EP0200637A1 - Apparatus for the production of a high temperature gas jet - Google Patents

Abstract

A tubular case closed at its two ends respectively by a first side wall carrying two electric supply terminals and a second side wall carrying a hot gas outlet nozzle for discharging a jet of heated oxygen. A heating tube extends axially through the case constituting a heating resistance, the wall or this heating tube being provided in one of its end portions with at least one opening for the passage of the gas to the interior of the heating tube and the outlet nozzle. The case also includes a heat exchanger of thermoconductive material and gas pre-heating means.

Description

The present invention relates to an apparatus for producing a jet of gas at high temperature, comprising an enclosure, means for introducing a gas into this enclosure, means for heating the gas in the enclosure and means for evacuation of hot gas from the enclosure.

In various industrial fields, jets of hot oxidizing gas, in particular oxygen, are used. For example, the flame-cutting technique uses a torch from which a high-speed oxygen jet comes out surrounded by a heating flame.

The chemical phenomenon involved in flame cutting is not very well known. There is probably an oxidation of iron in the form of oxides (FeO, Fe203, Fe30 ₄ ) oxides which have a melting temperature lower than that of the metal. We actually observe the presence of a shiny liquid sheath between the oxygen jet and the bleeding front, this liquid sheath being entrained by the oxygen jet and discharged to the outside in the form of droplets and sparks . Oxygen must diffuse in this liquid zone to maintain the iron combustion reaction. As this reaction is highly exothermic, the calories released are then used to maintain the high temperature necessary for the fusion of the oxides.

Currently the peripheral heating flame is essential for initiating the reaction. After priming, the essential role of this heating flame is to maintain the upper edge of the bleeding front at a temperature sufficient for the sheath of liquid slag to be renewed. However, the necessary calories being provided by the iron oxidation reaction, the heating in fact takes place only to avoid risks of defusing.

It therefore appears advantageous to be able to dispense with the permanent presence of this heating flank, and / or then increase the cutting speed and this constituting one of the aims of the invention.

Furthermore, in other industrial sectors it is also desirable to be able to have a hot gas generator, this gas being able to be an oxidizing gas by applications such as metallurgy, oxy-fuel burners, etc. non-oxidizing or inert gas, such as nitrogen, etc. in applications, for example, of the heat treatment type.

It is known from German patent 726668 to cool the nozzle of mixing a torch using cutting oxygen, brought around the latter in a coil surrounding the nozzle, the oxygen being thus preheated by recovery of part of the heat given off by the oxy-cutting reaction.

If it is envisaged in this patent to recover part of the heat given off by the cutting, this essentially has the purpose of cooling the cutting nozzle and avoiding an additional water cooling circuit.

The object of the present invention is therefore to provide a device of particularly simple design, having good thermal efficiency and making it possible to produce at its outlet a jet of gas at a very high temperature, which can reach 1600 ° C. at most.

The apparatus according to the invention is characterized in that the means for heating the gas in the enclosure consist, on the one hand, of a heating tube extending across the enclosure and constituting a heating resistor , this tube comprising electrical connection means for the connection of this resistor to electrical supply means, and on the other hand, heat exchanger means arranged around the heating tube and in thermal contact therewith, said means comprising at least one gas pipe from the means of introduction into the enclosure to an opening located near the first end of the heating tube, the second end of which communicates with the means for evacuating the hot gas from the enclosure, the gas thus being heated in the heat exchanger means before passing inside the heating tube to finally flow through the means for evacuating the hot gas from the enclosure.

• la figure 1 est une vue en coupe axiale d'un appareil pour la production d'un jet de gaz à haute température, utilisable notanment pour une opération d'oxycoupage.
• les figures 2, 3, 4, 5 et 6 sont des vues en coupe de variantes d'exécution de l'appareil.

Various embodiments of the present invention will be described below, by way of non-limiting examples, with reference to the appended drawing in which:

• Figure 1 is an axial sectional view of an apparatus for producing a jet of gas at high temperature, usable in particular for an oxygen cutting operation.
• Figures 2, 3, 4, 5 and 6 are sectional views of alternative embodiments of the device.

