FR2800443A1 - Heat source for infrared radiation of gas flow has concentric refractory casings heated by gas-air fuel mix fed into interior of inner casing - Google Patents

Abstract

The heat source for infrared radiation of gas flow has five (1,2,4,5) casings with an upper horizontal plate (6) to which the casings are attached concentrically. A central opening (7) is fed with a gas -air mixture flow perpendicular to the plate in the space defined by the first casing (1). The casings can define surfaces of rotation with lateral, oblique or vertical walls. The casings can be made of refractory material.

Description

DESCRIPTION The invention relates to a raised gas heater <B> radiant heater for directional heating capable of providing <B> at </ B> very low gas supply pressures. , a high radiation yield.

This transmitter is intended for surface heating appliances in industrial, craft and tertiary premises as well as any outdoor or semi-outdoor use.

Infrared radiation emitting heaters are currently of common use, some of which have a very good radiation efficiency such as that described in patent EP0382286131 in the name of the applicant. obtaining this high efficiency is conditioned by a nominal gas supply pressure substantially greater than that provided for the transmitter object of the invention.

Other devices have a good yield at low gas supply pressure. tD <B> It </ B> is the traditional radiant <B> to </ B> perforated ceramic refractory plates.

These plates are crossed by the air-gas mixture entering by one side, igniting and radiating on the other face. The limiting factor of the use of these devices <B> to </ B> ceramic plates is their maladaptation to dusty environments because their désenfassement is difficult and washing <B> to </ B> the water is not compatible with ceramic inserts. The disadvantage of these wafers is also their fragility and any split wafer must be changed on pain of communication of the flame <B> to </ B> the inner face of this wafer. It is also necessary to add a bad resistance to drafts.

In another type of apparatus that can operate at very low pressure, but with a medium or poor radiation efficiency, a conventional <B> to </ B> conventional gas, of rectilinear or circular shape, of the type used for household stoves is placed <B> at </ B> the base of a perforated refractory metal enclosure, the flame spouts of the ramp coming to lick the vertical or oblique wall of this enclosure and communicate <B> to </ B> this perforated metal surface, their heat of combustion. The redness thus produced is irregular, inhomogeneous, and the temperature level obtained does not generate a very high performance infrared radiation.

In this type of apparatus <B> to </ B> so-called low flame, one can mention the patent GB <B> 2091869 A </ B> following the same principle as that described above with a burner <B> to </ B> gas type "stove".

This burner, placed <B> at </ B> at the base of the apparatus, raises a circular flame around a heating body made of a black material, insulated on the inner side, and resting on a toasting on the outer side. This flame reaches <B> at full speed <B> to </ B> reach, but without homogeneity, most of the black material, but stops <B> at </ B> mid-height or less, when the regime decreases, resulting in a significant reduction of the radiant surface and therefore the radiation field. Also, in this type of apparatus <B> to </ B> so-called low flame because produced <B> to </ B> the base of a surface capable of producing infrared radiation there are also devices where the flame comes heat refractory ceramic pavers of various shapes, the boom <B> to </ B> beaks being even replaced by a burner <B> to </ B> vertical torch as in the US patent </ B> 4719874. The radiation yield and the range of infrared wavelengths produced may, in the latter case be described as poor and hardly reach the minimum yield threshold permitting the use of the radiant term. Finally, there are also all-metal appliances operating in the same pattern as ceramic plates <B> devices, the latter being replaced by a metal mesh sheet thin and finely perforated. The position of this fishnet, must very slightly deviate from the horizontal for several reasons <B>: </ B> The first reason is that if the device is tilted, the flow of air gas arriving from top to bottom on the inner side, in the middle of the mesh sheet, the lower half of the mesh no longer receives, on the inner side, only a tiny part of the fuel-oxidant mixture, and the combustion on the outer side becomes insignificant on the whole lower half which does not roll more. On the other hand, the upper half receiving twice its fuel-oxidant mixture needs, abnormal overheating is noted. However, the interest of a downward directional infrared transmitter is not to be limited to a restricted area close to the vertical but to be able to provide oblique radiation of greater amplitude in the desired directions. .

To try to reduce this disadvantage of a fishnet too hot on one half and dark on the other, it is certainly expected, internal side, a mesh <B> to </ B> larger mesh, parallel <B> to < / B> the radiation mesh, to spread the flow. If the result is partially achieved when one does not deviate by more than a few degrees from the horizontal position, the effect is practically nil on the <B> beam of </ B> radiation in oblique position.

