DE102009032260A1 - Infrared-radiation arrangement for infrared-radiation device, particularly for low-temperature infrared cabin, comprises support element and electrically supplied heater that are made of bundles of carbon fibers at holding element - Google Patents

Abstract

The infrared-radiation arrangement (1) comprises a support element and an electrically supplied heater (5) that are made of bundles of carbon fibers at a holding element (3) and are provided with electrical connecting elements (7) either individually or in groups of two heaters. A carrier element has the flexible holding element, which is made up of electrically insulated plastic material. An independent claim is also included for an infrared-radiation device.

Description

The The invention relates to an infrared radiator arrangement for an infrared irradiation device and in particular for a low temperature infrared cabin.

Infrared radiator arrangements for infrared irradiation devices find in heat applications Use that is done with the aim of localizing a body region (eg neck, back, joint, paranasal sinuses etc.) of the human body. One Another important area of application is so-called whole body warming or systemic heating, at which the core body temperature of the human body is specifically increased. The heating process takes place by absorption of Infrared radiation through the human skin and through transport of blood heated through the skin into the body. Heat applications, for example with the help of infrared heat cabins serve to increase the well-being and alleviate many, especially chronic complaints of the human musculoskeletal system. Through heat applications, blood circulation, tissue care and metabolism stimulated as well as pain relief and muscle relaxation reached. For heat applications using infrared radiation In particular, so-called infrared C-rays are suitable since these only a little penetrate deep into the skin and thus unwanted Stimuli on metabolically active skin cells are avoided.

When suitable radiation elements for generating infrared radiation for the above applications are Heizleiteranordnungen known, based on electric current conductive carbon fibers. These are the carbon fiber electrically energized, behave in the process like an electrical resistance and warm up as a result, resulting in a very effective emission of radiation in the infrared wavelength range leads.

In the DE 20 2006 007 228 U1 describes an infrared surface heating element, which is based on an electrically conductive carbon fiber fabric in a high vacuum as a multi-layered "sandwich" for space heating and drying. On the carbon fiber fleece is a special glass, which is coated with a selected nanoceramics to increase the emission efficiency.

In the DE 4 438 870 An infrared radiator is described which consists of one or more elongated drag bodies made of carbon fiber ribbon. The carbon fiber ribbons are located in a capillary cavity of a quartz glass envelope, which is evacuated or filled with gas.

In the DE 4 447 407 For example, a flexible sheet is described as a heat-radiating heating element, wherein the supplied electrical energy is converted into long-wave infrared radiation using fibrous or filamentary carbon modifications. In particular, a flexible layer composite is used, in which a mechanically limited loadable, consisting of electrically conductive fibers fiber web is used with a disordered arrangement of fibers in the form of a carbon fiber fleece to which a further dielectric textile cover layer is applied. The cover layer is needled with the carrier layer.

The DE 20 014 518 U1 describes a heating element in the form of a surface radiator with high heat storage capacity z. B. in the form of a stone or marble slab, which is heated by means of a Heizleiteranordnung. In this case, the heating conductor arrangement comprises a flat carbon fiber strip which, with the interposition of a first electrically insulating plastic film, is fixed in area contact with the radiator on the latter and likewise covered in a planar manner by means of a thermal insulation panel.

Infrared radiator arrangements This type have the disadvantage that the radiation profile generated by them both in terms of spatial distribution and temporal variation can not be changed so flexibly can, as for effective heat applications by infrared radiation is desirable. So is it for optimal effect of the infrared irradiation of the human body desirable that particular Body parts (eg shoulder, hip, spine etc.) each irradiated with different intensity can be. In addition, it may be necessary to increase the irradiation intensity also in the course of an irradiation treatment to change over time.

To the Use for heat applications are the above Infrared emitter assemblies unsuitable because in their use locally spatial and temporal variations of the generated Beam profiles are hardly possible.

