EP0585831A2 - Heater, especially for kitchen appliances - Google Patents

Abstract

Heating and/or bias resistors (10) are curved into an undulating shape from flat strip and are pressed into the base (7) of insulation (3) such that they are in consequence secured only against lifting off from the base (7), namely by friction. The respective resistor (10) has edge surfaces (14,15) which are continuous without any interruptions and without any steps. In consequence, an area-specific high power density can be achieved with a very simple construction. <IMAGE>

Description

The invention relates to a heater or radiator, in particular for kitchen appliances, as e.g. can be used as a radiant heater or other radiator for heating a hotplate, an oven muffle or other. Such radiators usually form a self-contained unit, which as such can then be attached to the corresponding device, e.g. a hob, a muffle wall or the like is to be attached. A heating side of the radiator then forms the correspondingly large-area output for the thermal output of the radiator. Resistors, such as heating resistors, series resistors or similar components, can be provided in a plane which is approximately parallel or set back from the plane of the thermal output.

The respective resistor is expediently assigned insulation which can simultaneously form the only support for mechanically holding one or all of the resistors and expediently has a continuous surface area which is approximately in the order of magnitude of the thermal output, for which purpose a particularly flat or only a few millimeters thick insulation is suitable. The insulation is primarily electrically insulating and can also be thermally insulating, but does not have to be impermeable to visible thermal radiation, for example infrared radiation, at least in the region of the intervention of the respective resistor. At least in these areas, the insulation can also be designed such that as much heat or at least the majority of it is dissipated from the engaging section of the resistor not only in the first phase of commissioning, but also in continuous operation, as from the non-engaging section.

An insulation, e.g. Resisting against lifting is relatively difficult to secure from a slurry poured into the form of mineral fiber, granules, binders or the like. It is then pressed into shape and then dried or hardened, while securing against lateral movements by engaging in depressions or between protrusions of the insulation is less difficult. Fastening elements can be used for securing against lifting, which can be formed in one piece with the resistor in the form of staples, adhesive spots or similar separate components or in the form of angled projections and are both connected to the resistor and engage in the insulation.

In the case of flat resistors in particular, such fastening elements then form resistance-inactive components insofar as they do not contribute to the electrical resistance value, namely rather in the manner of blind branches, the current does not flow through them, or the flow through them is only significantly reduced compared to the sections with maximum flow density. These fasteners increase in the case of certain training the complexity and possibly not negligible the weight of the radiator and are essentially only heated by heat conduction or radiation from the resistive areas of the heating resistor, but not by their own resistance work. Round wire resistance coils, on the other hand, can be embedded tightly enclosed in the insulation with resistance-active fastening sections. This also applies to flat resistors, which are attached to the insulation at least partially lying or completely embedded between insulation layers, for example as a non-inherently stable vapor-deposited layer. Compared to such resistors, flat resistors, whose resistance-active cross-sections are at least partially not parallel to the heating side or heating level, but instead inclined to right-angled, have significant advantages because they require less space even with high resistance power across their longitudinal direction and approximately parallel to the heating level and therefore in higher power density and can be better insulated against leakage currents. Securing against lifting is, however, more difficult and more complex for the reasons mentioned above.

The invention is furthermore based on the object of creating a radiator with which disadvantages of known designs or disadvantages of the type described can be avoided. Preferably, a resistor with flat cross sections in the area or outside of these cross sections should be secured in a simple manner on the insulation, in particular against being lifted off, even if at least parts of the respective flat cross section lie transversely to the heating plane. Furthermore, thermal overloads of the insulation should be avoided and / or as many conductive or metal members as possible that are electrically conductive with the resistor are connected to be involved in the electrical resistance work.

According to the invention, means are provided by means of which the respective resistance is secured against lifting off by the direct engagement connection of a resistance-active area with the insulation. The resistance expediently has at least one elongated longitudinal section with full flat cross sections in the region of this fastening section and / or subsequent to or in the longitudinal distance from this fastening section, which are at least partially transverse to the heating plane.

If the resistor or the fastening section does not have any protruding protruding fastening element on the edge surface facing the core of the insulation or on the other edge surface and engages deeply in the insulation compared to the active cross sections, the respective fastening section or the resistor can be used have only resistance-active cross-sections over its entire one-part longitudinal extent. Furthermore, the overall height of the insulation, of the resistor and of the entire radiator can be reduced, in particular, if the said longitudinal edge surface of essentially all of the longitudinal sections of the resistor lies essentially in a single plane. Or if there are no longitudinal sections of the resistor which are spaced apart and adjoin one another via an arc of curvature and which engage in the insulation at different depths or whose longitudinal directions are at an angle to one another. The central longitudinal axis of all fastening sections or all longitudinal sections can be provided in a single plane, through which the heating plane can be defined.

