FR3011621A1 - HEAT REGULATION DEVICE EMITTED BY A HEATING APPARATUS - Google Patents

Abstract

The invention relates to a device (10) for regulating the heat emitted towards a space to be heated by a device (1) for heating with successive charges, characterized in that it comprises a heat shield (11). formed of at least one insulating panel (13, 14) adapted to be deployed between at least part of the external walls (5, 6) of the heating apparatus and the space to be heated

Description

The invention relates to a device for regulating the heat emitted by a heating appliance, and more particularly to such a device adapted for manual-feed stove type heaters. in particular with logs of wood, and with slow restitution of heat. Progress in improving the thermal insulation of living quarters has resulted in energy efficient houses in which heating needs are substantially reduced without, however, completely eliminating them. In addition, these houses make use of means allowing significant passive solar contributions contributing, if necessary, to increase the heat input into these premises, or overheat them. However, if the average need for heating is reduced, it nevertheless remains necessary to have heating means having a greater power to meet specific needs such as the rise in temperature of a room, for example at return of winter holidays. The heaters, especially log wood stoves, can be classified according to their power, and in particular their combustion power and their power output. These heaters 20 are often described as sequentially charged combustion appliances as opposed to continuously fed appliances, for example liquid, gaseous or solid fuels in the split state (compressed wood pellets, for example). Combustion power is the power delivered by the amount, or load of burned wood multiplied by the heating value of the fuel and the efficiency ratio of the apparatus, reduced to the burning time of the wood load. The combustion power is delivered substantially simultaneously with the combustion of the wood load introduced into the heater.

The restored power corresponds to the energy effectively restored in the room in the form of heat reduced to the duration of this restitution which corresponds in general to the time interval between two successive loads. Ideally, a stove, and more particularly a storage (heat) stove has a high combustion power to quickly burn a large load of wood to store the heat produced in its mass and then restore it gradually, with a power curve restored to each device. One of the problems encountered with storage stoves, and more particularly with stoves called mass stoves, capable of very high heat accumulation due to their mass generally between 800 kg and several tons, is that the amount of stored heat is returned for several hours or even days. Therefore, in the presence of a well insulated local, mild climatic conditions and / or unexpected input of solar energy, the power returned is greater than the needs of the room to be heated and it sees its temperature rise to above the comfort temperature (overheating of the room). Furthermore, the heat requirements of the premises to be heated can vary, for example down when they are empty or at night. It is therefore interesting to reduce the temperature of the premises in order to save energy.

There is therefore a need to regulate the heat emitted towards the space to be heated so as to avoid overheating, generating waste of energy and discomfort and to allow an adaptation of the temperature of this space to the existing circumstances. Among the known solutions, those aimed at the regulation of the combustion power have certain common drawbacks. If the fuel load in the stove hearth is reduced, it is possible that the optimum combustion temperature can not be reached resulting in a deterioration of the combustion conditions and thus pollution and / or fouling of the hearth and duct. smoke evacuation. In addition, reducing the fuel load results in a more frequent supply of the household, which goes against the goal sought by the users. If the amount of combustion air in the stove hearth is affected, for example by reducing it, the quality of the combustion is affected and the efficiency of the stove decreases. In addition, again, such a process causes the generation of pollution. Document EP 1 467 152 discloses a device for regulating the heat emitted by a stove comprising a hearth in which the combustion of the logs takes place and, at a distance from this, an envelope forming the outer shell of the appliance. of heating. The regulating device consists of a set of plates placed between the hearth and the shell, for example in the form of a blind with vertical blades which, in a first position, allow the transmission of heat by radiation between the hearth and the shell of the device, and in a second position, limit this transmission. Such a device, internal to the device, has many disadvantages such as the risk of overheating of the device may cause blockages of mechanical elements and joints, the impossibility of accessing the device without disassembly and shutdown of the device which leads to maintenance difficulties, etc. In addition, such a device must be provided for the design of the heater and can not be added to an existing device. There is therefore a need that the invention aims to fill for a device for regulating the heat emitted by a heater that does not have the drawbacks of the prior art. The object of the invention is thus to provide a device for regulating the heat emitted which makes it possible to reduce the risks and consequences of forecast errors in the various heat inputs in the space to be heated. The invention also aims to provide such a device for regulating the heat emitted which can be removable or retractable.

