FR2624594A1 - ENERGY RECOVERY - Google Patents

Abstract

The invention concerns a heat-enchanger comprising at least one cross-flow heat-exchanger module (M) having two alternately attached sets of plates (1a, 1b). Each plate (1a, 1b) has internal channels (5a, 5b) for gas circulation which extend longidutinally, parallel and unidirectionally inside the plate (1a, 1b). The channels (5a, 5b) in one set of plates (1a, 1b) are aligned in the same direction and at a predetermined angle to the direction of alignment of the channels (5a, 5b) in the other set of plates (1a, 1b). According to the invention, a certain number of plates (1a, 1b) of said module have at least one opening (E), obtained in particular by cutting, which facilitates heat exchange between the gas streams. The invention is useful in ventilation or air-conditioning installations in enclosed spaces such as offices, cinemas, theatres, conference rooms, indoor stadia, private homes, apartment blocks, factories, etc.

Description

<U> Reverberator </ U>.

The subject of the present invention is a new energy recuperator, in particular being used in ventilation or air-conditioning installations of enclosures, such as, for example, offices, cinemas, theaters and this conference, sports halls, individual dwellings. or collective, factories, etc., whose internal temperature is different from the outside temperature.

It is known that in the ventilation or air-conditioning installations, the exhaust air, heated or cooled, is extracted by a fan through a network of ducts, while fresh air, respectively cold or hot, is injected. where results in a loss of calories.

Numerous energy recuperators have therefore been designed, in particular to reduce the energy losses resulting from the implementation of such ventilation or air conditioning installations. The basic idea is to recover some of the lost calories transported by the air coming out of the enclosure, to transfer it to the air entering the enclosure.

Such known recuperators generally comprise one or more energy exchange modules, capable of being traversed by two gas streams circulating crosswise, and intended for the transfer of a portion of the calories from one of said oily streams to the other. .

Numerous designs have been envisaged for the realization of these exchangers, the problem of searching for materials, and a configuration ensuring optimum efficiency (amount of energy recovered and transferred), and satisfactory overall strength.

The solution chosen for the realization of these energy exchanger modules consists of the assembly of plates having an internal configuration allowing the cross circulation of the two gas streams.

Thus, a module with two sets of plates alternately contiguous, each plate being provided with internal gas circulation channels extending substantially longitudinally, parallel and unidirectionally within said plate, canals. One of the sets being oriented in the same direction, forming with the direction of orientation of the channels of the plates of the other of the two sets a predetermined angle.

However, such plates generally comprise two outer walls, between which are defined the aforesaid channels, and it is understood that the two gaseous streams flowing, in a cross manner, in two consecutive plates, are in fact separated by a double thickness, which decreases the efficiency of the exchanger.

The present invention aims to solve the aforementioned drawbacks by proposing an energy recovery of a new design, improved efficiency, and the mechanical strength remains satisfactory.

The solution, according to the present invention, to solve this technical problem consists of a recuperator of the aforementioned type, characterized in that a number of plates of the energy exchanger module present at least one recess, obtained in particular by cutting, and allowing thus a better energy exchange between the gaseous currents.

According to a first embodiment of the invention, all the plates of one of the assemblies forming said energy exchange module have at least one such recess.

According to another embodiment of the invention, all the plates constituting the energy exchange module, with the exception of the end plates, have at least one such recess; two consecutive plates being further separated by a sheet made of a gas-impermeable material, chosen in particular according to its thermal characteristics, optionally bonded to one. of these two plates.

According to a particular characteristic of the invention, the exchanger module further comprises means for modifying the flow rate of the gas streams and / or for creating a turbulence of the gases passing through it, these means being preferably arranged at the recessed portions of the plates.

 According to a particular embodiment of the invention, the aforementioned means for modifying the flow rate of the gas streams and / or for creating a turbulence of the gases passing through the module, are formed by an element of the same constitution as the plates, which can be reported or obtained during the aforementioned cutting plates to create at least one recess.

The invention will be better understood, and other objects, features, details and advantages thereof will appear more clearly on reading the following explanatory description, made with reference to the appended diagrammatic drawings, given solely for purposes of illustration. non-limiting example illustrating several currently preferred embodiments of the invention, and in which - Figure 1 is a general perspective view, in perspective with tear, of a heat exchanger module of a flow recuperator crossed according to the state of the art; FIG. 2 is an exploded partial view of an energy exchanger module of a recuperator according to a first embodiment of the invention, showing three plates, one of which is recessed; FIGS. 3a to 3d illustrate four alternative embodiments of a recessed plate which is shown in FIG. 2 or FIG. 4; and FIG. 4 is an exploded partial view of an energy exchanger module of a recuperator according to a second embodiment of the invention, showing three recessed plates, each being provided with a separation sheet.

FIG. 1 shows therefore an energy exchanger module of a recuperator according to the state of the art closest to the invention. As we have seen, the energy recuperators known hitherto generally comprise one or more energy exchange modules arranged and assembled in various arrangements. The module M shown in Figure 1 comprises two sets of plates 1a, 1b, assembled in a contiguous manner, for example by gluing or by means of threaded rods passing through the plates, and bolts.