It It is therefore an object of the present invention to provide an infrared radiator arrangement, in particular for a low-temperature infrared cabin, to provide at the beam profile of the emitted infrared radiation the application needs, especially in context with a radiation of the human body, better Takes into account.

A low-temperature infrared cabin is to be understood here and below as meaning a cabin in which a thermally neutral ambient temperature of from 28 ° C. to 37 ° C., preferably 30 ° C. to, for an unclothed, stationary person 35 ° C prevails.

to Solution to this problem comprises the inventive Infrared radiator arrangement in a first aspect, a carrier element and at least one held on the carrier element, electrically energizable Heating conductor, wherein the carrier element is a flexible holding element made of electrically insulating plastic material and the at least a heating conductor a bundle of several flexible heating conductors includes. There are several of bundles of carbon fibers formed heating element spaced from each other on the holding element and either individually or in several groups of at least two Heat conductors provided with electrical connection elements.

One significant advantage of the proposed solution in that by providing connection elements for every single heating element or for several predetermined ones Groups the heating conductors electrically individually, d. H. independent from each other are energized. Thus, the infrared radiation profile generated by the heating conductor spatially locally variable with high flexibility. Especially in connection with an infrared irradiation device and with a low-temperature infrared cabin it gets to this Way possible, certain sections of the irradiated human body different irradiation intensities suspend. Furthermore, when using a suitable control device the generated radiation profile with a very high degree Flexibility also meets the requirements of heat treatments be adjusted accordingly.

Prefers the heating conductors are substantially parallel to each other on the flexible Holding element arranged. This simplifies both the manufacture as well as the electrical wiring of the heating conductors by means of the connection elements.

In In a second aspect, the infrared radiator assembly comprises Carrier element and at least one on the support element held, electrically energized heating conductor, wherein the carrier element a flexible holding element of electrically insulating plastic material and the at least one heating conductor is a bundle of several comprises flexible carbon fibers. Here are the at least one or a plurality of heat conductors formed of bundles of carbon fibers arranged on the holding element that portions of or the heating conductor in pairs spaced from each other and essentially parallel to each other and the distances of at least two adjacent section pairs are different.

By the variation of the distance of pairs of mutually extending sections the heating conductor (s) is the beam profile of the one to be emitted Infrared radiation already in the production of the infrared radiator arrangement established. In this way, the at a certain distance to the infrared emitter array located human body also on different parts of the body with different Radiation intensity are irradiated. This is for example on areas of the body with pronounced musculature (eg the side of the spine), which is a strong blood circulation require a particularly high radiance.

Of Another is to heat conductors either individually or in several groups of at least two heating conductors in an edge region the flexible holding element with electrical connection elements to provide. In this way, an individual energization of the Heating conductor possible.

In an advantageous variant comprises the inventive Infrared emitter array a selective means for selective selection the connection elements to be energized. By selective energization single heating element or individual groups of heating conductors is it is possible to use the spatial beam profile of the Heating element generated infrared radiation spatially locally and variable over time. The selection agent can be part of a more complex control mechanism be the electronic circuits and / or a software program includes.

Further Preferably, the at least one heating conductor is on the holding element attached. The attachment is preferably by sticking the Heating conductor on the flexible holding element, in particular by means an adhesive layer.

Farther Preferably, the holding element is a tissue into which the at least a heating element is woven. This variant is particularly suitable then, if a high-precision parallel alignment of the heating conductors to be achieved at precisely defined intervals.

Farther it makes sense, the holding element surface with a mineral sand, especially lava sand, containing the at least one heating conductor covering Mineral sands layer to coat. By the use of lava sand will provide optimal transfer of thermal energy into the inside of the body and an associated continuous one and slow increase in body core temperature ensured.

Furthermore, the holding element is preferably coated areally with a cover layer, in particular a lacquer cover layer or an impregnated lacquer carbon fiber fabric. By the Using a cover layer, the external optical impression of the infrared emitter arrangement according to the invention is improved on a viewer. Preferably, the cover layer is formed so that it is easy to clean, so has a smooth surface structure.

