EP1376015A1 - Electric radiator and method of making the same - Google Patents

Abstract

The radiator consists of at least two glass panels (2, 3, 4) with a resistance circuit (10) based on glass and silver applied by serigraphy between the first (2) and second (4) panels, with a third (3) trim panel in the front. The serigraphy process uses a mixture or ink based on fritted glass, silver and an organic binding agent such as ethyl cellulose. The radiator consists of at least two glass panels (2, 3, 4) with a resistance circuit (10) based on glass and silver applied by serigraphy between the first (2) and second (4) panels, with a third (3) trim panel in the front. The serigraphy process uses a mixture or ink based on fritted glass, silver and an organic binding agent such as ethyl cellulose. The second and optional third panels have a coating of adhesive (32, 42) on their surfaces (31, 41) facing the first panel (2), and at least one of the panels is fitted with a temperature limiter that switches off the power to the circuit at a predetermined temperature e.g. of 90 degrees C.

Description

The invention relates to an electric heater comprising, inter alia, at least two glass panels, as well as a method of manufacturing such a radiator.

In the field of electric heaters, it is known, for example from FR-A-2 789 879, to use a circuit resistive forming a heating element and arranged between two glass panels. In this prior art, the circuit electric is aluminum based and arranged between two polyethylene terephthalate (PET) films, which induces a relatively high cost price compared to the power obtained. PET films are relatively thermally insulating, which affects performance energy consumption of the radiator. In addition, resistance in aluminum cannot be soldered on wires copper supply and, in case of condensation, a such resistance may be the place of primers or breakdowns, especially in the junction area with the supply films, to the point where the radiator becomes unusable.

It is to these disadvantages that most particularly remedy the invention by proposing a electric radiator whose manufacture can be greatly simplified compared to the state of the art and whose reliability is increased, while its price of returns is quite attractive.

In this spirit, the invention relates to a radiator comprising at least two glass panels between two of which a resistive circuit is arranged, characterized in that that this resistive circuit is based on glass and silver and deposited by screen printing on a side face of a first panel facing a second panel.

Thanks to the invention, it is not necessary to have use of PET films to position a circuit resistive compared to glass panels, because the screen printing, which is a technique known in others areas, allows both the formation of the resistive circuit and its positioning on one of the panels. Use of silver mixed with glass, in particular sintered glass, allows to build a circuit with good electrical properties, mechanical resistance satisfactory and an ability to be soldered onto the wires in supply copper from the mains.

• II comprend un troisième panneau de verre formant habillage frontal, le premier panneau étant disposé entre les deuxième et troisième panneaux du radiateur.
• Le deuxième panneau et, éventuellement, le troisième panneau sont revêtus, sur leurs faces respectives tournées vers le premier panneau, d'une couche d'adhésif, ce qui permet de créer une structure multi-couches dont la résistance mécanique est très satisfaisante et dans laquelle le circuit résistif est confiné et isolé de façon étanche. En outre, l'utilisation d'un adhésif entre les premier et deuxième panneaux et, éventuellement, entre les premier et troisième panneaux facilite la transmission de la chaleur par conduction entre ces panneaux, puis par rayonnement.
• Le radiateur est équipé d'au moins un dispositif de limitation de la température de l'un au moins des panneaux de verre. Dans ce cas, ce dispositif de limitation est avantageusement apte à couper l'alimentation en courant du circuit résistif lorsque la température du panneau considéré atteint une valeur de seuil prédéterminée, notamment une valeur égale à 90°.
• Il est prévu un boítier de régulation du fonctionnement du circuit résistif, ce boítier étant fixé sur un montant reliant deux traverses disposées respectivement en partie haute et basse des panneaux et formant, ensemble et avec ce montant, un moyen de rigidification et de fixation du radiateur.

According to advantageous but not compulsory aspects of the invention, this radiator incorporates one or more of the following characteristics:

• It comprises a third glass panel forming a front covering, the first panel being disposed between the second and third panels of the radiator.
• The second panel and, optionally, the third panel are coated, on their respective faces facing the first panel, with a layer of adhesive, which makes it possible to create a multi-layer structure whose mechanical resistance is very satisfactory and in which the resistive circuit is confined and sealed. In addition, the use of an adhesive between the first and second panels and, optionally, between the first and third panels facilitates the transmission of heat by conduction between these panels, then by radiation.
• The radiator is equipped with at least one device for limiting the temperature of at least one of the glass panels. In this case, this limiting device is advantageously able to cut the current supply to the resistive circuit when the temperature of the panel considered reaches a predetermined threshold value, in particular a value equal to 90 °.
• There is provided a housing for regulating the operation of the resistive circuit, this housing being fixed on an upright connecting two crosspieces disposed respectively in the upper and lower part of the panels and forming, together and with this upright, a means of stiffening and fixing the radiator. .