Finally, the fact that it is provided on this type of transmitter only one finely perforated net for a radiation area corresponding to <B> at </ B> the nominal value of the power of the device, makes this type of device with little inclination <B> to </ B> support a corresponding temperature level <B> to </ B> a very interesting part of the infrared wavelengths <B> to </ B> high radiation efficiency . Experience shows that a single metal mesh, range <B> to </ B> more than <700> C </ B> and receive a low velocity air-to-gas flow <B> at </ b> because of the low pressure), is not able to effectively combat the risk of internal fire.

Finally, for all the above mentioned devices, the resistance to drafts is a limiting factor in practice their use <B> to </ B> an air speed of the order of <B > 1 </ B> meter / second maximum.

Also the present invention aims to <B> to </ B> overcome the disadvantages of these heaters <B> to </ B> infrared transmitter and particularly when it is required to use a very low pressure in nominal value, lower <B> to 50 </ B> mbar.

Another object of the invention is to obtain, on perforated refractory walls, stainless, non-porous, oblique or vertical <B>: </ B> <B> - </ B> a perfectly distributed radiation <B> - < / B> an infrared emission of high temperature to benefit from a high radiation yield, it is <B> to </ B> say a high percentage of heat radiated compared <B> to </ B> the total heat produced. The objective must therefore, to ensure a high reliability of operation <B> at high temperature, to meet the appropriate conditions for the temperature to be as high as possible <B> to </ B> the external surface of the transmitter while being more moderate <B> to </ B> inside, but still sufficient to ensure the pyrolysis of organic dusts.

<B> - </ B> Another object of the invention is to allow, by the stainless and non-porous nature of the emitter, washing <B> to </ B> water, as well <B> </ B> inside and out.

Finally, as will be shown later, the design of the structure allows you to reach # goals <B>: </ B> <B> - </ B> silent operation, <B> - </ B> high resistance to the wind.

The infrared transmitter according to the invention is therefore suitable for many applications when the source of available gas can or must be delivered only at very low pressure, whether it be inherent constraints <B> to </ B> certain distribution networks, compliance with regulations or partial replacement of existing devices, in complete installations designed for very low pressures, it is <B> to </ B> say for pressures generally between <B> 15 </ B> and <B> 50 </ B> mbar.

These applications relate to many areas where a directional infrared transmitter raised heater is <B> to </ B> both the most suitable and economical solution in agriculture, industry, tertiary and other sectors. . To answer <B> to </ B> all of the above mentioned objectives, the realization according to the invcntion consists of a succession of openwork concentric enclosures made of thin, stainless and non-porous refractory material. These nested speakers are organized around an axial mouth, through which is introduced, from top to bottom, the air-gas mixture coming from a conventional feed configuration <B>: </ B> duct, venturi, primary air intake, injector, safety valve, connection <B> to the gas supply.

Figure <B> (1) </ B> gives a nonlimiting example of the embodiment according to a downward conical conical geometry, comprising five concentric enclosures shaped in this example in refractory metal sheet, specifically perforated according to the role <B> j </ B> wired by each speaker. The enclosure <B> (l 1) </ B> is a first distributor of the air-gas mixture intended to <B> to burst this flow uniformly towards all the points of the internal surface of the enclosure (12).

The enclosure (12) is <B> to </ B> both a diffuser of the air-gas mixture distributed by the enclosure <B> (1) </ B> and a flame-return barrier thus avoiding the possibility of a fire <B> at </ b> the injector.

This enclosure (12) also provides a first dust prolysis of the primary air provided by the air-gas flow.

The enclosure <B> (13) </ B> will be described after the enclosure <B> (l <I> 5) </ I> </ B> The enclosure (14) is identical <B> to < / B> the enclosure (12) but its function is different It is <B> to </ B> flower of its outer wall that is established the combustion of the air-gas mixture and the birth of the infrared emission.

The enclosure <B> (l 5) </ B> is called enclosure for confinement and amplification of the infrared emission. It fulfills a known function, in particular in ceramic plates <B> plates, recovery of lost heat, but also a new function of amplification very important of the infrared emission of the enclosure (14) because of the nature and design of these two speakers described below.