Of Another option is to use the flexible holding element on one side attached curved support element. To this Way, the infrared radiator arrangement becomes practical Applications stiffened sufficiently, with the curved Design of the support element for ergonomic optimization of the infrared radiating element with respect to parts of the body to be irradiated (for example, the upper body) of the human body offering.

In A further preferred embodiment is on the holding element or at a distance from the holding element in the emission direction shielding arranged to shield infrared radiation. In this way can be certain parts of the human body be excluded from the irradiation by means of infrared radiation.

In In a third aspect, the present invention relates to an infrared irradiation apparatus which at least one infrared radiator arrangement according to the invention comprising, wherein the flexible holding element of the at least one infrared radiator arrangement Stiffened in segments by means of at least one support element is. The infrared irradiation device is particularly suitable for irradiation of larger areas of the human Body by means of infrared radiation, as by using the Infrared emitter assembly in conjunction with one or more Support elements a large-area ergonomic Adaptation of the infrared emitter array used to be irradiated Body parts done. But also when used for irradiation smaller areas of the human body can through the infrared radiator arrangement according to the invention an improved ergonomic adaptation of the infrared emitter assembly used be achieved to the body areas to be irradiated.

Prefers are the support elements as running in the horizontal direction Support strips formed. This simplifies things the manufacture and construction of the infrared irradiation device considerably, without the ergonomic adaptation of the infrared emitter assembly used affected by the body parts to be irradiated becomes.

Farther it makes sense that the support elements each Lehnensegmente carry in the distance direction and at a distance from the infrared radiator arrangement define a leaning contour. By means of the backrest segments to be irradiated body parts at a well-defined distance supported to the infrared radiator arrangement.

Prefers is the flexible holding element at least in areas between the stiffening support element by an additional Reinforced layer of flexible plastic. In this way the mechanical stability of the infrared radiator element continues elevated.

there It makes sense that the support elements transversely to the holding element are elastically deflectable attached to a bracket. To this Way, the ergonomics of the device can be further improved become.

In a fourth aspect, which also explained in previous Embodiments can be used, the present invention relates Invention an infrared irradiation device with at least one Infrared radiator arrangement, wherein the infrared irradiation device for attachment to a support structure further comprises a plurality of has elongated retaining plates, the longitudinal side side by side, in particular parallel to each other, are arranged. In this case, at least one infrared radiator arrangement extends over at least two adjacent holding plates across and away attached to the holding plates for segmental stiffening; Furthermore are on the holding plates backrest segments mounted in such a way that they define a Anlehnkontur on both sides of the infrared radiator arrangement.

The Use of multiple retaining plates allows a modular Structure of the infrared irradiation device. In particular, the Holding plates of the infrared irradiation device according to the invention attached to a common support structure while the flexible holding element of the infrared radiator arrangement indirectly mediate the holding plates is attached to the support structure. The geometric Arrangement of the holding plates can be made such that these already optimized in terms of their ergonomic orientation. Due to the use of a flexible retaining element, the infrared radiator arrangement easily different geometric arrangements of the holding plates be adjusted.

Prefers the backrest segments are arranged such that the defined by them Lean contour the radiation range of the infrared radiator arrangement partially covered. In this way, the backrest segments act automatically as a touch guard that can prevent that a user of the infrared irradiation device accidentally comes into contact with the infrared radiator arrangement.

Furthermore, it makes sense that at least a part of the holding plates is in each case provided with a contact protection element encompassing the infrared radiator arrangement. As contact protection elements in particular lattice bars offer. The contact protection elements can be fastened to the retaining plate, for example, on both sides of the infrared radiator arrangement. Alternatively, it is also conceivable that the contact protection elements are attached to adjacent backrest segments which are mounted on both sides of the infrared radiator arrangement on the holding plate. Even by means of the contact protection elements prevents a user of the infrared irradiation device is inadvertently in contact with the infrared radiator arrangement.

