EP0194975A2 - Radiating heating installation - Google Patents

Abstract

An installation for heating water by thermal radiation in the visible spectrum comprises an intermediate air channel (3) delimited by a primary, radiating wall (1) associated with the energy source (5) and by a secondary wall (2) for heat transfer, the internal surface of which collects the thermal radiation emitted by the primary, radiating wall (1) and transmitted through the intermediate channel (3). The external surface of this secondary wall (2) serves to heat the water contained in a reservoir (4). The intermediate channel (3), which serves for the transmission of the thermal radiation, is provided with a lower air inlet opening (7) and with an upper air outlet opening (8), which ensures free circulation of air in this intermediate channel (3), which allows indirect heating of the water by means of the thermal radiation emitted by the primary wall (1), which the energy source (5) brings to a high temperature, transmitted through the intermediate channel (3) with free air circulation, collected and absorbed by the internal surface of the secondary wall (2), the external surface of which serves to heat the water. This installation makes it possible to use thermal radiation in the visible spectrum to carry out indirect heating of water, of any other fluid, liquid or gaseous, or of a solid medium, in contact with the external surface of the secondary wall (2). <IMAGE>

Description

The present invention relates to a device for heating a medium by thermal radiation in the visible spectrum emitted by a radiating body brought to high temperature by an energy source.

In current heating systems, the transfer of heat from the energy source to the medium to be heated is essentially carried out by conduction or convection.

Thus, for example, in conventional electric heating systems for the production of hot water, an electric heating resistor is immersed in the water to be heated and is in direct or indirect contact with water.

Similarly, in heating systems using fossil fuels (wood, coal, fuel oil, oil, gas), the transfer of combustion heat to the medium to be heated is essentially carried out by conduction and convection.

This results in improper use of the energy produced by radiation from the heat source and the low temperature of the medium to be heated negatively influences the heat produced by this radiation.

The object of the present invention is to avoid the drawbacks mentioned above and to make maximum use of the radiation energy produced by a heat source at high temperature.

To this end, the radiation heating device which is the subject of the invention has the characteristics defined in the claims.

The heating device according to the invention is essentially provided with an intermediate channel which separates the energy source at high temperature of the medium to be heated, in particular water, which allows a free circulation of air in this channel, and which allows the emission and transmission, through this channel, of radiation used for heating indirect of said medium.

Said intermediate channel comprises at least one inlet opening and one outlet opening which connect this channel to the outside of the heating device and which allow the free circulation of air in this channel. Said air inlet and outlet openings will advantageously be associated with means comprising for example a diaphragm making it possible to adjust the inlet and the outlet of the air circulating in this channel.

The high temperature heat source used in a device according to the invention can be an electric heating resistor which is brought to high temperature without being directly and negatively influenced by the medium to be heated. The electric heating resistor can therefore work at its maximum power, while allowing optimum heat transfer.

• La figure 1 du dessin représente une coupe longitudinale schématique (suivant le plan A-A, fig. 2) d'une chaudière électrique pour la production d'eau chaude constituant une première forme d'exécution du dispositif de chauffage de l'invention.
• La figure 2 représente une coupe transversale schématique de cette chaudière (suivant la plan B-B, fig. 1).
• La figure 3 représente une coupe longitudinale schématique (suivant le plan A-A, fig.-4) d'une chaudière à mazout selon une deuxième forme d'exécution du dispositif de chauffage selon l'invention.
• La figure 4 représente une coupe transversale schématique (suivant le plan B-B, fig. 3) de cette chaudière selon cette deuxième forme d'exécution.
• La figure 5 représente une coupe longitudinale schématique (suivant le plan A-A, fig. 6) d'un dispositif pour le chauffage électrique d'eau selon une autre forme d'exécution de l'invention.
• La figure 6 représente une coupe transversale schématique de la forme d'exécution du dispositif selon fig. 5.

The invention can be illustrated by the embodiments of a radiation heating device according to the invention which are described below by way of example with the aid of the appended drawing.

• Figure 1 of the drawing shows a schematic longitudinal section (along the plane AA, Fig. 2) of an electric boiler for the production of hot water constituting a first embodiment of the heating device of the invention.
• Figure 2 shows a schematic cross section of this boiler (on the plane BB, fig. 1).
• Figure 3 shows a schematic longitudinal section (along the plane AA, fig.-4) of an oil boiler according to a second embodiment of the heating device according to the invention.
• Figure 4 shows a cross section diagram tick (according to plan BB, fig. 3) of this boiler according to this second embodiment.
• 5 shows a schematic longitudinal section (along the plane AA, Fig. 6) of a device for the electric heating of water according to another embodiment of the invention.
• FIG. 6 represents a schematic cross section of the embodiment of the device according to FIG. 5.