The enclosure <B> (13) </ B> is a thermal protection enclosure that screens between the speakers (12) and (14) so as <B> to </ B> moderate the temperature level from <B > (l </ b> 4) in the direction of <B> (l </ B> 2). To illustrate the role of the device <B> (l 3), </ B> it is to limit for example <B> to 700 'C, </ B> the temperature of the surface <B> (l </ B> 2) when the surface (14) is brought <B> to 900 'C. </ B> The <B> screen (13), </ B> lowers by its very presence <B> to <I> 800 </ I> 'C </ B> its own temperature received from (14) and thus limits <B> to 700' C </ B> the temperature of (12), thus avoiding too much reddening thereof and not compromising its role as a barrier against internal combustion. Nevertheless this reddening is sufficient to ensure a first prolysis of the dust of the primary air as indicated above.

Moreover, the enclosure <B> (13) </ B> behaves in relation to the enclosure (14) as a finisher of perfect distribution.

Despite the serious handicap of a gas supply <B> at </ B> very low nominal pressure in an atmospheric burner (without mechanical supply of combustion air) the infrared transmitter according to the invention is suitable <B> for </ B> fulfill the numerous conditions without which the following requirements are not obtained <B>: </ B> <B> - </ B> A homogeneity of the distribution, <B> y </ B> included on oblique or vertical walls of the introduced air-gas flow, which is provided by the distributor <B> (l </ B> Q <B> - </ B> A uniform distribution of the flow thus distributed <B> to </ B> through the broadcast speaker <B> (l </ B> 2) then the screen speaker <B> (13). </ B>

<B> - </ B> A total smoothness of the thin layer of air-to-gas flow entering combustion <B> to </ B> the exit of the perforations of the outer surface of the infrared emission enclosure (14) and consequently a balanced redness of each joint of this emission surface. <B> - </ B> <B> - </ B> A thermal overexcitation of the emission chamber <B> (l </ B> > 4) by the confinement enclosure <B> (l </ B> 5 '), which in turn becomes an auxiliary surface for enhancing the infrared emission of the enclosure (14) - Air efficiency secondary convection participating <B> in </ B> combustion in the space between the speakers (14) and <B> (l <I> 5). </ i> </ B>

Indeed, the secondary convection air, around the infrared emission surface (14), not only meets a medium worn <B> at </ B> high temperature <B> (900 'C) </ B but benefits <B> at </ B> this temperature of a combustion contact surface greater than 20 <B> to 25% </ B> that of the emitting surfaces of the prior art.

<B> - </ B> An electromagnetic spectrum of infrared radiation emitted by refractory surfaces thus arranged, whose wavelengths sought in applications are those contained in the infrared called "near <B>" </ B> received from the sun.

<B> - </ B> A radiation efficiency (radiated power <B> / </ B> nominal power in <B>%) </ B> of up to <B> 70%. </ B>

The detailed description of a preferred but non-limiting embodiment of perforated sheets of refractory metal is based on the cross-sectional drawing of FIG. 1: A tube <B> (17) </ B> conducts the flow of the air-gas mixture towards the inside of a series of <B> 5 </ B> enclosures <B> (I </ B> 1, 12 <B> 13, </ B> 14 , <B> 15), </ B> in the form of thin refractory and perforated sheet metal cones, nested one inside the other, top downwards.

The tube <B> (17) </ B> is integral with a top plate <B> (16) </ B> composed, for construction reasons, of two integral elements <B> (1 </ B> 6a) and <B> (I 6b). </ B> The tube <B> (16) </ B> emerges under the plate <B> (1 </ B> 6a) through a central hole, practiced in this tray, the same diameter as the tube. The tube-tray junction is waterproof. The <B> 5 </ B> speakers <B> (l 1, </ B> 12, <B> 13, </ B> 14, <B> 15) </ B> are fixed by their base and concentrically to the circular plate <B> (16): </ B> <B> - </ B> Enclosure <B> (11): </ B> it is the splitter of the air-gas flow entering by <B> the </ B> tube <B> (17). <B> (11) </ B> must meet the following characteristics <B>: </ B> # its concentric base at the outlet of the tube 'presses against the <B> (16) </ B> board across its entire perimeter. # its height occupies the entire available distance between the <B> (16) </ B> board and the top of the nested speakers as described below.

<B> - </ B> its surface of revolution, perforated, is determined by its diameter <B> to </ B> the base and the height mentioned above.

<B> e </ B> its diameter <B> to </ B> the base is determined according to the desired vertex angle so that the <B> flow </ B> air-passing gas <B> to </ B> through the perforations is distributed uniformly, in quantity and in direction, towards the inner wall of the diffusion chamber (12) the percentage of perforation is determined as a function of the nominal flow rate of the air-gas flow required, a minimum braking speed of this flow to enable it to achieve in the best kinetic energy conditions the inner face of the diffusion chamber (12).

on the other hand, the diameter of the perforations of the enclosure <B> (I </ B> i) must not constitute any gene for the passage of the admitted dust with the flow air (primary) -gas and must therefore be sufficient not to risk a trapped accumulation of dust sucked.