The apparatus shown in FIG. 1 comprises a tubular enclosure 1, for example made of stainless steel or of refractory material, the two opposite ends of which are closed by transverse flanges 2 and 3 respectively. The straight closing flange 3 is welded to the right end of the tubular enclosure 1 while the left flange 2 is removably mounted on a flange 4 welded to the left end of the enclosure 1 and it is fixed to this flange 4 by means of bolts 5. This closing flange 2 constitutes a support for two electrical supply terminals, one of which forms part of an electrical contact 6 engaged inside the enclosure 1, mounted to slide axially in the flange 2 and which is biased towards inside the enclosure by a spring 7 compressed between two washers 8 and 9, for example made of alumina. The washer 8 is held in abutment against a collar 6a of the contact 6 while the insulating sleeve 9 is engaged through the central part of the closing flange 2. The contact 6 projects axially outside the closing flange 2 and its outer end constitutes a terminal which can be connected to the positive pole of a DC power source, the negative pole of which is connected to the closing flange 2, for example by means of a terminal immobilized by one of the bolts 5 forming a negative terminal. However, the device can also operate with an alternative power source.

Inside the enclosure 1 is housed a heating element 11 constituted by a tube made of a ceramic material such as zirconia or lanthanum chranite or the two associated for example. Such a ceramic compound has the particularity of being both refractory (melting around 2,500 ° C.) and electrical conductor from room temperature. This ceramic tube preferably consists of a resistant central part and of conductive end parts having a resistivity about ten times lower than that of the central part. The extreme parts with low resistivity may comprise, on the ceramic tube with constant resistivity, platinum-plated external zones. However, according to a variant, the tube 11 could be entirely electrically resistant.

The ceramic heating tube 11 is fitted at its right end into a housing 3a of the same diameter provided in the internal front face of the right closing flange 3 and it is applied against the bottom of this housing 3a under the effect of the pressure exerted by the contact 6 on its opposite end, under the action of the spring 7. In fact this contact 6 is applied against the front face of a conductive end piece 12 itself bearing against the left end of the ceramic heating tube 11. The extreme left part of the heating tube 11 and the conductive washer 12 are housed in the internal recess of an alumina ring 13 engaged in the enclosure 1 and the external diameter corresponds to the internal diameter of this enclosure.

The ceramic heating tube 11 may or may not have a machined outer surface. This surface may, for example, have a thread or even longitudinal grooves.

The ceramic heating tube 11 is surrounded, over most of its length, by a heat exchanger made of thermally conductive material. This heat exchanger can be constituted by at least one internal tube 14 made of dense thermally conductive material, (for example made of alumina or lanthanum chrcmite) which is itself surrounded by an external tube 15 made of porous thermally conductive material, (for example made of alumina porous). Finally, a winding of zirconia felt 16 can optionally be provided between the external tube 15 made of porous alumina and the tubular enclosure 1.

The gas which must be heated, such as oxygen or air for example, flows through an external coil 17 which is wound around the tubular enclosure 1 and in thermal contact with it. The gas is introduced into the coil 17 at its left end, that is to say the one where the contact 6 is located, and it penetrates inside the enclosure 1, at the right end of the coil which communicates with the interior of the enclosure 1, by means of a hole 18 drilled at this location in the wall of this enclosure. The gas which enters the enclosure 1 at its right end, then flows, through the pipes 117, 118 as it is indicated by the arrows, longitudinally from right to left, through the external porous alumina tube 15 which may optionally have longitudinal grooves to facilitate this flow, and possibly through the zirconia felt winding 16 if the latter is present. At the left end of the porous alumina tube 15 the gas exits in a space delimited between this left end and the ring 13 in alumina, then it reverses its direction of flow while passing, from the left towards the straight, between the dense alumina tube 14 and the ceramic heating tube 11. This flow can be facilitated by the presence of longitudinal grooves or a thread, on the external surface of the heating tube 11 or on the internal surface of the alumina tube dense 14. In its straight part the heating tube 11 has, in its wall, at least one opening 19 which allows the gas to pass inside the tube 11. The hot gas can then exit the device, flowing, in the form of an axial jet, through an outlet nozzle 21 removably fixed, by means of screws 22, on the right closing flange 3. This nozzle 21 can be a well-known flame-cutting nozzle, cooled or not. In the nonlimiting example illustrated in FIG. 1, this nozzle 1 is cooled by water supplied by a pipe 23. It also has an inlet port 24 for connection to a source of heating gas.

