EP1511360A2 - Infrared radiator, its use and a manufacturing method - Google Patents

Abstract

The invention relates to an infrared radiator with an elongated, gas-tight cladding tube made of quartz glass and disposed in the cladding heating element made of carbon, wherein the heating element is electrically connected to at least two electrical contacts outside the cladding tube and wherein the heating conductor by at least one spacer spaced from the cladding tube and in is arranged centered, and is characterized in that the heating conductor is formed as an elongated band, that the at least one spacer is formed as a disc, wherein the disc has an opening for the passage of the heat conductor, wherein the disc has the open cross section between the heating conductor and at least partially fills the cladding tube, and wherein the disc of carbon fiber reinforced carbon (CFC) is formed.

Description

The invention relates to an infrared radiator with an elongated, gas-tight cladding tube Quartz glass and arranged in the cladding heating element made of carbon, wherein the heating conductor electrically connected to at least two electrical contacts outside the cladding tube and wherein the heating conductor by at least one spacer made of carbon spaced from the cladding tube and centered therein, the heating conductor being elongated Band is formed. The invention further relates to the use of such Infrared radiator and a method for its production.

Infrared radiators of the type mentioned are known from US 6,057,532. Here is one Infrared radiation source with a carbon fiber-containing, band-shaped heating element disclosed. The heating element is in a cladding tube made of quartz glass by means of spacers Carbon fiber centered and spaced from the wall of the cladding tube. As a spacer On the one hand, a yoke is used, which on nubs, which on the inner wall of the cladding tube are molded, is fixed. The preparation of the yoke itself and the molding of the Nubs on the inner wall of the cladding tube is very expensive and therefore expensive. on the other hand spacers are used in the form of a splint, which by the band-shaped heating element inserted and fixed again in the cladding tube by means of knobs. Such an embodiment leads in the shortest possible time to failure of the heating element, after in the field of Cotter the band is destroyed.

It is an object of the invention to provide an infrared radiator with a heating element made of carbon to provide more suitable spacers between the heating conductor and a cladding tube made of quartz glass, and to provide an optimized method for its production.

The object is achieved in that the at least one spacer is formed as a disc, wherein the disc has an opening for the passage of the heating element, wherein the disc at least partially fills the open cross section between the heating conductor and the cladding tube.
Such spacers are easy to manufacture and mount in the cladding tube. A perforation of the heating element itself is not required and a structuring of the inner wall of the cladding tube before introducing the spacer in the pipe cross section is no longer required.

Preferably, the disc is formed of carbon fiber reinforced carbon (CFC).

It has proven useful if the opening comprises part of the circumference of the disc. By Such a configuration of the spacer, the heating element laterally into the spacer pushed in and thus mounted even faster.

But it is equally possible that the opening spaced from the periphery of the disc is. In this embodiment, however, the heating element has to be threaded through the pane be, which means a higher installation time.

It has proven useful if the disc has a thickness in the range of 0.5 to 5 mm.

The heating conductor material used is graphite, graphite foil or carbonized, graphitized CFC material preferred for use.

It has proven useful if the heating element is glued in the opening, allowing a hiking of the Heating conductor is prevented in the disc. After bonding of heating conductor and disc takes place a heating of volatiles from the adhesive used.

It is advantageous for the life of the infrared radiator when the cladding tube with an inert Gas or gas mixture is filled or evacuated.

In particular, it has proven useful if the cladding tube is an oval perpendicular to its longitudinal axis Cross section has. As a result, a twisting of the heat conductor in the cladding tube automatically prevented and a separate fixation of the disc in the cladding tube as Verdrehschutz is not required.

If a cladding tube is used which is perpendicular to its longitudinal axis a circular cross-section has, it is advantageous if in the region of at least one spacer the cladding tube is deformed. A change in the wall thickness of the cladding tube is thereby substantially not generated.

A use of the infrared radiator according to the invention at Heizleitertemperaturen in the field from 900 to 2200 ° C is ideal.

The object is achieved for the method in that an infrared radiator, which has a cladding tube with a circular cross-section, is made such that the heating element is pushed together with the at least one spacer in the cladding tube and then the cladding tube is deformed by the cladding tube in Temperature is applied to the region of the at least one spacer and the heated cladding tube is deformed such that the at least one spacer fills the open cross section between the heating conductor and the cladding tube.
Such a method is simple, fast and inexpensive to perform, with a weakening of the cladding does not occur.
Only an exposure of the cladding tube with temperature leads to a collapse of the cladding tube inner diameter and an adaptation to the at least one spacer. In addition to exposure to the cladding tube with temperature, however, the heated quartz glass can also be deformed via possibly heated dies.

Figur 1a

einen Abstandshalter, der als Scheibe aus kohlefaserverstärkten Kohlenstoff gebildet ist,

Figur 1 b

den Abstandshalter aus Figur 1a in der Seitenansicht inklusive eines hindurch geführten Heizleiters,

Figur 2a

einen weiteren Abstandshalter aus kohlefaserverstärkten Kohlenstoff,

Figur 2b

den Abstandshalter aus Figur 2a in der Seitenansicht, wobei ein Heizleiter hindurchgeführt ist,

Figur 3

den Querschnitt durch einen Infrarotstrahler mit Zwillingshüllrohr und Abstandshaltern gemäß Figuren 2a bis 2b,

Figur 4a

einen Infrarotstrahler mit einem Hüllrohr, welches einen kreisförmigen Querschnitt aufweist im Längsschnitt,

Figur 4b

den Infrarotstrahler aus Figur 4a in einem weiteren Längsschnitt,

Figur 5

einen Querschnitt durch einen Infrarotstrahler mit verformtem Hüllrohr.