In the embodiment described, but not limited to, the desired result is obtained with a distributor whose characteristics are the following orders of magnitude For a diameter of the arrival tube of the air-gas flow of section <B> (SI): <B> - </ B> The <B> (S2) </ B> section of the dispatcher base <B> (11) </ B> is <B> (S2) = (SI) </ B> x <B> 6 </ B> with a range of <B> (SI) </ B> x 4 <B> to </ B> <B> (SI) </ B> x <B > 6. </ B>

<B> - </ B> The vertex angle is <B> 60 '</ B> For a <B> (S3) </ B> revolution surface of the diffusion enclosure (12) <B > - </ B> The surface of revolution (S4) of the splitter <B> (11) </ B> is (S4) <B≥ (S3) </ B> x 1/4 with a range of <B> (S3) </ B> x 1/4 <B> to (S3) </ B> x <B> 115. </ B>

and for the surface of revolution S4 of the distributor <B> (11), the percentage of perforation is (S4) x 40 <B>% </ B> with holes of diameter of 2 mm and in a range <B> 3 to 3.5 </ B> mm2 of unit section.

<B> N.13: </ B> This distribution enclosure <B> (11) </ B> is never in contact with its external side with the ignited mixture. Unlike the inner cone integral with the tube, described in EP <B> 0382286B 1 </ B> in the name of the applicant, it does not perform the same function. Therefore, the size of the diameter of the perforations of the distributor <B> (11) </ B> can be very significantly greater so as not to be an obstacle to the free passage of dust from the ambient air and a flow in very low pressure.

<B> It should also be noted that the interior space between the <B> (11) </ B> splitter and the diffusion enclosure (12) is a "cold" zone. This has the advantage of a moderate temperature of the air-gas flow and thus of an undisturbed density, as well as a temperature of the plate <B> (16) </ B> which is substantially lower than that, very of the infrared emission surface (14).

As a result, the tube <B> (17) </ B> of the arrival of the air-gas flow and, upstream, the conventional components such as venturi, primary air inlet nozzle, injector port, injector, safety valve etc ... do not have to suffer, by conduction, from high heat.

<B> - </ B> Enclosure (12) <B>: </ B> this is the diffusion enclosure of the air-gas flow received homogeneously in quantity and direction of the distributor <B> (11). </ B>

It is also the flame check barrier (fire <B> to </ B> the injector and internal combustion).

<B> - </ B> the openings according to which this enclosure is perforated have, in this optics a unitary section between <B> 0.70 </ B> and <B> 0.50 </ B> MM2 <B >. </ B> Indeed, the low speed of ejection of the air-gas flow diffused <B> to </ B> through these orifices makes it imprudent a larger section with regard to the non-return flame function.

<B> - </ B> in another optics, which must be taken into account, these holes must have a minimum section of <B> 0,50 </ B> mm 2 <B>: </ B> indeed , this chamber (12) also ensuring, as indicated above, a first pyrolysis of ambient dusts due to its temperature of the order of <B> 700 'C, </ B> it is appropriate to counter-carrer the propensity of mineral ash pyrolized dust <B> to </ B> aggregate around the holes. Too small a unit section of these orifices, on the one hand, would hinder the elimination of these ashes, and on the other hand, would reduce the efficiency of the diffusion function.

<B> - </ B> the anti-backfire function of this chamber (l 2) also leads <B> to </ B> a waterproof fixation of the base of this speaker <B> (l </ B> > 2) to the upper plate <B> (l 6) </ B> and <B> to </ B> the same sealing at the sutures shaping its wall of revolution.

