FR2716527A1 - Heating procedure for building - Google Patents

Abstract

A door (2) is mounted in a frame (1) fixed to a wall (21). The door has vertical side members (24,25), horizontal top and bottom members (3) and front and rear surface panels (4,35). A heating unit (6) is located within the door. The heating unit (6) consists of a substrate (8) of insulating material which carries an electrically conducting film (9). The conducting film (9) is arranged as a series of horizontal bands (26) which are connected to a power source (15,17) by vertical copper collectors (27,28) and flexible cable (18).

Description

METHOD AND DEVICE FOR HEATING PREMISES BY
RXYONNEMENT, ESPECIALLY BY HEATING DOOR
The present invention relates to the design and production of opening closings of premises, such as doors or windows, which are provided with a heating device so that they can be used to heat the rooms which they delimit. . In particular, using for this purpose the interior doors of buildings, closing for example living rooms, is advantageous in particular since one can avoid the usual means of heating, bulky and unsightly, and free the walls of radiators and other convectors. However, the invention also relates, and more generally, to a method of heating premises and to a heating device for its implementation, method and device which are capable of adapting under various forms of applications in industry, and not only in the context of doors or other heated windows.

 It has already been proposed to produce a door leaf so that it behaves like a support for a heating means thus made discreet, by placing inside the body of the leaf, an armored electrical resistance, arranged in a serpentine in notches formed in internal walls constituting a cellular core, the latter being interposed between two facing panels materializing the lateral faces of the opening.

When it is electrically supplied, the wire resistance releases heat which is used in part to heat at least one of the facing panels, which in turn transmits this heat into the surrounding space. It is estimated that the equivalent of a means of radiant heating can be obtained in this way in the infrared wavelength ranges.

 In this known design, if the air in the cells of the internal core is still air which does not circulate, the transmission of heat from the electrical resistance to the facing panel is effected by radiation is very insufficient. In fact, if the current intensity in the electrical resistance is increased in order to increase the heat flux per unit of surface area of the opening, a limit value is quickly reached from which the risks of combustion of the opening become unacceptable, if only in relation to the safety standards in force. To obtain sufficient heating capacity, one must therefore count on a transmission of the heating flow by convection, thanks to an air circulation created between openings at the top and bottom of the vertical wall of the door. But again, it appears impossible to obtain sufficient heating to meet the current needs of normal sized living rooms, having regard to the surfaces offered by the doors, without completely transforming these doors, in thickness and in appearance, whereas 'in addition we are faced with the same fire risks as above.

 The invention proposes to remedy these drawbacks of the prior art by using a heat source of a different type, although also operating by Joule effect under electrical supply, and more precisely with surface resistive elements, selected , adapted and / or mounted to integrate as a heating element or heat source in an opening element such as a door opening element, and thus provide the desirable calorific power, in a heating mode proceeding in practice exclusively by radiation thermal, without having recourse to convection phenomena to ensure thermal exchanges in the vicinity of the heating element.

 Advantageously, it makes it possible to take full advantage, in this new application, of the specific properties of surface resistive elements, such as those already known in the trade, in the form of conductive glasses, enameled sheets or organic matter films with electrically conductive coating. The conductive surface then forms a resistive layer with low linear resistance which distributes over an extended surface the electrical intensity and therefore the power of thermal emission, this emission being in a range of wavelengths outside the visible spectrum, corresponding to that of so-called obscure radiation, ie for example in wavelengths between 50 and 300 micrometers.

 By this, the invention is reflected in particular by a new mode of heating of living rooms (or other premises), which is capable of diffusing a thermal energy large enough to meet the heating needs of premises in a large number of cases. , under power supply at the usual voltage of residential premises, thanks to a transmission of the heat produced by the Joule effect which is ensured exclusively, or in practice almost exclusively, by direct conduction of the emitted thermal radiation. To this end, the invention provides, as opposed to what is known of current radiant panels, means aimed at preventing the occurrence of convection phenomena in the immediate vicinity of the surface resistive element.