When the appliance is in operation, the ceramic tube 11 is heated by the electric current passing from the contact 6, through the conductive washer 12, then over the entire length of the heating tube 11 to the left closing flange 2 which is connected to the negative pole of the electrical power source, i.e. to ground. Due to the passage of this electric current, the ceramic tube 11 heats up in its central part with high resistivity, so that the temperature of this central part can wait for approximately 1,800 ° C. in normal operation. The end parts of the heating tube 11 reach a temperature below 400 ° C, due to their much lower resistivity, which allows good electrical contact to be maintained. The heating tube 11 can be supplied with alternating or direct current, this heating tube being as pure resistance. The measurement of the intensity and the voltage of the current makes it possible to adjust the Joule power supplied to the heating tube 11 and consequently the calorific power which can be absorbed by the gas. The tubes 14 of dense alumina and 15 of porous alumina heat up together with the internal heating tube 11 and in turn heat the enclosure 1 and the coil 17. The gas flowing in the coil 17 is gradually preheated therein. ci, it enters the enclosure 1, at the outlet of the coil 17, then continues to heat up when it flows first from the right to the left through the external porous alumina tube 15 and possibly the winding of zirconia felt 16, then from left to right between the alumina tube dense 14 and the heating tube 11. As a result, the gas jet leaving the nozzle 21 can reach a temperature in the region of 1600 ° C.

Although coaxial alumina tubes 14 and 15 are preferably used between the central heating tube 11 and the external enclosure 1, it is also possible to use tubes of another material, for example of lanthanum. The dense alumina tube 14 is advantageously used because it has good thermal characteristics, an expansion coefficient close to that of the lanthanum chromite constituting the heating tube 11 and it also withstands very high temperatures. The porous alumina tube 15 which is preferably used around the dense alumina tube 14, offers the advantage of being a better thermal insulator than the dense alumina.

The winding of zirconia felt 16 which is optionally provided between the porous alumina tube 15 and the enclosure 1, makes it possible to reinforce the insulation and also to provide a significant exchange surface for the gas which also preheats by crossing

As described above, the electrical contact 6 is resiliently biased by the spring 7 against the heating tube 11, by means of the conductive washer 12. This allows the axial expansion and contraction of the heating tube 11 while retaining a good electrical contact. This expansion or contraction which is transmitted to the external part of the contact 6, can possibly be used for the regulation of the temperature of the heating tube 11.

The extreme left part of the enclosure 1 where the electrical contact 6 is located, is advantageously cooled by a circulation of water in an internal tube 25 fixed, for example, to the internal face of the flange 4. To perfect the presentation of the entire apparatus, the coil 17 which is traversed by the still relatively cold gas, is advantageously covered with a layer 26 of a thermally insulating material, the latter being in turn surrounded by an external cylinder 27.

In the variant embodiment of the device which is illustrated in FIG. 2, a dense alumina tube 28 is housed coaxially inside the heating tube 11 and this tube 28 is engaged, by its straight end, in a housing for same diameter provided in the internal face of the right closing flange 3. This flange is, in this case, removably mounted on a cylindrical support 29 welded to the right end of the enclosure 1, the fixing of the removable flange 3 to the support 29 being carried out by means of screws 31. In the internal face of the removable closing flange 3 are housed, on the one hand, the housing 3a, of relatively large diameter , receiving the right end of the heating tube 11, and on the other hand another housing 3b, of smaller diameter than the previous one but deeper, receiving the right end of the inner tube 28 of dense alumina. A platinum cup 32 is interposed between the extreme right part of the heating tube 11 and its housing 3a in the closing flange 3.

Furthermore, in the embodiment illustrated in FIG. 2, the internal tube 14 of dense alumina has a length greater than that of the external tube 15 of porous alumina. In fact the tube 15 made of porous alumina extends to the left front face 29a of the support 29 while the tube 14 of dense alumina penetrates inside this support 29 and passes completely through it to come into contact at its straight end with the internal face of the removable closing flange 3, An asbestos washer is interposed between the extreme right part of the dense alumina tube 14 and the cylindrical internal wall of the support 29, this washer being axially tightened by an internal coaxial flange 30 of the right closing flange 3.

The inner tube 28 of dense alumina stops, inside the heating tube 11, at a certain distance from the left end of the latter. Furthermore, the electrical contact 6 is supported on a conductive end piece 33 containing a platinum cup 34 which covers the left end of the heating tube 11 which is platinized. The conductive end piece 33 is extended to the right by an axial finger 35 extending partly inside the inner tube 28 of dense alumina.

In its extreme left part, the inner tube 28 of dense alumina has at least one longitudinal slot 36 allowing the passage of the gas inside the tube 28.