<B> - </ B> finally <B>: </ B> in terms of the ratio of surface area of revolution (12) to <B> to </ B> the distribution enclosure <B> (11) , </ B> the build must be such that <B>: </ B> Surface (12) <B≥ </ B> Surface <B> (11) </ B> x 4 with a range of <B> (11) </ B> x 4 <B> to (11) </ B> x <B> 5. </ B> In terms of the ratio of the openwork surface <B>: </ B> Openwork surface of (12) <B≥ </ B> perforated surface of <B> (11) </ B> 2.5 </ B> with a fork of <B> (11) </ B> x 2 <B> to (l 1) </ B> x <B> 3. </ B> <B> - <B> Enclosure <B> (13): </ B> it is the protective enclosure thermal and first confinement interposed between the enclosure (12) of diffusion and flame back barrier and the enclosure (14) of infrared emission. <B> It </ B> must be noted that the enclosure ( 14) having as described below, a perforated surface identical <B> to </ B> that of the enclosure (12) behaves itself as a first non-return flame barrier but insufficient security due of its high temperature. The interposition between these 2 enclosures (14) and (12) of the enclosure <B> (13) </ B> multiplies the anti-backfire safety by lowering the temperature of the enclosure (12) <B> at </ B> approximately <B> 700 'C </ B> maximum.

<B> - </ B> By cons, it helps <B> to </ B> raise the temperature of emission of the speaker <B> (1 </ B> 4), the space between the speakers < B> (l 3) </ B> and <B> (1 </ B> 4) being the seat of a return effect of the heat of the enclosure <B> (1 </ B> 4), which increases the emissive power of the latter.

<B> N.13: </ B> The usefulness of this <B> (13) </ B> precautionary enclosure in thermal protection of the enclosure (12), increases with the decrease of the nominal pressure of the gas to feed the transmitter object of this description. The lower the diffusion rate, the greater the risk of backfire on a <B> (1 </ B> 2) enclosure, which is too hot and unprotected.

This utility also grows and especially when the transmitter is used in a subject environment <B> to </ B> drafts. The mechanical action of these disturbances of the outside air is able to cause, without the protective wall <B> (13), </ B> a folding wind force capable of passing through the wall of the enclosure (12) and thus to cause internal combustion. In summary, <B> - </ B> if the pressure of the gas is sufficient and if the environment is a perfectly stable environment it may be considered not to have a speaker <B> (l 3) </ B> between the speakers <B> (l </ B> 2) and <B> (l </ B> 4).

<B> - </ B> If the pressure and environmental conditions indicated above are not firmly ensured, it is contraindicated not to provide the enclosure <B> (l 3) </ B> thermal protection and first containment.

The dimensions of the protective enclosure <B> (13) </ B> are identical <B> to those of the enclosure (12).

On the other hand, its wall is perforated according to a percentage of vacuum 1.2 <B> to 1.6 </ B> times greater than that of the wall of the enclosure (12) of diffusion. In the embodiment described, the empty parts of the enclosure (1 <B> 3) </ B> are perforations 2 with a diameter of 2 mm with an elementary section fork of the order of <B> 3 at 4 mm # is of much greater cross-section than perforations of the diffusion enclosure (12) which are <B> 0.8 </ B> mm. This, in order not to significantly curb the passage of the air-gas flow to the enclosure (14) infrared emission.

This <B> (13) </ B> enclosure does not require the need for "watertight" attachment to the upper tray and <b> to </ b> its sutures. However, in the embodiment described, it is crimped to the upper plate between the edges of the enclosures <B> (1 </ B> 2) and <B> (1 </ B> 4) for manufacturing convenience.

The spacing between the speaker walls (12), <B> (13) </ B> and (14) must be regular. This gap is limited because of the low pressure of the gas which induces only a thin dynamic layer of the air-gas flow called <B> to </ B> through the three walls of the speakers <B> (1 </ B > 2, <B> 13, </ B> 14).

For a gas pressure of 20 <B> to 30 </ B> mbar, a good spacing of these three enclosures is around <B> 1.5 </ B> mm.

The regularity of this spacing between the walls can be obtained as in the described mode, by raised ribs <B> (18) </ B> stamped on these walls. The interlocking of the speakers in one another stops at the contact of the relief of the ribs, the height of this relief being calculated to provide the desired value of the spacing between the walls. <B> It </ It goes without saying that any other equivalent means can be used to this effect. The advantage of the raised ribs and successive horizontal crowns, as shown in Fig. (B) (1), is to ensure, in terms of the construction of the apparatus, a rigidity of the walls well adapted to the high temperatures to which the device is subjected. Thus all distortions and deformations are avoided, without obscuring the light emission at the contact lines of the reliefs.

<B> - </ B> <U> Enclosure (14) </ U> <B>: </ B> it is the combustion chamber and infrared emission.