The boiler shown in FIG. 1 comprises an electric heating resistor 5 constituting a source of radiant energy at high temperature, which is surrounded by a first cylindrical wall 1 constituting a primary, radiating, coaxial partition formed of a material capable of supporting the high temperature of the radiant heat produced by the heating resistor 5. This primary, radiant partition has internal and external faces which are blackened, so that it can act as a black body capable of absorbing this radiant heat on its front face , internal, to heat up as well, and to emit secondary radiation in the visible spectrum. This wall 1 constituting a primary, radiant partition serving to capture the radiation emitted by the heating resistor 1, is surrounded by a second cylindrical wall 2 constituting a secondary, conductive, coaxial partition formed of a heat conductive material, which serves to heat exchange with the water to be heated, contained in a tank 4. These two coaxial partitions 1 and 2 are radially spaced and delimit between them an annular passage forming an intermediate channel 3 which is provided with an inlet opening 7 and an outlet opening 8 communicating with the outside of the device and serving to allow free air circulation in this channel 3, as indicated by arrows in FIG. 1.

The water tank 4 of the boiler described is delimited by an external insulating wall 6, closed at its two ends, and provided with a cold water inlet 9 and a hot water outlet 10.

The coaxial partitions 1 and 2 thus delimit the intermediate channel 3 which separates the source of energy at high temperature, constituted by the heating resistor 5, from the water to be heated in the tank 4.

• La résistance électrique chauffante 5 est conçue de manière qu'elle puisse être chauffée à.une température élevée de plusieurs centaines de degrés centigrade, et qu'elle puisse ainsi émettre de la chaleur rayonnante dans le spectre visible, dirigée radialement vers l'extérieur en direction de la face noircie, interne de la cloison primaire, rayonnante 1. Cette chaleur rayonnante est ainsi captée et absorbée par la face interne noircie de cette cloison primaire rayonnante 1, qui se réchauffe en conséquence, et émet à son tour un rayonnement secondaire à une température élevée, radialement vers l'extérieur, en direction de la cloison secondaire 2. Cette dernière est ainsi réchauffée indirectement par la chaleur du rayonnement secondaire émis par la cloison primaire, rayonnante à travers le canal intermédiaire 3, capté et absorbé par sa face interne. L'eau dans le réservoir 4 est ainsi réchauffée indirectement, par l'intermédiaire de la cloison primaire rayonnante 1, du canal intermédiaire 3 à libre circulation d'air, de manière que la température de l'eau n'influence pas directement la résistance chauffante 5 à haute température.

The operation of the described boiler can be explained as follows:

• The electric heating resistor 5 is designed so that it can be heated to a high temperature of several hundred degrees centigrade, and so that it can emit radiant heat in the visible spectrum, directed radially outwards in direction of the blackened, internal face of the primary, radiating partition 1. This radiant heat is thus captured and absorbed by the blackened internal face of this primary radiating partition 1, which heats up consequently, and in turn emits secondary radiation to a high temperature, radially outward, in the direction of the secondary partition 2. The latter is thus indirectly heated by the heat of the secondary radiation emitted by the primary partition, radiating through the intermediate channel 3, captured and absorbed by its face internal. The water in the tank 4 is thus indirectly heated, via the primary radiating partition 1, of the intermediate channel 3 with free circulation of air, so that the temperature of the water does not directly influence the resistance heating 5 at high temperature.

The boiler shown in FIG. 3 comprises an oil burner which has a flame 15, constitutes a source of radiant energy at high temperature, and is arranged axially in a combustion chamber delimited by a cylindrical wall 11 constituting a primary, radiating partition. , coaxial formed of a material capable of withstanding the high temperature of the flame 15 of the burner. This primary, radiant partition 11 has blackened internal and external faces, so that it can act as a black body capable of absorbing on its blackened internal surface the radiant heat emitted by the flame 15, thus heating up, and reemitting radially towards the exterior, from its blackened external surface, secondary radiation in the visible spectrum. This first wall 11 constituting a primary, radiating partition used to intercept and re-emit the radiation produced by the flame 15, is surrounded by a second cylindrical wall 12 which constitutes a secondary, coaxial partition formed of a heat conducting material, and which serves to the exchange of heat with the water to be heated contained in a tank 14. The two coaxial walls 11 and 12 are spaced radially from each other, serve to delimit between them a vertical annular passage forming an intermediate channel 13 which is provided at its lower end with an air inlet 17 and, at its upper end with an air outlet 18, and allows free circulation of air along this channel 13, as indicated by arrows in FIG. 3. The tank 14 of this boiler is delimited by an external insulating wall 16 closed at its two ends, and provided with a tangential cold water inlet 19 and a radial hot water outlet 20 .

The coaxial walls 11 and 12 thus delimit the intermediate channel 13 which separates the flame 15 from the burner, constituting the source of energy at high temperature, from the water to be heated.