• déposer par sérigraphie, sur une face latérale d'un panneau de verre non trempé, une encre conductrice comprenant du verre, de l'argent et un liant organique ;
• chauffer ce panneau à une température telle que le verre contenu dans l'encre fond, alors que le liant est éliminé et ;
• tremper le panneau.

The invention also relates to a method for manufacturing a radiator as described above and, more specifically, to a method for manufacturing an electric radiator comprising at least two glass panels between which a resistive circuit is disposed, characterized in that '' it includes steps consisting in:

• depositing by screen printing, on a side face of a non-tempered glass panel, a conductive ink comprising glass, silver and an organic binder;
• heating this panel to a temperature such that the glass contained in the ink melts, while the binder is removed and;
• soak the panel.

This process can be implemented in a way industrial with a high degree of reliability and reproducibility and allows economical manufacturing of electric heaters.

• L'étape de chauffage du panneau a lieu à une température comprise entre environ 700°C et environ 800°C.
• L'étape de trempe a lieu dans le même four que l'étape de chauffage ou immédiatement en sortie du four de chauffage.
• On utilise, comme liant organique, de l'éthylcellulose.

According to advantageous aspects, this process can incorporate one or more of the following characteristics:

• The panel heating step takes place at a temperature between about 700 ° C and about 800 ° C.
• The quenching step takes place in the same oven as the heating step or immediately at the outlet of the heating oven.
• Ethylcellulose is used as the organic binder.

• la figure 1 est une vue en perspective éclatée d'un radiateur conforme à l'invention, vu par l'arrière ;
• la figure 2 est une coupe verticale du radiateur de la figure 1, en configuration montée sur une cloison verticale ;
• la figure 3 est une section éclatée et à plus grande échelle selon la ligne III-III à la figure 2 et
• la figure 4 est une représentation schématique de principe d'une installation de fabrication d'un radiateur selon les figures 1 à 3.

The invention will be better understood and other advantages of it will appear more clearly in the light of the following description of an embodiment of a radiator in accordance with its principle and of its manufacturing process, given only by way of example and with reference to the appended drawings in which:

• Figure 1 is an exploded perspective view of a radiator according to the invention, seen from the rear;
• Figure 2 is a vertical section of the radiator of Figure 1, in configuration mounted on a vertical wall;
• FIG. 3 is an exploded section on a larger scale along the line III-III in FIG. 2 and
• FIG. 4 is a schematic representation of the principle of an installation for manufacturing a radiator according to FIGS. 1 to 3.

The radiator 1 shown in Figures 1 to 3 is intended to be mounted on a vertical partition C. It includes three glass panels, namely a panel intermediate 2 disposed between a front panel 3 and a rear panel 4.

The three panels 2, 3 and 4 are made of tempered glass and are assembled into a multi-layered structure as well as appears from the explanations which follow. A baguette upper 5 and lower rod 6, respectively provided with end caps 51 and 61 are provided to be mounted in the upper and lower parts of the radiator 1 by receiving panels 2, 3 and 4 in grooves 52, respectively 62, of adapted geometry. Of them uprights 7 and 8 are provided to connect the strips 5 and 6 on the rear of the radiator 1 and allow the fixing of the radiator 1 on partition C, while stiffening all

In place of caps 51 and 61, angles unrepresented metal can be used for immobilize the panels 2, 3 and 4 in the grooves 52 and 62.

The upright 8 supports an electronic unit of regulation of the operation of radiator 1, this unit being supplied with current from the mains, as represented by wire 91. Unit 9 is also connected to panel 2 by a current supply wire 92 of a resistive circuit 10 affixed on the face 21 of the panel 2 facing the rear panel 4.

The circuit 10 is formed on the face 21 of the panel 2 by means of a device 101 for depositing, by screen printing, a bead 10 'formed by a mixture or ink based on sintered glass, silver and an organic binder. such as, for example, ethylcellulose. Sintered glass is loaded with lead to lower its melting temperature. The geometry of the circuit 10 is obtained by a displacement of the device 101, in space, as represented by the arrows F ₁ , F ₂ and F ₃ in FIG. 4.

The bead 10 ′ is formed by screen printing on a blank 2 ′ of glass panel not yet tempered. Once the bead 10 'has been deposited, the blank 2' is conveyed, for example by a conveyor 102, to an oven 103 which comprises a first part 103 a in which the blank 2 'is brought to a temperature between approximately 700 and approximately 800 ° C., before the blank is cooled in a portion 103 b , during a quenching operation of the panel 2, which can take place by any known technique, in particular by blowing air fresh.

The glass used in the ink for forming the cord 10 'is selected such that its melting temperature is lower than the heating temperature of the blanks 2' in part 103 of the furnace 103. Thus, the glass melts during transit of the blanks 2 ′ in the furnace 103, which leads to the formation of the circuit 10.