Each plate 1a, 1b comprises two identical and spaced parallel outer plane walls 2, 3, extending substantially parallel, between which are arranged a set of parallel, spaced parallel longitudinal walls 4a, 4b forming an internal channel network 5a, 5b, gas flow extending unidirectionally within each plate 1a, 1b, respectively.

The walls 4a, 4b are arranged, in the example shown, transversely to the outer walls 3, 4, of each plate, to provide better rigidity.

However, this is only a preferred embodiment, the walls may also be arranged at any sharp angle with the outer walls 3, 4, supra.

The plates 1a, 1b may be made of various materials, but, for reasons of rigidity, it will be preferred to use rigid plastics; such as for example polyethylene or polycarbonate. In this case, the plates can be obtained relatively easily by extrusion.

As shown in FIG. 1, the plates 1a, 1b are assembled alternately, the channels 5a of the plates 1a being oriented in a direction substantially normal to the direction of orientation of the channels 5b of the plates 1b.

Again, this is only an exemplary embodiment, since the angle formed between the orientation directions of the channels 5a and 5b can of course be different from a right angle.

Thus, as is understood, the module M is capable of being traversed by two gaseous currents flowing in a cross manner, along directions A and <B> 8 </ B> which correspond to the respective directions of orientation of the channels 5a, -5b, plates 1a, 1b.

This module therefore allows the recovery and transfer of calories from one of the gaseous streams, for example hot exhausted air leaving a superheated enclosure, to the other gaseous stream, for example fresh air entering the room. pregnant. It is obvious that the two gaseous streams should in no case be brought into contact, and therefore will be provided module sealing means, well known to those skilled in the art.

It will be noted that all the plates 1a, 1b, forming the module M are identical, and present in the example shown the shape of a square. Generally, the plates will have a general shape of a regular polygon symmetrical with respect to a diagonal, such as a square, a hexagon or a. Thus, the manufacture of the module requires only the manufacture of a single type of plate. The plates can also be different, for example in the form of a rectangle.

Referring to Figures 2 and 4, will now be described. The characteristics of an energy exchanger module of a recuperator according to two embodiments of the invention. The general principle governing these new designs is that it seeks a better heat exchange between the streams or gaseous currents passing through the module, without harming the overall rigidity <B> of </ b> the latter. Indeed, as understood with reference to FIG. 1, the gaseous currents passing through two successive plates 1a-1b are separated by a double thickness corresponding to the thickness of the outer wall 3 of the plate 1a and to the thickness of the outer wall 2 of the adjacent plate-1b.

The originality of the invention consists in that a number of plates of the exchanger module M present at. less a recess, obtained in particular by cutting, which will allow a better heat exchange between the gas streams, by removing the double thickness mentioned above. The thermal energy gains will be all the more important as said recesses will be important.

Thus, according to a first embodiment of the invention, represented in FIG. 2, all the plates 1b of one of the two aforementioned assemblies forming the exchanger module M have at least one recess E, extending over a major part The surface of the plate.

The shape of this recess, which will preferably be obtained by cutting a plate 1b, as described with reference to FIG. 1, may be quite arbitrary, for example circular (FIG. 2), rectangular, square, polygonal, etc. The recess recess can be any and will depend essentially on the dimensions of the plate. However, these recessed portions obtained by cutting, in the case where the plates are identical, are chosen asymmetrical shapes with respect to the plane perpendicular to said plates, containing the diagonal relative to which said plates are symmetrical.

According to a second embodiment of the invention, represented in FIG. 4, all the plates 1a, 1b constituting the heat exchanger module M, with the exception of the end plates (not shown), have at least one recess E; two consecutive plates 1a, 1b, being separated by a sheet 7 covering The or the aforementioned recesses, and made of a gas-impermeable material, chosen according to its thermal characteristics, for example treated or untreated paper, treated fabric or no, nonwoven, metallized plastic films or not, or metal films, in particular aluminum.

This sheet 7 can be inserted between two plates, then sealed, for example by gluing or welding, to one of. two plates, when assembling the plates in module, or previously sealed, for example by gluing or welding, on one of these plates before assembly.

The nature of the sheet 7 can also be selected according to particular objectives relating to the separation of the gas streams. Thus, it is possible to choose a sheet that is impermeable to gases, but that will allow moisture to pass through, in particular to intervene in the humidity level. This particular aspect of the invention is not limited to the energy exchanger module of the type shown in FIG. 7, and which constitutes the state of the art closest to the invention, but can be transposed to any type. energy exchanger module, and in particular exchangers comprising rigid U-shaped separation plates.

In the example shown, the treated paper sheet 7 is sealed by gluing, before assembly, to one of the outer walls of each plate 1a, 1b, so that only one wall (in fact constituted by the sheet 7 ) separates two successive plates 1a, 1b.

According to a particular characteristic of the invention, which applies to the two embodiments described above, the recuperator module M further comprises means for modifying the flow rate of the gaseous currents and for creating a turbulence of the gases passing through it, and these means are preferably arranged at the recessed portions E of the plates.