The operation of this oil-fired boiler, and in particular the role of the walls 11 and 12 delimiting the intermediate channel 13, correspond essentially to those of the walls 1 and 2 and of the channel 3, as has already been explained with respect to the electric boiler according to figure 1.

The heating device according to FIGS. 4 and 5 constitutes a variant similar to that already described according to FIGS. 1 and 2. The identical elements thus have the same reference numbers in FIGS. 1.2 and 5.6, and will only be briefly described here.

In this variant according to figs. 5 and 6, the heating device is provided with an electrical resistance composed of a plurality of electrical heating spirals 25, each mounted on a porcelain support and housed respectively in corresponding longitudinal grooves formed at the periphery of a body refractory 22. This body 22 is heated to high temperature by these spirals 25 and has an external wall 21, constituting a primary wall used to emit thermal radiation in the visible spectrum and to delimit one side of the intermediate channel 3 for the free circulation of air using the air inlet 7 and outlet 8 openings communicating with the outside of the heating device. The intermediate channel 3 is also delimited by a secondary wall 2 whose internal surface receives, through this channel 3, the thermal radiation emitted in the visible spectrum by the primary wall 21, while its external surface is in contact with water to be heated in the tank 4, provided with an external insulating wall 6 and inlet 9 and outlet 10 openings.

This structure and the operating mode of the heating device are therefore essentially similar to those already described with respect to FIGS. 1 and 2.

It is understood that different modifications and variants of the radiation heating device can be provided within the framework of the invention. The radiation heating device according to the invention can also be advantageously used for heating water or any other suitable medium, therefore various fluids, liquids or gases, or any solid medium, intended for indirect heating by transmitted thermal radiation. through said intermediate air circulation channel. Thus, thanks to the special combination as provided in accordance with the invention, comprising in particular said primary, radiant wall associated with said intermediate channel of free air circulation, it becomes possible to carry this wall pri mayor, radiating at a very high temperature allowing it to emit thermal radiation in the visible spectrum, to avoid at the same time any harmful overheating, or indeed undesirable cooling, and thus to ensure prolonged indirect heating by high radiation temperature with high efficiency.

Claims (5)

1. A device for heating a medium by thermal radiation in the visible spectrum emitted by a radiating body brought to high temperature by an energy source, characterized in that it is provided with an annular intermediate channel (3, 13) free air circulation surrounding the energy source (5,15,25), which is provided with a lower air inlet opening (7) and an air outlet opening upper (8) communicating with the outside of the device and allowing the free circulation of air in this intermediate channel, and that this intermediate channel (3,13) of air circulation is delimited on the one hand by a primary wall, radiant (1,11) associated with the energy source (5,15,25), while this channel is delimited on the other hand by a secondary wall (2,12) of heat transfer having an internal surface arranged in look of said primary, radiant wall and an external surface disposed in contact with the medium to be heated, the whole so that this channel in intermediate (3,13) ensures a free circulation of air around the primary, radiating wall (1, 11, 21), that this primary, radiating wall is brought to high temperature and can thus transmit thermal radiation in the visible spectrum , through this intermediate channel in which air circulates freely, towards said secondary wall (2,12) serving for the transfer of heat to the medium to be heated. 2. Device according to claim 1, characterized in that said annular intermediate channel (3.13) of free air circulation is delimited on the one hand by a primary, radiating partition (1.11) which surrounds the source d energy and which has blackened internal and external surfaces, this intermediate channel being delimited on the other hand by a secondary, heat-conducting partition (2.12) constituting said heat transfer wall, separating said intermediate channel (3.13) from the medium to be heated and having an internal surface arranged opposite said primary partition and intended to collect and absorb the thermal radiation transmitted by said primary partition, through said intermediate channel (3,13) of free air circulation and having an external surface used for indirect heating of the medium to be heated by means of secondary radiation emitted by the primary partition (1.11) and transmitted to the secondary partition (2.12). 3. Device according to claim 1 or 2, characterized in that the air inlet and outlet openings of said intermediate channel are provided with means for adjusting the air circulation in this channel. 4. Device according to claim 1 or 2, characterized in that it is provided with an electric heating resistance which constitutes the energy source is associated with said radiant primary wall (1,21) so as to heat it- ci at a high temperature allowing it to emit thermal radiation in the visible spectrum which passes through said intermediate channel (3) and is picked up by the internal surface of said secondary wall (2), the external surface of which is arranged in contact with water to heat. 5. Device according to claim 1 or 2 comprising a combustion chamber for heating water by radiation, characterized in that said primary, radiating wall (11) delimits the combustion chamber and one side of said intermediate channel (13) whose opposite side is delimited by said secondary wall (12) whose internal surface receives the thermal radiation emitted by said primary wall (11) and whose external surface is arranged in contact with the water to be heated.

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