The invention also relates to such a device that can be added as an option to an existing device or installed later on an existing installation. The invention further provides such a device that can fit harmoniously into a room and serve as a support for decorative elements. Finally, the invention aims to provide such a device to meet new technical standards at a reduced cost. To do this, the invention relates to a device for regulating the heat emitted towards a space to be heated by a combustion heater with successive charges, characterized in that it comprises a heat shield formed of at least an insulating panel adapted to be deployed between at least a portion of the outer walls of the heater and the space to be heated. Throughout the present text, an insulating panel is defined as a flexible or rigid element having the property of forming a barrier to the transmission of heat by any of the modes of transmission such as convection, conduction or radiation. Thus, a veil opaque to infrared radiation, even if it is of a small thickness not constituting an obstacle in the sense of conduction or convection is considered an insulating panel. The space to be heated is defined as the volume of the room in which the heater is installed, outside the heat shield relative to the heater. It may extend beyond the room in which the heater is installed if it is intended to heat a plurality of adjacent rooms. By thus providing a heat shield around the heater, it is possible to at least partially confine the heat generated inside the heat shield when the insulation panels thereof are deployed. Thus, on the one hand, the heating apparatus is isolated from the space to be heated, which limits the heat transfers towards this space, and on the other hand the heat loss at the level of the apparatus itself. is reduced, allowing to keep to the earth of the heater a higher temperature and therefore accumulate energy in the device for a subsequent return. The variable deployment of the panels of the heat shield thus makes it possible to regulate the quantity of heat transmitted to the space to be heated and thus to compensate for any unexpected input of solar energy or any other energy having the effect of raising the temperature the space to be heated beyond what is necessary for the thermal comfort of the occupants or to deliberately lower the temperature of the space to be heated.

In addition, the heat shield being formed of panels placed outside the heater, it is independent of it and can be added after the manufacture and installation of the heater. It can thus equip an existing heater. Similarly, the regulating device can be removed when it is not necessary, for example when the heater is not in operation (in summer). In addition, the control device and in particular the heat shield being visible outside the heater, it can serve as a support for decorative elements, for example paintings on the insulating panels. It should also be noted that the new 2012 thermal regulations provide for the need for automatic regulation for any heating system, including wood burning stoves. Therefore, a device according to the invention makes it possible to respect these standards economically. Advantageously and according to the invention, the insulating panel (s) also comprises at least one reflecting surface facing the external walls of the heating apparatus. By providing at least one reflecting surface on the insulating panels, on their side opposite the heating apparatus, the thermal confinement achieved is effected not only by acting on the conduction and / or the convection but also on the radiation by returning this one in the direction of the heater.

Advantageously and according to a first embodiment of the invention, the heat shield is in contact with the outer walls of the heater. Thus, for heating appliances whose external wall temperature does not exceed a limit value, for example 220 ° C, it is possible to arrange the insulating panels directly in contact with these walls by judiciously choosing the material of these panels made of resistance to heat, flammability, etc. Advantageously and according to the invention, the heat shield comprises flexible insulating panels covering at least one wall of the heater. Depending on the shape of the heater and the desired regulation, the flexible insulation panels may cover a greater or lesser extent the appliance, for example the top and sides of the stove, or the back and / or the facade, by providing the necessary cut-outs for the door, the ash drawer, as well as the various elements whose access must be preserved.

Advantageously and according to the invention, the heat shield comprises at least one winder adapted to deploy and fold each panel covering a vertical wall by winding the panel on itself. The use of flexible insulating panels makes it possible to provide one or more winders capable of winding or unwinding each panel, together or separately, for example by direct winding on the winding tube of a tubular motor or by pulling on straps. winding. By placing the winder on the top of the heater, it is possible to wind the panels covering the four vertical faces of the appliance. Advantageously and according to the invention, the heat shield comprises means adapted to deploy and fold each panel covering a vertical wall by folding multiple panels. In this variant, the insulating panels are made in the form of "boat" blinds, in which traction on cords connecting slats fixed horizontally on the flexible insulating panel allows these panels to be retracted by folding a panel on the panel. other.