In In a preferred embodiment, the retaining plates elastically deflectable attached to the support structure. In this way can the position of the backrest segments mounted on the support plates optimal to the parts of the human body to be irradiated be adjusted.

The Invention will be described below with reference to preferred embodiments with reference to the attached figures closer explained.

1 shows a first embodiment of an infrared radiator arrangement according to the invention.

2 shows a second embodiment of an infrared emitter array according to the invention.

3 shows an alternative wiring example according to the invention for the first and second embodiments.

4 shows another alternative wiring example for the first and second embodiments.

5 shows an alternative arrangement of the heating conductors on the holding element of the first and second embodiments in the form of a fabric.

6 shows a side view of a variant of the infrared emitter assembly according to the invention.

7 shows a shielding element of an infrared radiator arrangement according to the invention in the form of a shielding grid.

8th shows a perspective view of an embodiment of an infrared irradiation device according to the invention.

9 shows a side view of the embodiment of 8th ,

10 shows a perspective view of another embodiment of an infrared irradiation device according to the invention.

11 shows a side view of the embodiment of 10 ,

The 1 generally shows one with 1 designated infrared radiator arrangement for an infrared irradiation device. The infrared radiator arrangement 1 includes a flexible retaining element 3 made of electrically insulating plastic material. On the holding element 3 are a plurality of flexible heating conductors 5 arranged parallel to each other. The heating conductors 5 are by means of a layer of flexible resin with substantially identical distance on the flexible support member 3 glued. The electrical connection for energizing the heating element takes place by means of the at a side edge of the flexible holding element 3 attached connection elements 7 in the form of copper flakes, on which the heating conductors 5 by means of an insulating strip 10 be pressed. In each case three adjacent heating conductors with the same connection element 7 connected. In this way, with reduced wiring costs an individual energization of the heating element 5 possible, which leads to the desired inhomogeneous beam profile with respect to the radiated from the infrared radiator array infrared radiation. Such a configuration is suitable, for example, when parts of the back of the human body are to be irradiated with different intensity.

On the connecting elements 7 opposite side of the flexible retaining element 3 is a common ground connection 8th appropriate. The connection elements 7 are electrical and mechanical with a power strip 9 connected. The power strip 9 is with a selection agent 11 connected, which is the selective control of the heating conductor 5 allows for selective energization. The selection agent 11 is part of a control mechanism that includes electronic circuits and / or a software program.

In a variant of the first embodiment, it is possible, the number of existing connection elements depending on the application requirement as desired in relation to the number of existing heating conductors 5 set.

In a further variant of the first embodiment, the ground connection 8th through connection elements 7 replaced.

In another variant may instead of the copper leaflets in conjunction with the insulating strip and crimp sleeves be used.

In another variant, the heating conductors not held by means of resin on the flexible holding element, but "sandwiched" between the holding element of flexible plastic and an additional holding element made of flexible plastic.

In a further variant, instead of a layer of flexible resin, the heating conductors 5 surrounded by flexible plastic and by means of the surrounding flexible plastic on the flexible support member 3 attached.

The 2 shows a second embodiment 1a an infrared radiator arrangement for an infrared irradiation device. The second embodiment differs from the first embodiment by different distances between two pairs of adjacent heating conductors 5a , In 2 is the distance D1 of two arranged in a central region of the holding element adjacent heating conductor 5a greater than the distance D2 of two adjacent heating conductors 5a extending at the edge of the retaining element 3a are arranged. By varying the distances between adjacent heating conductors 5a It is also possible in this embodiment, a spatially inhomogeneous beam profile of the infrared emitter array 1a generate radiated infrared radiation.

The type of beam profile produced is already determined by the arrangement geometry in the production of the infrared radiator arrangement. Also for the infrared radiator arrangement of the second embodiment is a single common connection elements 7a and a ground connection 8a adequate to the electrical wiring of the heating conductors 5a to realize.