FIGS. 1a to 2b show suitable spacers for the infrared radiator according to the invention, FIGS. 3 to 5 show the infrared radiator according to the invention itself.
It shows:

FIG. 1a

a spacer formed as a disc of carbon fiber reinforced carbon,

Figure 1 b

the spacer of Figure 1a in the side view including a guided therethrough,

FIG. 2a

another carbon fiber reinforced carbon spacer,

FIG. 2b

the spacer of Figure 2a in the side view, wherein a heating conductor is passed,

FIG. 3

the cross section through an infrared radiator with twin cladding tube and spacers according to Figures 2a to 2b,

FIG. 4a

an infrared radiator with a cladding tube, which has a circular cross-section in longitudinal section,

FIG. 4b

the infrared radiator of Figure 4a in a further longitudinal section,

FIG. 5

a cross section through an infrared radiator with deformed cladding.

Figure 1a shows a spacer 1, which is formed as a disc, wherein the disc has an opening 2 for carrying out a heat conductor. The disc is made of carbon fiber reinforced Carbon (CFC) is formed.

FIG. 1b shows the spacer 1 from FIG. 1a in a side view. It is through the opening 2, visible in Figure 1a, a heating element 3 out.

Figure 2a time a further spacer 1 made of carbon fiber reinforced carbon (CFC), at the opening 2 is a part of the circumference of the disc designed as a spacer. 1 includes.

Figure 2b shows the spacer 1 of Figure 2a in the side view, wherein in the opening of the second a heating conductor 3 is arranged.

FIG. 3 shows the cross section through an infrared radiator with a cladding tube 4 serving as a twin tube is designed with oval cross-section and consists of quartz glass. In the two channels of the Hüllrohres each a heat conductor 3 is arranged, which by disk-shaped spacers 1 is centered and held. The heating element 3 are located in the openings 2 of the spacers 1.

Figure 4a shows a longitudinal section through an infrared radiator with a cladding tube 4, which has a circular cross-section. In the cladding tube 4, a heating element 3 is arranged, the is centered and held by spacers 1 in the cladding tube 4. The ends of the cladding tube 4 are sealed gas-tight and have current feedthroughs 5a, 5b. The heating element 3 is over tensioned a tension spring 6, so that prevents heating of a sagging of the heating element becomes.

FIG. 4b shows the infrared radiator from FIG. 4a in a further longitudinal section, which is rotated 90 ° is made to represent in Figure 4a.

Figure 5 shows a cross section through an infrared radiator with a cladding tube 4, which has a having circular cross-section. In the cladding tube 4, a heating element 3 is arranged, which by spacers 1 is centered and held in the cladding tube 4. In this case, the heating element 3 through an opening 2 out in the spacer 1. The spacer 1 is designed as a non-circular disk, the velvet heating 3 is introduced into the cladding tube. Only then is the cladding tube 4 in Area of the spacer 1 is heated and deformed, so that a local adjustment of the inner contour of the cladding tube 4 and the spacer 1 in the areas 4a, 4b of the cladding tube 4 is generated. As a result, a rotation of the heating element 3 in the cladding tube 4 is effective prevented and the cladding tube 4 not weakened.

Claims (12)

Infrared radiator with an elongated, gas-tight cladding tube made of quartz glass and arranged in the cladding heating element made of carbon, wherein the heating element is electrically connected to at least two electrical contacts outside the cladding tube and wherein the heating conductor by at least one spacer made of carbon spaced from the cladding tube and centered therein is arranged, wherein the heating conductor is formed as an elongated band, characterized in that the at least one spacer (1) is formed as a disc, wherein the disc has an opening (2) for passage of the heating conductor (3), wherein the disc is the open Cross-section between the heating conductor (3) and the cladding tube (4) at least partially fills. Infrared radiator according to claim 1, characterized in that the disc of carbon fiber reinforced carbon (CFC) is formed. Infrared radiator according to one of claims 1 to 2, characterized in that the opening (2) comprises a part of the circumference of the disc. Infrared radiator according to one of claims 1 to 2, characterized in that the opening (2) spaced from the circumference of the disc is arranged. Infrared radiator according to one of claims 1 to 4, characterized in that the disc has a thickness in the range of 0.5 to 5 mm. Infrared radiator according to one of claims 1 to 5, characterized in that the heating conductor (3) made of graphite, graphite foil, or carbonized, graphitized CFC material is formed. Infrared radiator according to one of claims 1 to 6, characterized in that the heating conductor (3) is glued in the opening (2). Infrared radiator according to one of claims 1 to 7, characterized in that the cladding tube (4) is filled with an inert gas or gas mixture or is evacuated. Infrared radiator according to one of claims 1 to 8, characterized in that the cladding tube (4) perpendicular to its longitudinal axis has an oval cross-section. Infrared radiator according to one of claims 1 to 9, characterized in that the cladding tube (4) perpendicular to its longitudinal axis has a circular cross-section, wherein the cladding tube (4) in the region of the at least one spacer (1) is deformed. Use of an infrared radiator according to one of claims 1 to 10 at Heizleiterertemperaturen in the range of 900 to 2200 ° C. Method for producing an infrared radiator according to claim 10, characterized in that the heating conductor (3) is pushed together with the at least one spacer (1) in the cladding tube (4) and that the cladding tube (4) is subsequently deformed by the cladding tube ( 4) in the region of the at least one spacer (1) is subjected to temperature until the at least one spacer (1) fills the open cross section between the heating conductor (3) and the cladding tube (4).

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