Alternatively also, the folding of a flexible panel can be performed by a direct pull on the bottom of the panel, the latter creasing in the form of puckering going up similarly to a blind "bubbled". Advantageously and according to a second embodiment of the invention, the heat shield comprises a structure adapted to keep the insulating panel (s) away from the outer walls of the heating apparatus. When the wall temperatures of the heater or the characteristics of the materials used do not allow to put insulating panels in contact with the outer walls of the device, the device according to the invention can be made to include a structure adapted to maintain a spacing respecting the recommended safety distances for the materials used, between the insulating panels and the walls of the apparatus. The structure may advantageously be made in the form of metal rails for sliding fastening elements of the insulating panels. Advantageously and according to a first variant of this second embodiment of the invention, the structure is integral with at least one of the walls of the space to be heated, in the vicinity of the heating apparatus. By thus fixing the support structure of the panels on partitions of the space to be heated around the heater, the distance between the insulating panels and the appliance is well determined, eliminating the risk of seeing one of the panels come in contact with the heater. Advantageously and according to the invention, the structure comprises at least one rod fixed to the ceiling of the space to be heated to which the insulating panels are suspended and delimits around the heating apparatus a thermal confinement zone when the panels are deployed. By using a ceiling-mounted rod or rail, and using panels whose height corresponds to the floor-to-ceiling height, the heat loss is minimal. Advantageously and according to a second variant of the second embodiment of the invention, the structure is a self-supporting structure at least partially surrounding the heating apparatus. It is thus possible to reduce in height and therefore in volume the thermal confinement zone.

In addition, the structure can be easily dismantled to be stored when the heater is not in operation. Advantageously and according to the invention, the insulating panels are in the form of flexible curtains adapted to be deployed, respectively folded, by sliding on a bead wire. Whatever the structural variant used for the device of the invention, various forms of insulating panels may be employed, and in particular flexible curtain-like insulating panels sliding on a rail or a rod and surrounding the device of the invention. heater.

Advantageously and according to the invention, the insulating panels are in the form of rigid sliding panels. By providing the heat shield in the form of a plurality of rigid insulation panels suspended from a rail, it is possible to provide a telescopic partition to isolate the thermal confinement zone, particularly when the heater is placed in a an angle. Advantageously and according to the invention, the insulating panels are concealed, in the folded position, in at least one housing formed in walls of the space to be heated. When the heat shield is made in the form of rigid insulating sliding panels, it is possible to at least partially embed them, in the open position, in a housing in the walls of the room or behind a wall. The panels are thus at least partially concealed in the open position. Advantageously and according to the invention, the insulating panels are in the form of rectangular blades pivoting about a longitudinal axis, said blades having longitudinal edges adapted to cover the corresponding edges of the adjacent blades in their deployed position and whose main faces are parallel in their folded position. The heat shield may also be in the form of insulating panels in the form of narrow rectangular blades, adapted to pivot along a longitudinal axis between a position in which the main faces of the blades are substantially parallel to each other and at a distance from each other. from one another, allowing the radiation from the heater to pass to the space to be heated and a position in which the respective edges of the adjacent blades overlap, thereby obscuring the passage of the radiation and / or the hot air between the containment zone and the space to be heated.

The longitudinal axis of pivoting of the insulating panels may advantageously be vertical in the manner of a blind or horizontally in the manner of a venetian blind or a blind. Advantageously and according to the invention, the device comprises means for moving the insulating panels parallel to their longitudinal axis so that their main faces are plated on the main faces of the adjacent panels in the folded position. When the insulating panels are made in the form of parallel blades, it is convenient to be able to fold them in the manner of a blind, so that the panels occupy the least possible space.

Advantageously and according to the invention, the insulating panels are in the form of rigid rectangular panels hinged along their adjacent longitudinal sides so as to form an accordion screen. The insulating panels can thus be deployed in any continuous shape around the heater, in a leaf folding laterally or two leaves opening substantially in the middle of the insulating screen. Advantageously and according to the invention, the device further comprises means for motorizing the movements of the panels. Whatever the embodiment of the heat shield, the invention provides to associate motorization means for moving the insulation panels between their deployed position and their folded position. For example, a set of cables moving carriages supporting the axis of insulating panels in the form of a roller blind makes it possible, by winding these cables around a motor shaft, to rotate each blade and to distribute them equidistantly on the blade. along a rail in which these cables are guided. Of course, the motorization means are chosen according to the shape of the heat shield and the insulating panels that compose it.