It is identical <B> to </ B> the diffusion enclosure (12), both in its dimensions and its ribs as the percentage of vacuum in which it is perforated. The unitary section of the perforated holes is also identical and between <B> 0.50 </ B> mm2 and <B> 0.70 </ B> mm2. To the two functions <B> already </ B> described for the enclosure (12) of the flame-back barrier and of the passage of the ashes of the ambient dusts sucked with the primary air of the air-gas flow is added that of obtaining a multitude of combustion points corresponding to the dimensional characteristics of the transmitter.

When the apparatus is switched on, the fineness and the blue-violet color of the combustion layer of the air-gas flow which is flush with the external surface of this combustion chamber (14) show that the conditions are met. ideal for a good carburation, regular in all points.

Rapidly, the reddening of the surface of this enclosure (14) is generated due to its constitution of low inertia.

The resulting infrared emission therefore benefits from the same regularity and surface homogeneity.

The fixing of this enclosure <B> (l </ B> 4), nested on the enclosure <B> (l 3) </ B> must meet the same "sealing" requirements as the enclosure (12) for the same reasons, the crossing of its wall by the air-gas flow before its ignition should be made exclusively by the days calibrated its entire surface. The temperature of this chamber <B> (l </ B> 4) being particularly high, and the low pressure, no parasitic crack of size greater than the calibrated days, whether in length or width, can not be accepted. Therefore, this enclosure (14) infrared emission is also crimped to the upper plate and its construction sutures carefully closed. The raised ribs, stamped on its walls are identical <B> to </ B> those of the speakers <B> (13) </ B> and <B> (1 </ B> 2) and fulfill the same functions of maintaining spacing with enclosure <B> (13) </ B> and no deformation <B> to </ B> heat.

<B> - </ B> Enclosure <B> (1 <I> 5) </ I>: </ B> It's <B> to </ B> the outside, the last enclosure called second containment and amplifying the infrared emission.

In patent EP.03 <B> 82.286B 1 </ B>, in the name of the applicant, there exists an identical enclosure, in its form, but not in its function.

In this patent EP.0382.286Bl it is implemented that two conical speakers One of diffusion, shape and function different from those of the present description, is responsible for projecting <B> to </ B> distance and <B> to </ B> high or medium pressure the air-gas flow.

The other, similar to the <B> (l 5) </ B> speaker of the present description, is able because of the pressure sufficient to receive <B> at </ B> > distance the flaming air-gas flow and directly produce the entire nominal infrared emission on its single wall.

The patent <B> to </ B> two enclosures cited above is therefore not adapted to the problem posed by very low nominal pressures, the combustion and radiation conditions being degraded by insufficient projection speed air-gas flow, which, in the case of this patent, is ignited between the two enclosures, which is not the case in the present invention.

In the present invention, on the contrary, this latter enclosure can not only recover, as in the prior art, a part of the non-radiating heat that would be lost in front of the infra-red emission plate or mesh, but this which is new, this enclosure <B> (l 5) </ B> by its particular construction and positioning characteristics can also fulfill a function of confinement allowing a maximum recovery of the heat which would be lost, this confinement being conceived to not affect the quality of combustion <B> at </ B> the external surface of the infrared emission enclosure (14).

These specific confinement conditions achieved by the <B> (l 5) </ B> enclosure and positioned as described below greatly amplify the temperature between the <B> (1 </ B> 4) and <B > (15). </ B> The effect obtained is a shortening of the wavelengths of the infrared emission resulting in an increase of the electromagnetic frequency. This electromagnetic overexitation increases <B> to </ B> in turn the level of infrared energy exchanged permanently, from one <B> to </ B> the other and vice versa, by the walls of these two parallel speakers in every way.

To obtain this synergy of the two enclosures <B> (1 </ B> 4) and <B> (15), </ B> the present design thus provides the combination of the following two parameters <B>: </ B <B> - </ B> the perforated surface of the wall <B> (l 5) </ B> does not exceed <B> 1.6 </ B> times the perforated surface of the wall <B> (l </ b> 4) with a range of 1.2 <B> to 1.6. </ B>

<B> - </ B> the spacing of these two walls is adjustable according to the value of the gas supply pressure. This, in order to give <B> to </ B> the spacing between these two speakers <B> (l </ B> 4) and <B> (15) </ B> the value adapted to the volume of optimum containment which may be greater if the gas pressure is higher. <B> A </ B> is indicative, in the described mode, for a pressure of between 20 and <B> 30 </ b> mbar, this spread and order of <B> 8 </ B> mm.