 According to the invention, an interior building door can thus be equipped, within the door at the rear of a thermally permissive facing panel, with at least one heating plate with one or more surface resistive elements, representing together, over all or part of the height of the door, a surface emitting thermal radiation extending over at least 30%, and preferably over at least 60% of said plate, so that the latter preferably provides a power at least 500 W per square meter of surface.

 The heating plate advantageously consists of a flat insulating substrate, coated on at least part of its surface, and preferably on a major part of its surface, on the front face of said plate, of a deposit of electrically conductive material, forming a surface-resistivity element. A thin and light substrate made of organic material, such as a polyester of the polypropylene type for example, is to be preferred to enamelled metal sheets, to avoid parasitic noises resulting from thermal dilations in operation. The conductive layer can be obtained in a known manner, for example by screen printing using a conductive composition such as a paste based on graphite, silver or nickel-chromium.

 According to a preferred embodiment of the invention, the plate is thermally coupled without air gap with the facing panel by means of a thermal radiation diffusing element made of a material which is good conductor of heat, mounted opposite front of the heating plate covering the entire surface of the conductive deposit (s).

 Insofar as the best materials for this are generally of a metallic nature, there is then interposed, between the heating plate, on its front face with a conductive surface, and the diffuser, an insulating layer of dielectric material. It will be noted that a fine, flat and flexible layer is sufficient to ensure satisfactory electrical insulation without unduly affecting mechanical and thermal contact. It may in particular be a continuous flat sheet of glass fabric, mica, or any equivalent material, making it possible both to avoid electrical short-circuits and to maintain planar material contact opposing the convection losses.

 As a diffuser, it is advantageous to use a flat sheet of metallic nature, in aluminum or light alloy in particular, not perforated but the faces of which are preferably not united, for example a sheet embossed or otherwise formed to increase the exchange surface. thermal conveying heat on the front of conductive deposits.

 Rather than actually equipping a door with such a heating device, it is also possible, as a variant of the invention and more generally, to ensure the heating of premises by having a vertical partition of said premises, a heating plate with element (s). with surface resistivity, at the rear of a facing panel permissive for the thermal radiation which it emits by Joule effect under electrical power and against which it is pressed in a situation of direct thermal transfer by conduction, excluding thermal transfer by convection, so in practice with no air gap between the two.

 According to a preferred embodiment of the invention, the flat plate with surface electrical conductivity emitting thermal radiation by the Joule effect is interposed between a thermally insulating element, preferably also constituting a mechanical support for said plate, and said facing panel, in an arrangement such that the conductive surface of said plate is electrically insulated from the panel and that the emitted thermal radiation is directly transmitted to the part to be heated through the facing panel. A plate comprising a conductive deposit on at least 30%, and preferably 60% of its surface, and covering for example about half of a door of usual dimensions, makes it possible to ensure satisfactory heating under a current electrical voltage of 220 V, the plate being thermally coupled to the facing panel by means of a thermal radiation diffusing element made of a material which is a good conductor of heat interposed flat in direct contact with one another as already mentioned above. before.

 It is advantageous to group the heating plate, the insulating layer, and the metal plate on the front face constituting the diffuser, so preferably that the thermally insulating element also constituting mechanical support, in a self-supporting unitary unit of generally flat shape and of low thickness, which can be prefabricated. Such a heating device according to the invention can be intended to be inserted into a recess of corresponding shape made, of manufacture, in the body of an opening, using where appropriate as a mechanical support insulating a filling material, such as a polyurethane foam or equivalent, helping to wedge the plated assembly in mechanical contact against the facing panel.

 We will now describe in more detail particular embodiments of the invention which will make it better understand the essential characteristics and the advantages, it being understood however that these embodiments are chosen by way of example and that they are in no way limiting .

Their description is illustrated by the accompanying drawings, in which
- Figure 1 is a perspective view with cut-away, of a door leaf provided with a radiation heating device, according to a first embodiment of the invention;
- Figure 2 shows an exploded cross section of the opening of Figure 1
- Figure 3 is a partial schematic plan view of the heating plate in a self-supporting unitary assembly
- Figure 4 is a partial sectional view of the door opening of Figure 1, according to an alternative embodiment;
- Figure 5 is a view is a partial view similar to Figure 1, illustrated on a larger scale.