Advantageously and according to the invention, the motorization means are adapted to be controlled according to a difference between a temperature measured in the space to be heated and a set temperature. As soon as motorization means are installed enabling the insulation panels of the heat shield to be deployed or folded, it is particularly advantageous to be able to control these motorization means so as to modulate the heat transfer between the heat sink and the heat sink. heating and the space to be heated so as to ensure a temperature regulation of the latter. The automation of the temperature control can be effected according to a set temperature, the temperature actually measured in the space to be heated, the temperature in the thermal confinement zone, and so on. as a function of predefined time periods. Advantageously and according to the invention, the motorization means are further adapted to be controlled by a command in all or nothing. It can also be provided a maneuver switch for controlling the deployment or folding of the insulating panels between their deployed position their folded position or any intermediate position. In its simplest version, the operating switch is operated manually. Advantageously and according to the invention, the control in all or nothing is transmitted by a remote transmission means. It is also possible to use a control box for the operation of insulating panels connected to a telephone line or a home network, connected or not to the Internet, to allow like other various home automation commands, to be The invention also relates to a device for regulating the heat emitted by a heating appliance characterized in combination by all or some of the characteristics mentioned above or below. Other objects, features and advantages of the invention will become apparent from the following description and the accompanying drawings in which: - Figure 1 shows a perspective view of a heater equipped with a device according to a first embodiment of the invention; - Figure 2 schematically shows a variant of the device of Figure 1; FIG. 3 represents a schematic perspective view of a device according to a second embodiment of the invention; FIG. 4 represents a schematic perspective view of a device according to a third embodiment of the invention; FIG. 5 represents a schematic perspective view of a device according to a fourth embodiment of the invention; - Figure 6 shows a top view of a device of Figure 5 highlighting an advantage of the device according to the invention. Figure 1 shows a heater 1, in this case a stove, equipped with a device 10 for regulating the heat emitted by the stove according to a first embodiment of the invention. In the example shown in Figure 1, the walls of the heater are for example concrete (with the exception of the door) and their surface temperature does not exceed 220 ° C even at the height of the thermal transfer to the walls.