With this arrangement, the gas which penetrates inside the heating tube 11, through the holes or slots 19 provided in its extreme right part, again flows inside the tube 11 to the left, into the space delimited between this heating tube and the inner tube 28 made of dense alumina, then it passes through the slot or slots 36 provided in the extreme left part of the tube 28 to flow from again inside the tube 28 from left to right in the direction of the outlet nozzle 21.

FIG. 3 illustrates an alternative embodiment of the apparatus similar to that of FIG. 2 but in which the oxygen cutting nozzle 21 and the electrical contact 10 are not cooled by a circulation of water. In this case the contact 6 extends inside a finned radiator 37 mounted on the left closing flange 2 and which thus ensures the natural cooling of the contact 6. Furthermore, in this variant the device does not include more coil which is replaced by a cylindrical chamber 17a surrounding the heat exchanger 14, 15.

In the alternative embodiment illustrated in FIG. 4, the heating tube 11 is immobilized, in its extreme right part, that is to say that which is close to the outlet nozzle 21, by means of a clamp 38 in stainless steel with interposition of an asbestos ring 39 between the extreme right part of the heating tube 11 and the right closing flange 3. Furthermore, in this embodiment, the gas is introduced into a thread 17b at its end located on the right side, that is to say on the side of the outlet nozzle 21, this thread 17b being machined in the external surface of the tubular enclosure 1. The gas penetrates inside the enclosure 1 by holes 18 located in the left part of the enclosure 1. As a result, the gas penetrating inside the enclosure 1 flows from the left to the right through the external porous alumina tube 15 then from the right to left between the inner tube 14 of dense alumina and the heating tube 11, it penetrates inside this heated tube ant by passing through the slots 19 provided in the extreme left part of the heating tube 11 and it flows axially to the right, in the direction of the outlet nozzle21. On this nozzle is fixed a tube 41 of alumina, of short length and which extends inside the extreme right part of the heating tube 11.

In the embodiment illustrated in FIG. 4, the dense alumina tube 14 is immobilized by a cable gland 42 near the electrical contact 6. Furthermore, the cooling of the left part of the device is obtained by means of 'A circulation of water in an external cylindrical chamber 25a.

In the alternative embodiment illustrated in FIG. 5, the extreme left part of the heating tube 11 is directly connected to an electrical supply terminal 43, carried by the closing flange. left 2, via a braid 44. Furthermore, a thermocouple 45, used for regulation, can also be introduced axially inside the heating tube 11, through the left closing flange 2. It is possible to also introduce longitudinally, into the heating tube 11, another tube for heating or preheating any fluid, through this tube of refractory material.

FIG. 6 represents a preferred embodiment of the invention in which the enclosure (right part of the figure) has a structure similar to that of the preceding figures, the introduction of hot gas being however made by the end opening of the heating tube, while the electrical supply means of the heating tube (left part of the figure), have a structure adapted to the internal expansion movements of the heating tube.

The device according to this variant comprises an outer protective casing 101 surrounding the enclosure formed by the tubes 102 and 104 arranged coaxially, for example made of refractory steel, between which a gas circulation space 103 is provided. This space 103 has the shape of a helix, machined in the external surface of 104, the gas being introduced through the orifice 123 at the end (left in the figure) of the enclosure, and leaving through the orifice 120 (right end in the figure) to follow the channel 105 located between the inner wall of the tube 104 and a first alumina tube 106, inert, not heating, the gas thus returning to the level of the left end. It then follows the channel 107 located between the first tube 106 and a second tube 108 of the same kind as 107. The gas thus returns to the level of the right end of the enclosure or a passage 121 is provided for returning the gas in contact with the outer face of the heating tube 111 in the channel 109, located between the last and the second alumina tube 108. the gas then enters the interior of the heating tube 111 via openings 110 located in the centralizer 124 which also brought the electrical voltage to the heating tube 111 by the electrical contact 126.

The flow of current takes place at the level of the annular rim 112. The gas passes through the entire heating tube and is evacuated (at the right end of the figure), through the opening 114 placed in the axis of the heating tube 111 , in the flange 115. On this is fixed, in the example of the figure a nozzle 116 whose channel 117 is placed in the extension of the channel 114, said nozzle also comprising a fuel supply channel 118.

This nozzle makes it possible to use hot gas, for example oxygen in an oxy-fuel torch or an oxy-fuel burner.

The flange 115 is electrically connected to the heating tube by a washer 113, for example made of platinum, crimped at the end of the heating tube 111, for example made of lanthanum chromite.