In 3 is a variant of the second embodiment 1b shown. In this variant, the heating conductors 5b on the flexible holding element 3b mounted, each heating conductor is guided in such a way that its two ends on the same side of the flexible support member 3b each with a connection element 7b are provided. In this way, the electrical connection of the heating conductors can be completely on one side of the flexible holding element 3b respectively. In this variant, arrangement geometries of the heating conductors with varying spacing (D1 or D2) of adjacent sections relative to one another are realized. But there are also other arrangement geometries, for example, with identical spacing, possible.

4 shows a further variant of the second embodiment of the infrared irradiation device according to the invention 1c , In this variant, the heating conductor 5c meandering on the flexible holding element 3c arranged, wherein the distance between adjacent sections of the heating conductor 5c varied. In this case, the distance D1 between two adjacent sections of the heating conductor 5c in an edge region of the flexible holding element 3c smaller than the distance D2 in a central region of the flexible holding member 3c , By varying the distances between adjacent heating conductors 5c it is also possible in this variant, a spatially inhomogeneous beam profile of the infrared emitter array 1c generate radiated radiation.

In another variant, it is possible, the first and the second embodiment and their variants in terms Number and arrangement geometry of the heating conductors, connection of the heating conductors to connection elements, grouping of the heating conductors to connection elements and to combine distance variation of pairs of adjacent heating conductors.

In 5 is a variant 1d of the first and second embodiments of the infrared radiator arrangement according to the invention, in which the flexible retaining element 3d is formed as a fabric into which a plurality of heating conductors 5d woven in parallel to each other. This variant is particularly suitable if the heating conductors are not to be attached by an adhesive to the flexible holding element.

In a further variant of the first embodiment, the infrared radiator arrangement 1e as in 6 shown in side view on a curved stiffening plate 13 appropriate. As material for the stiffening plate 13 In particular, metallic materials are offered, since by means of this an undesired emission of infrared radiation in the rearward direction is avoided. The geometry of the stiffening plate 13 can be chosen arbitrarily depending on the requirement of the application.

In a further variant of the infrared radiator arrangement, as also in 6 shown, flat with a layer of lava sand 15 coated, which is the heating conductor 5e covering area.

In a further variant, the infrared radiator arrangement is as in 6 shown flat with a paint topcoat 17 coated. Alternatively, the infrared radiator assembly may also be coated with an impregnated carbon fiber fabric. By means of the lacquer top layer 17 becomes the external optical impression of the infrared radiator arrangement 1e improved on a viewer.

In an in 7 variant shown is the infrared radiator arrangement 1f or to a shielding element in the form of a shielding grid 19 supplemented, so that certain radiation ranges emitted by the infrared radiator array radiation through radiopaque surface elements 21 on the screen 19 are shielded.

in the All directions given below refer to the position of use the described device.

The 8th and 9 show an infrared irradiation device according to the invention 100 , which is an infrared radiator arrangement according to the invention 1 includes, in perspective view and side view, wherein the flexible retaining element 3 over a plurality of grid-like arranged support elements 101 extends and stiffened on this. Each support element 101 is elastically deflectable on a support structure 105 appropriate. Furthermore, each support element comprises 101 a spaced backrest segment 103 , Between each two adjacent backrest segments 103 a sufficiently large gap is provided so that infrared radiation can pass through the interspaces to the body parts to be irradiated.

The support elements 101 the infrared irradiation device according to the invention can be aligned so that the backrest segments forming a backrest contour 103 on the parts of the human body to be irradiated (eg the human back). In this way it is achieved that the infrared radiator arrangement 1 is located across the entire area of the human body to be irradiated, at a uniform distance from the body surface. This avoids that the intensity of the incident on the body surface infrared radiation varies by distance. The backrest segments 103 take on a support function for the human body.