The regulating device 10 comprises a heat shield 11 consisting of flexible insulating panels clad on the walls of the heater, such as the upper panel 12 which covers the upper face of the stove and includes a cutout for the passage of the flue 2, the side panels 13, shown half-wound on the side faces 5 of the stove, and the front panel 14 completely deployed on the front face 6 of the stove and having a cutout for the passage of the door 3 and the drawer 4 ashes . The insulating panels may advantageously be made of fiberglass fabrics such as isoGLAS® textiles marketed by TEXEO for example. Such textiles are particularly suitable for forming heat shields because of their resistance to high temperatures (550 ° C) and their high residual volume which gives them a high insulating capacity. Each insulating panel may comprise at least one metallic reflective face 17, for example made by painting, vacuum metallization or other method known per se. In this case the metallized face 17 is oriented opposite the corresponding wall of the heater and pressed against it. The device 10 also comprises a winder housing 15 comprising one or more electric motors (not shown) adapted to maneuver straps 16 allowing the winding of the various insulating panels forming the heat shield 11. When all the insulating panels of the screen 11 are deployed, that is to say they are unwound so as to cover the walls of the heater, the characteristics of the heat exchange between these walls and the space to be heated are changed. In particular, the radiation heat exchange is otherwise blocked, at least greatly reduced by the presence of the reflective face 17 of the insulating panels which returns the radiation to the heater. Similarly, the exchanges by conduction and / or convection are reduced by the presence of an insulating layer forming the thickness of the panel. Advantageously, the characteristics of the insulating panels such as the material, the thickness and the maximum surface area covered by the insulating panels are adapted so that, when the heat shield is fully deployed, the power restored by the heating device provided with the The emitted heat control device corresponds to the minimum of the power required to maintain the temperature in the space to be heated. Thus, it is possible, by modulating the deployment of the heat shield, to modulate the power output of the device and to avoid temperature peaks in the space to be heated related to the occurrence of unexpected heat gains for example, significant sunlight not provided by meteorology, or overheating produced by the heat peaks emitted during the combustion of a large fuel load. It is also possible to fold the heat shield to increase the transmission of heat stored to adjust the temperature of the space to be heated for example before the return or the lifting of the occupants. The winder 15 may also comprise a servocontrol 5 (not shown) making it possible to adjust the winding and therefore the area covered by the panels as a function of the temperature of the space to be heated, for example measured by a temperature probe placed in this space. The winding device of the insulating panels of the heat shield shown in FIG. 1 can be replaced by a variant shown in FIG. 2. In this variant, the insulating panels are made in the form of blinds of the "boat" blind type. comprising sections of insulating and / or reflective material separated by rigid horizontal slats. Cords 20 actuated by the winder 15 act on the furthest batten slid through eyelets formed in the upper battens. Pulling on the cords 20 causes the pleat 18 of flexible insulating material separating the batten furthest away from its immediately superior neighbor to be folded until it is driven by the furthest batten in the direction of a batten. neighbor, also causing the folding of the pan of insulating material located above. Another variant not shown for the deployment of the flexible insulating panels forming the heat shield 11 can be made in the form of a "bubbled" blind, in which the cords 20 act on the lowest part of a single pan. of flexible insulating material and fold it into folds. According to a second embodiment of the invention, more particularly adapted to heating devices in which the temperature of the outer walls does not allow, for reasons of safety, to press the insulating panels on them, the screen thermal insulation must be placed away from the walls of the appliance. In the example shown in FIG. 3, the emitted heat control device comprises a heat shield 11 formed of flexible panels 23 hooked to a structure such as a rod 21 fixed to the ceiling 7 of the room in which is installed the heater 1. The rod 21 has a shape, for example in a circular arc, adapted so that the insulating panels 23 form a curtain around and away from the heater. The insulating panels 23 are attached to the rod by carriages 22, mobile thereon. The length of the panels 23 corresponds to the height of the ceiling so as to achieve a thermal confinement zone around the heater when the insulation panels are deployed to form a continuous curtain between the floor and the ceiling. The heat shield may be gradually removed by moving the insulating panels 23 apart by sliding the carriages 22 movable on the rod 21 to allow a gradual transfer of heat from the confinement zone to the space to be heated. Of course, the insulating panels 23 can be moved automatically or manually like conventional curtains by playing on one or more drive cable (s) of the carriages 22 from a position where the panels are deployed (closed curtain) to a position where the panels are folded (open curtain). The rod may have any suitable shape to surround the heater, for example in a quarter circle if the appliance is placed in a corner of the room, in a semicircle if the stove is placed along a wall or in a complete circle if the stove is placed in the center of the room. Other forms are also conceivable provided that the carriages 22 can circulate on the rod in order to deploy or fold the heat shield. The dimensions and position of the rod are adapted to provide a predetermined safety distance between the deployed panels and the walls of the heater. In a second variant of this embodiment of the control device illustrated in FIG. 4, the heat shield comprises a self-supporting support structure, for example comprising four vertical uprights 24 connected by sleepers. In the example shown, the uprights 24 extend from the floor to the ceiling 7 of the room, but it could well be envisaged that they are limited to the height of the heater, possibly with an insulating panel. extending over the heater, with, if necessary, a clean cut to let the flue. The insulating panels forming the lateral and front faces (and if appropriate upper and / or dorsal) of the heat shield are made in the form of insulating rigid blades 25 having at least one reflecting face and pivoting about a longitudinal axis 25a. . The width of the blades 25 and their spacing are adapted so that in the deployed position, the longitudinal edges of a blade overlap or are covered by the longitudinal edges of the adjacent blades, thus forming a continuous screen that obscures or limits the passage of radiation and / or or hot air between the containment zone and the space to be heated. When the insulation panels are folded, the main faces of the blades 25 are parallel and the space between the blades allows the passage of heat between the confinement zone and the space to be heated. Advantageously, the blades 25 can also be movable along the uprights 24 when they are in the latter position in order to group them at one end of the support structure. The axis 25a of the blades 25 may be vertical, according to the model of a blind with vertical blades or, as in the example shown in Figure 4, the axis 25a may be horizontal, the blades 25 thus forming a jealousy or a store called "Venetian".

Of course, whatever the arrangement chosen, the blades 25 can take any intermediate position between the deployed position and the folded position, allowing a continuous adjustment of the amount of heat transmitted. In addition, the blades 25 can be moved, manually or motorized, by means of rods or cords, like the aforementioned blinds.

FIGS. 5 and 6 show yet another alternative embodiment of the regulating device according to the invention, in which the insulating panels 27 are in the form of rigid rectangular panels, sliding in a rail 26 fixed for example in the ceiling of the room where the stove is installed. The heat shield is thus produced in the form of a telescopic partition which can be concealed, in the folded position, in a housing 9 formed in a wall 8 of the part (see FIG. 6) or in a baffle formed for this purpose. Deployment or folding of the insulating panels 27 can also be motorized by a sliding cable drive in the rail 26. Thus, whatever the embodiment of the control device according to the invention, the insulating panels and / or reflective forming the heat shield 11 can be deployed and folded manually or motorized. In particular, when the deployment (respectively refolding) is motorized, it is possible to enslave it to an automatism taking into account the different temperatures measured, for example in the space to be heated and / or in the thermal confinement zone, or outside the room / house to control the screen deployment and regulate the heat output from the heater to the space to be heated.