The electrical circuit is closed up to the electrical connection 135, by means of the steel tubes 102 and 104, held coaxially by the other flange 127 on which the conductive parts 128 and 136 are fixed, enveloping the electrical connections.

The electrical contact 126, the end of which forms a centering device 124 of the heating tube 111 is electrically isolated from the contact envelope part 128 by a sliding part 125, integral with the contact 126, capable of sliding inside the part 128 against which it possibly comes into abutment at 138 under the thrust of the spring 131, thus making it possible to maintain the heating tube 111 in position, an expansion of the latter compressing said spring. The end (left in the figure) of the contact 126 is connected to a flexible wire 130, for example of platinum of sufficient length to absorb the dilations of the device, the other end of which is integral with the contact 133 fixed in the parts insulators 132 and 139 from which opens the second electrical contact 134 for connecting the heating tube to electrical supply means not shown in the figure. The part 132 comprises an annular housing in which the said spring 13 is supported. The part 136 which surrounds the insulating parts 125, 132, 139 comprises a space 137 for the circulation of cooling water at the level of the electrical contacts, in order to preserve the characteristics of the spring and the enclosure seals. It should be noted that in operation the spring 131 makes it possible to maintain the electrical contact between the heating tube 111, and the contact 126, both in contraction and in expansion.

For the heating of the oxidizing gases, a heating tube made of lanthanum chromite, zirconia, molybdenum bisilicide or silicon carbide is used. For neutral or reducing gases, carbon, graphite, mobybdenum, tungsten, tantalum, silicon carbide can also be used.

In general and whatever the gas, a material will be used which, by the Joule effect, can reach at most a temperature of the order of 2,300 ° C.

In order to increase the temperature of the gas leaving the device, at constant flow, it is desirable to place several heating tubes, coaxially, with a gas circulation between them in the form of longitudinal baffles (as is the case between the tubes 106, 108, and 111) or by machining a helical channel on the surface of a tube which comes to slip exactly into the other, or approximately (as is the case for tubes 102 and 104 ).

Claims (27)