It is known in fact that variations in flow, or turbulence of the gases inside the module make it possible to obtain a significant increase in the heat exchange between the gas passing through the module.

The aforementioned means for modifying the flow rate of the gas streams and / or for creating a turbulence of the gas passing through the module are preferably formed by an element of the same constitution as a plate, that is to say having two parallel outer walls. in which a network of internal channels is arranged.

These means may be shaped differently from the plates, and made for example in the form of a strip or bar of cellular plastic material or not.

FIGS. 3a to 3d show four embodiments of recessed plates comprising such means respectively referenced 8a to 8d.

As seen, these means can be reported (8b) and positioned during the assembly of the plates to constitute the module, or obtained during the cutting of the plate (8a, 8c, 8d). The shape and the arrangement of the elements 8a, 8b, 8c, 8d can be arbitrary, for example rectilinear (8b, 8c) or inverted V (8a).

When the internal channels of the elements 8a, Hb; 8c, are open, there is creation at the entrance and exit of these channels of turbulence gases passing through these elements. Part of the internal channels of these elements may be partially or completely closed off (FIG. 3d) and flow variations of the gaseous currents passing through the plates are thus created. Such variations can also be obtained by plugging some of the internal channels 5a, 5b, plates, at the most appropriate places, for example on the contour of the recessed portions of the plates.

The advantages of the energy recovery devices which have just been described are numerous. They can be obtained easily, at low cost, from the usual components of existing recuperators; They allow an improved yield with a separation of the two gaseous flows or currents, and an overall rigidity unchanged.

- They can be large as of. small dimensions and their applications are not limited by these dimensions.

It should be noted that the energy recuperator according to the present invention is not limited to the only applications described above. In particular, such an energy recuperator can be used in particular as a condenser, for example in association with machines such as tumble dryers.

Claims (10)

<B> <U> CLAIMS </ U> </ B> 1. Energy recuperator intended in particular for use in ventilation or air-conditioning installations of enclosures, such as, for example, offices, cinemas, theater and conference rooms, sports halls, individual or collective dwellings, factories, etc., of which the internal temperature is different from the outside temperature of the type comprising at least one energy exchanger module capable of being traversed by two gaseous currents circulating crosswise, and intended for the transfer of a portion of the calories one of said gaseous streams to the other, said modulë comprising those sets of plates (la, 1b) contiguous alternately, each plate being provided with channels (5a, 5b) internal gas circulation extending substantially Longitudinally, parallel and unidirectionally within said plate, the channels (5a) of the plates (la> of one of the sets being oriented along an in a direction forming, with the direction of orientation of the channels (5b) - of the plates (1b) of the other of the two sets a predetermined angle, characterized in that a number of plates of said module present to the Kidney a recess <B> CE), </ B> obtained in particular by cutting and allowing a better heat exchange between the gas streams. 2. Energy recuperator according to claim 1, characterized in that all the plates (1b) of one of the aforesaid sets forming the exchanger module have at least one recess CE) preferably extending over a major part of The surface of the plate. 3. energy recovery device according to claim 1, characterized in that all the plates constituting Le mdduLe exchanger above, except the end plates, have at least one recess CE); two consecutive plates (1a, 1b) being separated by a sheet (7) made of a material impermeable to gas, chosen in particular according to its thermal characteristics, and optionally sealed, for example by cottage, on one of these two plates . 4. energy recovery device according to one of claims 1 to 3, characterized in that said module further comprises means (8a, 8b, 8c, 8d) for modifying the flow rate of the gas streams and / or to create turbulence gases therethrough, and in that these means are arranged at the recessed portions of the plates. 5. Energy recovery device according to claim 4, characterized in that the aforementioned means are formed by an element of the same constitution as a plate, which can be attached or obtained during the aforementioned cutting of the plate to create at least a recess. 6. energy recovery device according to one of claims 1, 2, 4 or 5, characterized in that all the aforementioned non-recessed plates comprise two outer walls (23) planar identical and spaced extending substantially parallel and between Which are arranged, preferably transversely, a set of parallel walls (4) parallel and spaced forming the aforementioned internal channels (5a, 5b). 7. Energy recuperator according to claim 6, characterized in that the aforementioned non-recessed plates are identical, and have a general shape of a regular polygon symmetrical with respect to a diagonal, such as for example a <I> square, </ I> or a diamond. 8. energy recovery device according to one of claims 6 or 7, characterized in that the aforementioned hollow plates are obtained by cutting the aforementioned non-recessed plates. 9. Energy recuperator according to claim 8, characterized in that the aforementioned cut-outs of the recessed plates are symmetrical with respect to the plane perpendicular to said plates containing the diagonal relative to which said plates are symmetrical. 10.. Energy recuperator according to claim 3, characterized in that the aforesaid sheet (7) is made of a material chosen from treated or untreated paper, treated or untreated fabric, nonwoven fabric, metallized or non-metallized plastic films or metal films, in particular alumihium.