The 10 and 11 show a further embodiment of an infrared irradiation device according to the invention 100a , which is particularly suitable for the irradiation of the human spine and its vicinity. In this embodiment, six holding plates 102 line-like with each other and arranged parallel to each other and each secured by means of a plurality of spring elements elastically deflectable to the support structure. The flexible holding element 3 the infrared radiator arrangement 1 extends in a horizontal with respect to the horizontal central region in the vertical direction over all holding plates and is fixed thereto. The flexible holding element 3 the infrared radiator arrangement 1 is by means of an additional layer of flexible plastic 107a strengthened. On each holding plate 102 are four backrest segments 103a appropriate. The width of the infrared radiator arrangement 1 is in proportion to the backrest width of the infrared irradiation device 100a low and is for example 5 cm to 20 cm. In the embodiment, the surface contour 105k the holding structure 105a adapted substantially to the surface contour of the back of the human body. However, other geometries are conceivable. An ergonomic fine adjustment to the human back is made by the elastically deflectable on the support structure 105a attached holding plates 102 , which when leaning the back of the backrest segments 103a be deflected from their rest position. Because the infrared radiator arrangement 1 is mounted on the holding plates, the distance of the infrared radiator arrangement is at the same time when leaning of the human back 1 adapted to the surface of the human back. For use as an infrared radiator arrangement 1 especially offers in the 2 to 4 shown variants.

Either the number of retaining plates as well as the number of backrest segments can be varied in further variants of the embodiment become.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 202006007228 U1 [0004]
• - DE 4438870 [0005]
• - DE 4447407 [0006]
• - DE 20014518 U1 [0007]

Claims (20)

Infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) for an infrared irradiation device, in particular for a low-temperature infrared cabin, comprising a carrier element and at least one electrically energizable heating conductor held on the carrier element ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ), wherein the carrier element is a flexible holding element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) made of electrically insulating plastic material and the at least one heating conductor ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) comprises a bundle of a plurality of flexible carbon fibers, characterized in that a plurality of heating conductors formed from bundles of carbon fibers ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) at a distance from each other on the holding element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) and either individually or in several groups of at least two heating conductors ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) with electrical connection elements ( 7 ; 7a . 7b ; 7c ) are provided. Infrared radiator arrangement according to claim 1, characterized in that the heating conductors ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) substantially parallel to one another on the flexible holding element ( 3 . 3a ; 3b ; 3c ; 3d ; 3e ) are arranged. Infrared radiator arrangement ( 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) for an infrared irradiation device, in particular for a low-temperature infrared cabin, comprising a carrier element and at least one electrically energizable heating conductor held on the carrier element ( 5a ; 5b ; 5c ; 5d ; 5e ; 5f ), wherein the carrier element is a flexible holding element ( 3a ; 3b ; 3c ; 3d ; 3e ) made of electrically insulating plastic material and the at least one heating conductor ( 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) comprises a bundle of a plurality of flexible carbon fibers, characterized in that the at least one or more heating conductors formed from bundles of carbon fibers ( 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) in the manner of the retaining element ( 3a ; 3b ; 3c ; 3d ; 3e ) are arranged that portions of the or the heating conductor ( 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) in pairs at a distance from each other and substantially parallel to each other and the distances of at least two adjacent pairs of sections are different. Infrared radiator arrangement ( 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) according to claim 3, characterized in that the heating conductors ( 5a ) either individually or in several groups of at least two heating conductors ( 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) in at least one edge region of the flexible holding element ( 3a ; 3b ; 3c ; 3d ; 3e ) with electrical connection elements ( 7a ; 7b ; 7c ) are provided. Infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) according to any one of the preceding claims, further comprising a selection agent ( 11 ) for the selective selection of the connection elements to be energized ( 7 ; 7a ; 7b ; 7c ). Infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) according to one of the preceding claims, characterized in that the at least one heating conductor ( 5 ; 5a ; 5b ; 5c ; 5d ; 5e ; 5f ) is mounted on the holding element. Infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) according to one of claims 1 to 6, characterized in that the retaining element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ; 3f ) is a fabric, in which the at least one heat conductor is woven. Infrared radiator arrangement ( 1 ; 1a ; 1b . 1c ; 1d ; 1e ; 1f ) according to one of the preceding claims, characterized in that the retaining element ( 3 ; 3a ; 3b . 3c ; 3d ; 3e ; 3f ) surface with a mineral sand, in particular lava sand containing the at least one heating conductor covering mineral sands layer ( 15 ) is coated. Infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) according to one of the preceding claims, characterized in that the retaining element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) surface with a cover layer, in particular a lacquer cover layer ( 17 ) or an impregnated lacquer carbon fiber fabric is coated. Infrared radiator arrangement according to one of the preceding claims, characterized in that the retaining element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) on a curved support element ( 13 ) is attached. Infrared radiator arrangement according to one of the preceding claims, characterized in that on the retaining element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) or at a distance from the retaining element ( 3 ; 3a ; 3b ; 3c ; 3d ; 3e ) in the radiation direction shielding elements ( 19 ) are arranged to shield infrared radiation. Infrared radiation device, comprising at least one infrared radiator arrangement ( 1 ; 1a ; 1b ; 1c . 1d ; 1e ; 1f ) according to one of the preceding claims, wherein the flexible retaining element ( 3 ; 3a ; 3b ; 3c . 3d ; 3e ) of the at least one infrared radiator arrangement ( 1 . 1a ; 1b ; 1c ; 1d ; 1e ; 1f ) is stiffened in segments by means of at least one support element. Infrared irradiation device ( 100 ) according to claim 12, characterized in that the support elements each Lehnensegmente ( 103 ), which define a contact contour in the distance direction and at a distance from the infrared radiator arrangement. Infrared irradiation device ( 100 ) according to claim 12 or 13, characterized in that the flexible holding element ( 3a ; 3b ; 3c ; 3d ; 3e ) at least in areas between the stiffening support element by an additional layer of flexible plastic ( 107 ) is reinforced. Infrared irradiation device ( 100 ) according to one of claims 12 to 14, characterized in that the support elements transversely to the retaining element elastic ( 3a ; 3b ; 3c ; 3d ; 3e ) deflectable on a holder ( 105 ) are attached. Infrared irradiation device ( 100 ) according to one of claims 12 to 15, characterized in that the support elements for attachment to a support structure ( 105a ) a plurality of elongated retaining plates ( 102 ), which are arranged alongside one another, in particular parallel to one another, along the longitudinal side; wherein the at least one infrared radiator arrangement ( 1 ) via at least two adjacent holding plates ( 102 ) extends transversely across and on the holding plates ( 102 ) is mounted for segmental stiffening; and wherein on the holding plates ( 102 ) Backrest segments ( 103a ) are mounted in such a way that they are located on both sides of the infrared radiator arrangement ( 1 ) define a leaning contour. Infrared irradiation device with at least one infrared radiator arrangement according to one of claims 1 to 11, characterized in that the infrared irradiation device ( 1 ) for attachment to a support structure ( 105a ) Further, a plurality of elongated retaining plates ( 102 ), which are arranged alongside one another, in particular parallel to one another, along the longitudinal side; wherein the at least one infrared radiator arrangement ( 1 ) via at least two adjacent holding plates ( 102 ) extends transversely across and on the holding plates ( 102 ) is mounted for segmental stiffening; and wherein on the holding plates ( 102 ) Backrest segments ( 103a ) are mounted in such a way that they are located on both sides of the infrared radiator arrangement ( 1 ) define a leaning contour. Infrared irradiation device according to claim 16 or 17, characterized in that the backrest segments ( 103a ) are arranged such that the support contour defined by them the radiation range of the infrared radiator arrangement ( 1 ) partially covered. Infrared irradiation device according to one of claims 16 to 18, characterized in that at least a part of the retaining plates ( 102 ) each with a the infrared radiator arrangement ( 1 ) comprehensive contact protection element ( 110a ) is provided. An infrared irradiation device according to any one of claims 16 to 19, further comprising a support structure ( 105a ), wherein the retaining plates ( 102 ) elastically deflectable on the support structure ( 105a ) are attached.

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