1. Apparatus for producing a jet of gas at high temperature comprising an enclosure, means for introducing a gas into this enclosure, means for heating the gas in the enclosure and means for discharging the gas hot of the enclosure, characterized in that the gas heating means in the enclosure consist, on the one hand, of a heating tube (11) extending across the enclosure (1) and constituting a heating resistor, this tube (11) comprising electrical connection means for the connection of this resistor to electrical supply means, and on the other hand, heat exchanger means (14, 15, 16,17) arranged around the heating tube and in thermal contact therewith, said means (14, 15, 16, 17) comprising at least one pipe (117, 118) for conducting gas from the means of introduction (18) into the enclosure to an opening located near the first end of the heating tube (11), the second end of which co mmunique with the means for evacuating the hot gas from the enclosure, the gas thus being heated in the heat exchanger means before passing inside the heating tube to finally flow through the means for evacuating the hot gas of the enclosure. 2. Apparatus according to claim 1, characterized in that the opening of the heating tube is constituted by the first end of said tube. 3. Apparatus according to claim 1, characterized in that the opening of the heating tube is formed in the lateral surface of said tube. 4. Apparatus according to one of claims 1 to 3, characterized in that the means for discharging the hot gas from the enclosure consist of a nozzle connected to the second end of the heating tube. 5. Apparatus according to one of claims 1 to 4, characterized in that it further comprises means for preheating the gas (17, 17a, 17b) at least partially surrounding the enclosure so that the gas is preheated before enter the enclosure. 6. Apparatus according to one of claims 1 to 5, characterized in that the enclosure is tubular, closed at its two ends respectively by two transverse flanges, a first flange carrying two terminals, isolated from each other other, connecting to electrical supply means and a second flange, crossed by the means for evacuating the hot gas from the enclosure. 7. Apparatus according to one of claims 1 to 6, characterized in that the heating tube is made of a material which, by Joule effect, can reach at most a temperature of the order of 2.300 ° C. 8. Apparatus according to one of claims 1 to 7, characterized in that the heating tube is made of a material chosen from one or more of the materials such as zirconia, lanthanum chrcmite, silicon carbide, disilicide of nobybdenum, carbon, graphite, molybdenum, tungsten, tantalum. 9. Apparatus according to one of claims 1 to 8, characterized in that the heating tube (11) comprises a resistant central part capable of heating by Joule effect and at least one end made of a material of low electrical resistivity. 10. Apparatus according to any one of the preceding claims, characterized in that the heat exchanger means consist of at least one internal tube (14) made of dense thermally conductive material, which is itself surrounded by an external tube (15) in thermally conductive material. 11. Apparatus according to claim 10 characterized in that it comprises a winding of zirconia felt (16) between the outer tube (1) of porous alumina and the tubular enclosure (1). 12. Apparatus according to one of claims 5 to 11 characterized in that the inlet of the gas preheating means (17) is located on the side of the first flange (2) carrying the terminals, their outlet end communicating with the inside the tubular enclosure (1) via a hole (18) located on the side of the second closing flange (3) carrying the outlet nozzle (21) and the heating tube (11) is pierced with at least sun hole or slot (19) for gas passage located on the side of the second closing flange (3). 13. Apparatus according to one of claims 5 to 11 characterized in that the inlet of the gas preheating means (17) is located on the side of the second closure flange (3) carrying the outlet nozzle (21), their outlet end communicating with the interior of the tubular enclosure (1) via a hole (18) located on the side of the first closing flange (2), the heating tube (11) being pierced with at least a hole or slot (lç) in its end part facing the first closing flange (2). 14. Apparatus according to any one of the preceding claims, characterized in that a thread or longitudinal grooves (lla) are provided, for the passage of gas, in the heat exchanger means (102, 104, 106, 108) on the external and / or internal surface of at least one of the tubes (102, 104, 106, 108) constituting said heat exchanger means. 15. Apparatus according to any one of the preceding claims, characterized in that a tube made of thermally conductive material (28) is engaged axially in the heating tube (11), from the second closing flange (3), and this refractory tube (28) stops at a distance from the end of the heating tube (11) which faces the first closing flange (2). 16. Apparatus according to claim 15, characterized in that the internal tube of thermally conductive material (28) extends over the greater part of the length of the heating tube (11), near its end facing the first closing flange (2), and the tube (28) is pierced, in this extreme part, with at least one hole or slot (36) for the passage of gas in the direction of the outlet nozzle (21). 17. Apparatus according to any one of the preceding claims, characterized in that the first closing flange (2) carries, in its central part, an insulating sleeve (9) which is crossed by an electrical contact 6 engaged inside of the enclosure (1), mounted to slide axially in the flange (2) and which is biased towards the interior of the enclosure by a spring (7), the contact (6) being applied under pressure against a conductive end piece (12 ) itself resting against the end of the heating tube (11) which faces the first closing flange (2), the opposite end of the heating tube (11) being engaged in a housing (3a) provided in the second closing flange (3) carrying the outlet nozzle (21). 18. Apparatus according to any one of claims 1 to 17, characterized in that the end of the heating tube (11) which faces the first closing flange (2), is connected to an electrical supply terminal ( 43) carried by the first closing flange (2), via a braid (44), and a thermocouple (45), or another tube for heating any fluid can be introduced inside the heating tube (11), through the first closing flange (2). 19. Apparatus according to any one of the preceding claims, characterized in that the first closing flange (2) is in thermal contact with a chamber (25a) or a tube (25) traversed by cooling water. 20. Apparatus according to any one of claims 1 to 19, characterized in that the first closing flange (2) is in thermal contact with a radiator (37) to ensure its cooling by air. 21. Apparatus according to any one of the preceding claims, characterized in that the means for preheating the gas consist of a coil (17) surrounding the tubular enclosure (1) and in thermal contact therewith. 22. Apparatus according to any one of claims 1 to 21 characterized in that the gas preheating means consist of a cylindrical chamber (17a) surrounding the heat exchanger (14, 15). 23. Apparatus according to any one of claims 1 to 22, characterized in that the gas preheating means consist of a thread (17b) machined in the external surface of the tubular enclosure (1). 24. Apparatus according to one of the preceding claims, characterized in that the heating tube (111) is held in position by a centralizer (124) having openings (110) allowing gas to be introduced into the preheating means (102, 104, 106, 108) in the heating tube (111) by one of its ends. 25. Apparatus according to claim 24, characterized in that the centralizer (124) also carries an electrical contact (126) movable in translation, so as to follow the longitudinal expansions of the heating tube (111). 26. Apparatus according to claim 25, characterized in that the movable electrical contact (126) is connected by a flexible wire (130) to a fixed electrical contact (133) integral with the envelope part (136) but electrically insulated therefrom this.

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