<B> N.13 </ B>: A spacing <B> frozen </ B> by construction would cause for pressures not related to this spacing, a parasitic noise wriggling, while the present transmitter according to the invention is perfectly quiet. The subjection of this last enclosure <B> (15) </ B> can be obtained, as in the mode described, by fixing brackets <B> (I </ B> 9) to the upper plate <B> ( 1 6b) of adjustable height, depending on the model of the appliance and the nominal gas pressure <B> to </ B> for which it is intended. Finally, as for other enclosures stamped embossed ribs or any other type of stiffening prevent any deformation <B> to </ B> high temperature.

The detailed description of the preceding embodiment is not limiting.

Other geometries, depending on the chosen applications can be made according to the basic criteria of the invention.

<B> A </ B> As an example, we can cite various geometries that lend themselves well <B> to </ B> the very conception of the apparatus and such that <B>: - </ B> < B> - </ B> the frustoconical shape (fig.2a) of the speakers <B> (1 </ B> Q, (12), <B> (13), </ B> (14) and <B> (15) </ B> If we want to limit ourselves to oblique radiation.

<B> - </ B> the vertical cylindrical shape (Fig.2b) if one wants to favor a horizontal radiation <B> - </ B> the hemispherical shape (Fig.2c) and (Fig.2d) In the <B> (2b), </ B> (2c) and <B> (2d) </ B> geometries with <B> (11), (1 </ B> 2), <B> (13) speakers ), </ B> (14) and <B> (l 5) </ B> vertical <B> (2b) </ B> or hemispherical (2c) and <B> (2d), </ b> it is advantageous to provide <B> to </ B> the inside of the distribution enclosure <B> (l 1) </ B> a full or finely perforated pre-distributor conical inverse to pre-direct the flow air-gas uniformly towards the diffusion enclosure (12).

This combination is a means giving an equivalent result <B> to </ B> that obtained directly by the single conical splitter <B> (11) </ B> of the embodiment described above. In summary, in many aspects, the infrared transmitter according to the invention, for operation at very low pressure has advantages among which can be cited <B>: </ B> <B> - </ B> a range of electro-magnetic wavelength positioning it in the middle of the spectrum of useful heat of the sun for the well-being of living beings.

<B> - </ B> a radiation yield of the order of <B> 70% </ B> <B> - </ B> resistance to wind allowing it to accept, without extinction, currents of more than 2 meters / second.

<B> - It </ B> is dust-free <B> to </ B> the air and does not fear compressed air pressure jets from <B> 7 to 8 </ B> bars unlike appliances <B> to </ B> ceramic plates on which it is recommended not to exceed 2 bars.

<B> - </ B> It is also washable <B> to </ B> water since made of stainless and non-porous material.

<B> - It </ B> is easy <B> to </ B> install, without heavy suspension infrastructure, because of its low weight compared with <B> at </ b> its heat output.

These various aspects explain for themselves the economic nature of this infrared heating transmitter <B> to </ B> gas designed to accept without handicap a gas supply <B> at </ B> very low pressure without recourse < B> to </ B> an electro-mechanical device for propelling the air-gas mixture.

Claims (1)