 For reasons of clarity, the same elements have been designated by the same references and the representation of the drawings is schematic.

 The door shown in fig 1 comprises a frame 1, sealed in a partition or a vertical wall 21, on which is mounted by hinges 22, an opening 2 which is provided with a heating device constituting a unitary self-supporting assembly according to invention. This device is integrated in the door leaf in the upper part. It is generally flat and thin, and extends over at least half of the surface of the opening.

 As shown in Figures 1 and 5, the opening consists of a body formed of a rectangular frame, comprising two vertical uprights 24-25, rigidly connected by crosspieces 3, and two facing panels 4 and 35 materializing the visible sides of the opening. In accordance with the figures, a unitary heating assembly 6 is placed in the body of the opening, in direct thermal contact by its front surface, producing thermal radiation, with the facing panel 4. In the case of FIG. 4, two similar heating unit assemblies 6a and 6b are placed symmetrically in the body of the leaf, in direct thermal contact with each of the facing panels 4 and 35 respectively.

 In practice in the particular case described, each heating device is inserted behind a facing panel, between the latter and a filling mass 7 made of an insulating material, such as mineral wool or polyurethane foam, which, while providing additional mechanical support maintaining the flatness of the heating device in contact with the corresponding facing panel, serves as flow directional by unilaterally blocking the heat flow and focusing it forward. In this way, the facing panel plays the role of a thermally permissive panel, allowing itself to be passed directly through by the thermal radiation emitted in operation by the device 6.

 As shown in FIGS. 1 and 35 in particular, the heating assembly 6 (or each heating assembly 6a or 6b) essentially comprises a heating plate 30 formed, according to the example shown, by deposition, on a substrate made of insulating material 8, d 'an electrically conductive layer 9 shaped according to an appropriate drawing, here in the form of a ladder.

 The substrate 8 being in the example considered a polypropylene sheet on which the resistive layer 9 is screen printed, this latter forms a series of horizontal bands 26 of graphite deposition, wider than the intervals devoid of conductive deposition which separate them , and connecting in parallel two vertical lateral bands, respectively covered with copper deposits 27-28 forming current collectors which terminate in electrodes connected to an electrical connection box 29. In the arrangement illustrated in FIG. 1, the box 29 being located at the top right, on the side of the hinges 22, the collecting strip 27 located to the left of the opening is connected to the box by means of an insulated electrical wire 31, which can be easily accommodated in the thickness of the door, possibly in a groove provided for this purpose in the filling mass 7.

 As can be seen in the figures, the conductive strips 9 cover approximately 70% of the surface of the insulating substrate, which itself extends over an area substantially greater than 50% of that of the opening 2. With strips sufficiently close together, or even strips joining in a continuous deposition, surface thermal emission capacities of up to 3000 W per square meter are produced.

 A layer of dielectric material 10 is applied to the front face of the substrate 8 comprising the resistive layer 9. It is a sheet of glass silk or mica 0.3 to 1.5 mm thick, by example 0.5 mm.

 Above the layer 10 is applied a metal plate good conductor of heat ll which, in the example shown, is an aluminum sheet, 0.5 to 1 mm thick, whose specific surface is increased by embossing. This plate plays the role of a heat diffusing element. It improves heat exchange by simple conduction between the heating element 9 and the facing panel to be heated 4, being in intimate thermal contact with one and the other by a large heat exchange surface.

 Behind the heating plate 30, on the back of the substrate 8, provision has been made for placing a flat and united metal sheet 5, with the interposition of a layer or intermediate sheet of dielectric material 32, similar to layer 10, which completes the insulation. electrical already provided by the substrate 8. The sheet 32 is adapted in order to improve both the quality of the flat mechanical support and that of the thermal coupling by constituting an additional absorbent element returning the heat flow towards the front of the heating device.