When the elevation of temperature in the part 103 of the furnace, the organic binder of the cord 10 'affixed to the blank 2' is removed by evaporation, combustion or other physical phenomenon, so that remains on the panel 2 as the mixture of molten glass and silver which then constitutes circuit 10.

At the outlet of the oven 103, the panel 2 can be moved onto a cart 104.

The panel 2 disposed on the carriage 104 can then be routed to a next workstation in which it is assembled with a panel 3 and a panel 4 to form a multi-layer structure 234 on which elements 5 to 9 are then mounted.

As shown more particularly in Figure 3, the face 31 of the panel 3 facing the panel 2 and the side 41 of panel 4 facing panel 2 are each coated with an adhesive layer 32, respectively 42, allowing the formation of structure 234 independently the use of sticks 5 and 6.

The face 43 of the panel 4 opposite the panel 2 is, meanwhile, coated with a metallization layer 44 to reflect the thermal radiation from of circuit 10 during operation.

Thus, the diffusion of the heat resulting from the operation of the circuit 10 takes place essentially towards the front of the radiator 1, as shown by the arrows F ₄ in FIG. 2.

Thanks to the use of adhesive layers 32 and 42, heat diffusion, between panels 2 and 3 and between panels 4 and 2, is more efficient, because the layers 32 and 42 avoid the creation of gaps at the interface between panels 2 and 3, on the one hand, 2 and 4, on the other hand, such interstices which may result from manufacturing tolerances and / or irregularities in surface of these panels. In other words, conduction between panels 2, 3 and 4 is improved by the use of adhesive layers 32 and 42.

From panel 3, the diffusion of heat towards the volume of the room to be heated is carried out essentially by radiation.

According to an advantageous aspect of the invention, the panel 3 can be provided with a decoration allowing personalization the appearance of the radiator 1 and to hide the circuit 10.

However, the use of such a front panel is not mandatory and a simplified version of the radiator can be considered which includes only panels equivalent to panels 2 and 4 mentioned above.

Unit 9 includes a thermostat 93, a button setting 94 and an on / off switch 95.

Unit 9 is also associated, by a wire electric 96, to a temperature sensor 97 affixed to the rear face 43 of panel 4.

The output signal from sensor 97 is used by a logic part 98 of unit 9 to maintain the temperature of structure 234 to a value below a predetermined threshold value, for example equal to 90 ° C. Thus, if the sensor 97 detects that the structure 234, that is to say in this case panel 4, reaches a temperature of 90 °, power to circuit 10 by unit 9 is interrupted.

The sensor 97 can be of any known type, for example bi-metallic example.

The invention has been represented with a radiator comprising a single resistive circuit. It applies however to a multi-circuit radiator which can be distributed on both sides of the intermediate panel when a front panel is used.

Claims (10)

Electric heater comprising at least two glass panels between two of which is placed a resistive circuit, characterized in that said resistive circuit (10) is based on glass and silver and deposited (10 ′) by screen printing on a lateral face ( 21) of a first panel (2) facing a second panel (4). Radiator according to claim 1, characterized in that it comprises a third glass panel (3) forming a front covering and in that said first panel (2) is disposed between said second (4) and third (3) panels. Radiator according to at least one of the preceding claims, characterized in that said second panel (4) and, optionally, said third panel (3) are coated, on their respective faces (31, 41) facing towards said first panel (2 ), a layer of adhesive (32, 42). Radiator according to any one of the preceding claims, characterized in that it is equipped with at least one device (97, 98) for limiting the temperature of at least one of said glass panels (2, 3, 4 ). Radiator according to claim 4, characterized in that said limiting device is capable of cutting the power supply to said resistive circuit (10) when the temperature of said panel (2, 3, 4) reaches a predetermined threshold value, in particular a value equal to 90 ° C. Radiator according to at least one of the preceding claims, characterized in that it comprises a box (9) for regulating the operation of said resistive circuit (10), said box being fixed on an upright (8) connecting two crosspieces (5, 6) disposed respectively in the upper and lower parts of said panels (2, 3, 4) and forming together and with said upright a means of stiffening and fixing of said radiator (1). Method for manufacturing an electric radiator comprising at least two glass panels between which a resistive circuit is disposed, characterized in that it comprises steps consisting in: deposit (F ₁ , F ₂ , F ₃ ) by screen printing, on a side face (21) of a non-tempered glass panel (2 '), a conductive ink (10') comprising glass, silver and an organic binder; heating said panel (at 103 a ) to a temperature such that the glass contained in the ink melts, while said binder is removed and dip said panel (in 103 b ). A method according to claim 7, characterized in that the step of heating said panel (2 ') takes place at a temperature between about 700 ° C and about 800 ° C. Method according to one of claims 7 or 8, characterized in that the quenching step takes place in the same oven (103) as the heating step or immediately at the outlet of the heating oven. Method according to one of Claims 7 to 9, characterized in that it consists in using, as organic binder, ethylcellulose

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