order to produce a plate heat exchanger made of the plate elements 1 described above, these can be folded and welded at their edges. In this way flow channels are created, which are separated from one another, for one fluid flow and for the other fluid flow. Through the plate elements 1 enthalpy can be exchanged between the fluid flows.

To produce the plate element 1, a three-layer planar laminate arrangement 1 is first produced. In this case, the plastic membrane layer 2 is placed on the lower non-woven fabric layer 4, and the non-woven fabric layer 1 on the plastic membrane layer 2. Then the plate element 1 is made by means of a single process step that serves both for the deformation, i.e. the creation of a spatial structure for the plate element 1, and for the full-area bonding between the plastic membrane layer 2 on the one hand and the two layers non-woven fabric 3, 4, on the other. For this process step, the same tools can be used that are also used in the production of conventional plate elements.

In addition, a maximum temperature of 160 degrees C is not exceeded in this process step. This ensures that the plastic membrane layer 3 maintains its necessary enthalpy permeability for proper operation.

In order to hygroscopically adjust the two layers of nonwoven fabric 3, 4, they are provided with a coating made of a zeolite and a binding agent, which coating can be produced by means of a dipping or a spraying process.

Claims (17)

1. Plate element for a heat exchanger, which is an arrangement (1) of at least two layers, with one layer (2), by means of which enthalpy can be transferred between two fluid flows separated by the plate element (1 ), and at least one perforated layer (3, 4), characterized in that the plate element (1) is formed as a laminate arrangement (1), in that the layer serving for enthalpy transfer between the two fluid flows separated by the plate element (1) is formed as a plastic membrane layer (2), because the at least one perforated layer (3, 4) is formed as a support layer (3, 4) made of a perforated material and deformable, and in that by means of the at least one support layer (3, 4) the plate element (1) can be provided with a predetermined mechanical strength and a spatial structure and these are maintainable. Plate element according to claim 1, whose membrane layer (2) is formed as a plastic membrane layer (2). Plate element according to claim 1 or 2, the at least one support layer (3, 4) of which is formed as a woven or non-woven fabric layer (3, 4). Plate element according to one of Claims 1 to 3, the at least one support layer (3, 4) of which is made of a thermally deformable material. Plate element according to one of Claims 1 to 4, which is a three-layer laminate arrangement (1) with an additional support layer (4), which is arranged on the side of the membrane layer (2) facing opposite the first support layer (3) and by which the plate element (1) can be provided with a predeterminable mechanical strength and spatial structure and these are maintainable. Plate element according to one of Claims 1 to 5, in which a full-area, punctual, strip or grid-like connection of each support layer (3, 4) to the membrane layer (2) it is achievable by material properties of each support layer (3, 4) and/or of the membrane layer (2). Plate element according to one of Claims 1 to 5, in which a full-area, punctual, strip or grid-like connection of each support layer (3, 4) to the membrane layer (2) it is achievable by means of a bonding agent, preferably a hot melt adhesive. Plate element according to one of claims 3 to 7, in which each non-woven fabric layer (3, 4) is formed from a polyester non-woven fabric. 9. Plate element according to claim 8, in which the polyester non-woven fabric has a weight between 20 and 80, preferably 50 g/m2. 10. Plate element according to claim 8 or 9, wherein the polyester non-woven fabric is hygroscopically adjustable. Plate element according to claim 10, in which the polyester nonwoven has a coating made of a zeolite and a binder for hygroscopic adjustment. Plate element according to one of Claims 2 to 11, in which the plastic membrane layer (2) is made of a polyurethane material or a polymer material. Plate element according to one of claims 1 to 12, which can be folded and welded or glued at its edges, and thus can be joined to other plate elements (1) of the same type to form a heat exchanger of plates. Method for producing a plate element (1) for plate heat exchangers according to claim 1, in which an at least two-layer laminate arrangement made of a membrane layer, preferably a membrane layer, is made of plastic (2), and of at least one support layer (3, 4), preferably in each case a layer of non-woven fabric (3, 4) on both sides of the plastic membrane layer (2), in flat shape and this flat laminate arrangement (1) is provided, through a deformation step, with the spatial, load-bearing and maintainable structure. Method according to claim 14, wherein an adhesive bond is also created between each support layer (3, 4) and the membrane layer (3) in the deformation step. 16. Process according to claims 14 or 15, whose deformation step is carried out at a temperature <160 degrees C. Method according to one of Claims 14 to 16, in which each support layer (3, 4) is provided with a coating, which is made of a zeolite and a binding agent, by means of a dipping or spraying method.