CLAIMS <B> 1. </ B> Infrared transmitter <B> to </ B> light radiation for gas supply <B> to </ B> very low pressure especially for heaters suspended for directional heating to the and / or on the sides in the agricultural, industrial, craft and tertiary sectors, characterized in that - it comprises in combination <B>: </ B> a geometric structure that can take various forms (Fig. < B> 1, </ b> 2a, <B> 2b, </ b> 2c, <B> 2d) </ B> and composed of: <B> - </ B> of at least 4 concentric speakers <B > (11), (1 </ B> 2), (14), <B> (15), </ B> a fifth speaker <B> (l 3), </ B> also concentric which can be interposed between the enclosures (12) and (14) according to the conditions of prossion gas supply and instability of the ambient air of the environment. These enclosures <B> (l 1), </ B> (12), <B> (13), </ B> (14), <B> (15) </ B> having side walls, oblique, vertical or hemispherical depending on the selected geometries of thin material, refractory, stainless, non-porous and blushing <B> to </ B> heat. -an upper plate <B> (16) </ B> substantially horizontal, open at its center, and in which said speakers are fixed concentrically to said plate, -entered one into the other. <B> - </ B> a central mouth <B> (l 7) </ B> secured to the tray <B> (l 6) </ B> and sealed with it, bringing perpendicular to said plateau by the central opening thereof and in the interior space created by the enclosure <B> (l 1) </ B> the air-gas flow coming upstream of a conventional configuration of primary air supply and in gas for atmospheric burner and thus comprising in particular the known elements such as venturi, primary air intake, injector, injector holder, safety valve, gas supply connection. 2. Transmitter according to claim 1, characterized in that the perforated enclosures <B> (1), (1 </ B> 2), <B> (13), </ B> (14) and <B> (l 5) </ B> have specific characteristics <B> to </ B> their respective function (s) <B>: </ B> L enclosing <B> (l 1) </ B> said distribution having according to the chosen geometries <B> - </ B> a section of its base fixed to the top plate <B> (16) </ B> in ratio of size from 4 <B> to 6 </ B> with section of mouth <B> (17) </ B> <B> - </ B> a surface of revolution in ratio of magnitude of 1 / 4 <B> to 1/5 </ B> with the surface of revolution (the enclosure (12) following. <B> - </ B> a percentage of surface openwork compared <B> to </ B> > the total area of the order of 40 <B>% </ B> with elementary orifices of the order of <B> 3 to 3.5 </ B> mm 2 of unitary section. said diffusion and second barrier anti-back flame presenting according to the dimensions and the geometries of real <B>: </ B> <B> - </ B> a surface of revolution in magnitude ratio of 4 <B> <I> to </ I> 5 </ B> with the distribution enclosure < B> (l 1 </ B> <B> - </ B> a total surface of the openwork parts in ratio of size 2 <B> to 3 </ B> with the total surface of the perforated parts of the distribution enclosure <B> (11) <B> - </ B> an elementary section of <B> 0.50 to 0.70 </ B> mm2 for each of the holes constituting the perforated part. <B> - </ B> a fastening method ensuring the sealing of junction with the top plate <B> (l 6) </ B> The enclosure <B> (l 3) </ B> called protection thermal and first confinement presenting according to the dimensions and the geometries of realization <B>: </ B> <B> - </ B> a surface of revolution substantially identical <B> to </ B> that of the enclosure ( 12) <B> - </ B> a total area of the perforated parts in size ratio of 1.2 <B> to 1.6 </ B> with the total area of the perforated parts of the diffusion enclosure (12 ). <B> - </ B> an elementary section of the order of <B> 3 to </ B> 4 mm 2 for each perforated surface orifices The enclosure (14) called infrared emission and first barrier flame arrestor having, for all its characteristics, a sensitive identity with the enclosure <B> (1 </ B> 2), <B> y </ B> including a mode of fixing ensuring the sealing of junction with the upper shelf. The enclosure <B> (15) </ B> said second confinement and amplification by excitation of the electromagnetic emission of the enclosure (14) characterized in that it differs from known grids by < B>: </ B> <B> - </ B> a total open area in a size ratio limiting <B> to </ B> a value of 1.2 <B> 1.6 </ B> times the total open area of the emission chamber (14). <B> - </ B> a spacing with the enclosure (14) adjustable according to the gas supply pressure. <B> - </ B> adjustable brackets <B> (19) </ B> <B> 3. </ B> Transmitter according to claims <B> 1 </ B> and 2 characterized in that <B>: </ B> <B> - </ B> the sidewalls of the enclosures (12), <B> (13), </ B> (14) are spaced apart by spacing means such as embossed ribs on these enclosures, holding them <B> at </ B> a controlled distance from each other and serving as anti-deformation stiffeners <B> to </ B> heat without obscuring the light emission to the contact lines of the reliefs. 4. Transmitter according to claim 1, characterized in that its geometric structure can take various forms such that the conical shape (FIG. 1), </ i> B> Base Up Speakers <B> (11), (1 </ B> 2), (13), (14), <B> (15) <B> - </ B> the truncated-conical shape (2a), large base upwards of the said enclosures <B> - </ B> the cylindrical shape <B> (2b) </ B> if it is desired to have an emitting surface of vertical revolution < B> - </ B> hemispherical shape (2c) or <B> (2d), </ B> circular section up <B> 5. </ B> Transmitter according to claims <B> 1 </ B and 4, characterized in that the respective distribution enclosures <B> (l 1) </ B> for the forms <B> (2b), </ B> (2c), <B> (2d) </ B> have in their internal volume, along the central vertical axis of symmetry, a cone solid or very finely perforated, top up to the outlet of the flow of air-gas, thus becoming in combination with the speakers <B > (11) </ B> of these said forms a equivalent means of perfect distribution of the air-gas flow such as that obtained directly with the enclosure <B> (11), </ B> top down of the conical shape (Fig. <B> 1). </ B>