Of course, the deployment or the folding can also be controlled by hand, by an all-or-nothing command such as a switch, or remotely by telephone or by means of a home network connected to the Internet. Of course, this description is given by way of illustrative example only and the person skilled in the art may make numerous modifications without departing from the scope of the invention, such as using other variants of insulation board deployment between the heater and space to be heated. For example, the insulating panels and / or reflective may be rectangular, rigid and articulated to each other by their longitudinal edges so as to constitute a heat shield in the form of foldable folding screen and folding accordion. Similarly, many motorization systems for this deployment (respectively folding) can be adapted according to the structure of the heat shield.

Claims (7)

CLAIMS1 / - Device (10) for regulating the heat emitted towards a space to be heated by a device (1) of combustion with successive charges, characterized in that it comprises a heat shield (11) formed of at least one insulating panel (12, 13, 14, 23, 27) adapted to be deployed between at least a portion of the outer walls (5, 6) of the heating apparatus (1) and the space to be heated. 2 / - Device according to claim 1, characterized in that the (s) panel (s) insulator (s) also comprises (s) at least one face (17) 10 reflective facing the outer walls of the heater . 3 / - Device according to one of claims 1 or 2, characterized in that the screen (11) heat is in contact with the outer walls (5, 6) of the heater. 4 / - Device according to one of claims 1 to 3, characterized in that the screen (11) comprises thermal panels (13, 14) flexible insulating covering at least one wall (5,6) vertical of the heating appliance. 5 / - Device according to claim 4, characterized in that the heat shield (11) comprises a winder (15) adapted to deploy and fold each 20 panel (13, 14) covering a vertical wall by winding the panel on him- even. 6 / - Device according to claim 4, characterized in that the heat shield (11) comprises means adapted to deploy and fold each panel (13, 14) covering a vertical wall by folding multiple panels (18) 25. 7 / - Device according to one of claims 1 or 2, characterized in that the heat shield (11) comprises a structure (21, 24) adapted to maintain the (s) panel (s) insulating (s) distance external walls of the heater.8 / - Device according to claim 7, characterized in that the structure (21, 24) is integral with at least one of the walls of the space to be heated, in the vicinity of the apparatus (1) for heating. 9 / - Device according to claim 8, characterized in that the structure comprises at least one rod (21) fixed to the ceiling (7) of the space to be heated which are suspended panels (23) insulating and delimits around the apparatus (1) for heating a thermal confinement zone when the panels are deployed. 10 / - Device according to claim 7, characterized in that the structure is a structure (24) self-supporting at least partially surrounding the heater. 11 / - Device according to any one of claims 7 to 10, characterized in that the insulating panels are in the form of curtains (23) flexible adapted to be deployed, respectively folded, by sliding on a rod (21) . 12 / - Device according to any one of claims 7 to 10, characterized in that the insulating panels are in the form of rigid panels (27) sliding. 13 / - Device according to claim 12, characterized in that the insulating panels (27) are concealed, in the folded position, in at least one housing (9) formed in walls (8) of the space to be heated. 14 / - Device according to any one of claims 7 to 10, characterized in that the insulating panels are in the form of rectangular blades (25) pivoting about a longitudinal axis (25a), said blades 25 having edges longitudinals adapted to cover the corresponding edges of the adjacent blades in their deployed position and whose main faces are parallel in their folded position. 15 / - Device according to claim 14, characterized in that the longitudinal axis (25a) of the panels is arranged horizontally.16 / - Device according to claim 14, characterized in that the longitudinal axis (25a) of the panels is arranged vertically. 17 / - Device according to any one of claims 14 to 16, characterized in that it comprises means for moving the panels 5 parallel to their longitudinal axis so that their main faces are plated to the main faces of the adjacent panels in the folded position. 18 / - Device according to any one of claims 7 to 10, characterized in that the insulating panels are in the form of rigid rectangular panels hinged along their longitudinal sides 10 adjacent to form an accordion screen. 19 / - Device according to any one of the preceding claims, characterized in that it further comprises means for motorizing the movements of the panels. 20 / - Device according to claim 19, characterized in that the drive means are adapted to be controlled according to a difference between a temperature measured in the space to be heated and a set temperature. 21 / - Device according to any one of claims 19 or 20, characterized in that the drive means are further adapted to be controlled by a command in all or nothing. 22 / - Device according to claim 19, characterized in that the control in all or nothing is transmitted by a remote transmission means.