 In accordance with FIG. 3, the elements 5 to it are assembled in a self-supporting assembly made unitary due to the mutual fixing, along their periphery, of the metal plates 5 and II, so that the latter enclose the surface resistive elements in an enclosed space with respect to the ambient air and devoid of any air gap likely to allow thermal transfers by convection, at the same time as they provide mechanical resistance ensuring the permanence of the flatness and good quality thermal contact. In the example shown, this fixing is obtained by crimping produced by folding in 12 the edges of the plate 11 on the edges of the plate 5 around the substrate 8 and insulating insulating layers 10 and 32. However, it is often more advantageous to carry out this fixing by welding with a wheel or by gluing.

 In the final stage of the manufacturing process of the heated door which has just been described, the complete heating device is mounted in the door leaf 2, which arrives from the joinery with its facings 4 and 35 assembled on a frame of which only the cross member upper 3 has not been mounted. A rebate 13 formed in the vertical uprights 24 and 25 of the frame serves as a guide for positioning the heating assembly 6. Once inserted therein (the two symmetrical elements being inserted at the same time if necessary), the insulating filling 7 in the vacuum remaining between the facing panels 4 and 35. The upper cross member 3 of the frame is then attached and then fixed.

 Returning to FIG. 1, it can be seen that the two terminals of the resistive layer 9 are capable of being connected by means of a spiral connection cable 18, at the outlet of the connection box 29, via a thermostat 15 and via a manual switch 16, to an alternating current source such as a socket on the mains 17.

 As already pointed out in the introductory part of this description, the invention as it has just been described in a particular embodiment, essentially consists in using as heating elements 9 one or more surface resistive elements arranged in the same plane in a situation of direct transfer by conduction through the facing panel of the door, for thermal radiation in dark wavelengths emitted when this or these resistive elements are supplied with electric current.

 In the application to the heating of premises such as living rooms or offices, the electrical supply is usually carried out at a voltage of 220 Volts.

 The use of surface resistive elements makes it possible to ensure the emission of thermal radiation without having to fear an overheating of the electrically conductive surfaces, because, unlike the wired electric resistances used in the past in this kind of application, the linear resistance is extremely low for a high current intensity, representing a high electrical power capable of emitting significant thermal energy by the Joule effect.

 For example, knowing that it is necessary to avoid overheating and to remain at temperature at the facing panel below the limit imposed by safety requirements, a resistive element covering a surface of 1.5 m2 by its conductive deposit to be able to satisfy all the heating needs of a room of habitual dimensions and ensure the full comfort of the people brought to reside in the room.

 Indeed, the films with conductive deposition produced by current technologies allow powers of up to 3000 W / m2, while we prefer to be satisfied with a power of between 300 and 2000 W / m2 in the context of the 'invention.

 It is understood that such a heating element surface is not difficult to integrate in accordance with the invention in a door of the room.

 In the embodiment illustrated by the figures, provision has been made to use as heating elements conductive deposits on a film of organic material, the deposits being conventionally in the form of graphite deposition strips arranged in parallel between two lateral strips current collection.

The entire conductive deposit covers an area of the order of 70% of the complete area of the organic matter film. The latter has the advantage of being able to be easily cut out in the interval separating two successive strips so as to obtain, by the retained conductive surface, the desired energy capacity.

 If necessary, the graphite deposit can be replaced by a deposit of silver paste or by another metallic deposit, of nickel, chromium or the like, which can imply different specific resistivities for the conductive material itself. In all cases, it is a deposit of very small thickness with very low linear resistivity, corresponding to a linear power of around 10 to 90 watts per linear meter, while for wired resistances, we are talking about hundreds of watts per linear meter.

 Furthermore, in accordance with an alternative embodiment of the invention, the heating element, cut appropriately into shape and dimensions according to the door to receive it, can be covered with a continuous conductive deposit over its entire surface. The surface capacity of thermal emission is all the better.

 Note, however, that the choice of a heating element with conductive strips may be more advantageous in the case where, in accordance with a secondary characteristic of the invention, this element is combined with a temperature control device. In this case, as a function of the heating call determined for example by a room thermostat, the regulating device automatically controls on / off the electrical supply of one and / or the other from several resistive elements. with conductive surface, these being individually connected separately from each other to the electric current circuits.

 Another advantage of heating elements of this type lies in the fact that the substrate carrying the conductive deposit is in the form of a thin, flat sheet or plate (0.5 mm thick for example, more generally 0, 3 to 1.5 mm thick) which is both flexible enough to prevent thermal expansion or contraction causing the appearance of parasitic noise in operation and to easily adapt in a situation of thermal contact with other elements of the heating assembly, or even directly with the permissive facing panel of the door, and nevertheless sufficiently strong mechanically so that the flatness is preserved during the positioning operations as well as in the final assembly.

 It is also possible to vary the thickness or the nature of the conductive deposit, or preferably the width of the strips at equal length and distance, in order to concentrate the energy emitted per unit area more in the lower part than in the upper part of the door.

 Naturally, and as it already clearly follows from the above, the invention is not limited to the particular embodiments which have been described by way of preferred examples, of which it encompasses all the variants remaining within the scope of the scope of the patent.

 In particular, when the implementation of the invention has been detailed above in the context of heating by a door of premises from an interior door of a building, it should be understood that the same heating device could be integrated for the same purpose in any opening, for example window or furniture, or placed behind the facade of any partition, and even any wall not necessarily vertical. In addition, the unitary assembly described above can be designed as a self-supporting device intended to be used alone, preferably but not limited to in a vertical position, or to be fixed in veneer of a door, partition or other wall, in particular when it has its own facing panel, although the same device plate can simultaneously perform the functions of facing panel and thermal diffuser.

Claims (10)

 1 / A method of heating premises, characterized in that it essentially consists of having a vertical partition of said premises, a heating plate (30) with surface resistivity, constituted by a substrate (8) coated with a conductive deposit (9) , at the rear of a facing panel (4) permissive for the thermal radiation that it emits by Joule effect under electrical power, said plate (30) and said facing panel (4) being pressed one against the 'other in a situation of direct heat transfer by conduction, to the exclusion of any air gap favoring convection phenomena.  2 / A space heating device by radiation suitable for implementing the method according to claim 1, characterized in that it comprises a surface resistivity heating plate, constituted by a flat substrate (8) coated with a conductive deposit. (9), at the rear of a facing panel (4) permissive for the thermal radiation which it emits by Joule effect under electrical power, said plate and said facing panel being pressed against one another in situation of direct heat transfer by conduction, excluding any air gap promoting convection phenomena.  3 / Device according to claim 2, characterized in that it comprises a thermal diffuser element (11) disposed on the front face of said surface resistivity heating plate so as to cover without conductive air its conductive surface, in particular between- ci and said facing panel.  4 / Device according to claim 3, charac terized in that it further comprises a layer (10) of dielectric material insulating the conductive surface of said plate of said diffuser element.  5 / Device according to any one of claims 2 to 4, characterized in that it comprises on the rear face of said heating plate an absorbent element capable of constituting a mechanical support for the latter and of returning the heat flow forward issued during operation.  6 / Device according to any one of claims 2 to 5, characterized in that the conductive surface of said plate extends over at least 30%, and preferably over at least 60% of the surface of said substrate.  7 / Device according to any one of claims 2 to 6, characterized in that it is integrated in a door leaf limited by said facing panel (4), said heating plate being mounted in an enclosed space without air gap between the latter and a filling mass (7) constituting an insulating thermal absorbent.  8 / Device according to any one of claims 2 to 7, characterized in that it has a flat and planar shape, extending over at least half of the surface of an opening (2) of interior building door .  9 / Device according to any one of claims 2 to 8, characterized in that said heating plate comprises a resistive layer of an electrically conductive material (9) deposited in parallel strips on a substrate (8) consisting of a sheet of organic material, between two lateral bands forming current collectors.  10 / Device according to any one of the preceding claims, characterized in that the elements constituting it are assembled into a self-supporting unitary assembly of generally flat and planar shape forming for said surface resistivity plate an enclosed space devoid of air gap allowing heat transfers not convection.