The heating resistor for securing against lateral movements parallel to the heating plane is also advantageously supported directly over the surface of the insulation, its two side surfaces being able to bear closely against approximately parallel supporting surfaces of the insulation, essentially under all operating conditions, at approximately the same or different heights. In contrast to a support only in the area of a sharp edge of an edge surface and not also at a distance from this edge surface, very good lateral support is achieved as a result. The resistance can also be well secured against movements to the core of the insulation if it is supported on the insulation over at least half of its length or its entire length with the associated edge surface at least in one operating state. Is the respective mounting section spring back z. B. biased in that it engages approximately parallel to the heating plane curved in the insulation, so an additional securing jamming against the insulation takes place by the expanding and / or narrowing spring force.

In a preferred embodiment, the respective fastening section or the entire resistor is formed by a flat wire or a flat strip, the respective longitudinal edge of which is approximately straight in the stretched, that is to say the longest, state and / or the lateral surfaces of which are also free of any projections or openings can. The material thickness of the flat cross section can be well below half a millimeter and, depending on the requirements, can be any integer multiple of a tenth of a millimeter or a hundredth of a millimeter, for example seven hundredths of a millimeter. The material width or height of the flat cross section is expediently several millimeters, in particular less than 10 or 5 mm, and can vary according to the requirements in these areas, each integer multiple of a half and / or a millimeter, for example 3 mm. The greatest depth of engagement of this flat cross-section in the insulation is expediently at least a quarter of the material width or the width between the edge surfaces and at most a fraction more than this width, the depth of penetration being, depending on the requirements, each integer multiple of half a millimeter and / or one millimeter can.

Irrespective of the features described, there is a very advantageous embodiment of the radiator if the insulation is at least partially designed as a light guide and / or on at least one surface as a light exit window within its cross sections and is thus connected to at least one light source. The light source can be in a simple manner the resistor which emits infrared radiation during operation, which is arranged, for example, over a large area or approximately uniformly distributed over the insulation and whose radiation then propagates over a large area within the insulation and also emerges to the heating side. As a result, the entire insulation can be used in whole or in part as a light plate, which can be recognized by the covering, translucent and / or transparent cover plate made of glass ceramic or the like as an indication of the operating state. By partially darkening and / or cross-sectional mixing with an opacifier, the light guide and / or the light exit function can be changed so that certain desired patterns are achieved. No opacifying agent can be provided in light-guiding areas or areas provided for the light exit, but this can be replaced by a translucent admixture, for example quartz powder, or another grain size. The remaining components of the insulation are expediently light colored to white and / or translucent in these areas.

Corresponding components have been added so that the insulation does not tend to sinter or brittle hardening, even under high operating temperatures, but remains elastic or elastic. As a result, the insulation remains reversibly deformable and / or resiliently elastic without tearing and can adapt to its own thermal expansions or to those of the resistor or fastening section.

Fig. 1

einen Ausschnitt eines erfindungsgemäßen Heizkörpers in perspektivischer Ansicht,

Fig. 2

einen Ausschnitt einer weiteren Ausführungsform in vergrößerter Darstellung,

Fig. 3

eine weitere Ausführungsform eines Heizkörpers im Schnitt.

These and further features emerge from the claims and also from the description and the drawings, the individual features being realized individually or in groups in the form of sub-combinations in one embodiment of the invention and in other fields and being advantageous and capable of being protected by themselves Can represent versions for which protection is claimed here. Embodiments of the invention are shown in the drawings and are explained in more detail below. The drawings show:

Fig. 1

a section of a radiator according to the invention in a perspective view,

Fig. 2

a section of another embodiment in an enlarged view,

Fig. 3

another embodiment of a radiator in section.

The radiator 1 has an essentially dimensionally stable, multi-part and cup-shaped base body 2, the cup opening of which is essentially completely thermal Output forms. The largest material volume of the base body 2 forms an essentially two-part or three-part insulation 3 consisting of a supporting body 4 and an insulating body 5. The supporting body 4 has, in particular, electrically insulating properties and forms the essentially flat and / or smooth bowl bottom which is exposed for thermal output . The support body 4 is supported flat on an approximately plate-shaped insulating body 5, which have better thermal insulating properties than the support body 4 and can only rest on this in the edge and / or at least one ring area, so that a large area between the two bodies 4, 5 Gap gap exists. The mechanical strengths, such as compressive, bending, tensile and / or shear strength of the insulating body 5 can be lower than those of the supporting body 4, and both are arranged in a socket 6 made of material of a higher strength, for example in a sheet metal shell, which the insulation 3 secures axially and / or radially essentially without play.

Axially beyond the bottom 7 of the insulation 3 is a ring-shaped continuous edge 8 which forms the cup opening and is made of insulating material which, according to FIG. 1, is formed in one piece with the supporting body 4 and consists of an insulating material which corresponds to that of the supporting body 4 and / or the insulating body 5 is similar. This edge 8, the radial thickness of which is greater than the thickness of the supporting body 4, is closely surrounded by a jacket-shaped edge 9 of the holder 6, which here projects axially beyond the free end face of the edge 8, but does not lie directly against the cover plate in the installed state, e.g. by an insulating ring placed on the edge 8, which protrudes over the edge 9.

On the ground. 7, several elongated strand-shaped resistors 10 are fastened so that they are parallel to movements against Floor 7 or to their longitudinal direction or against lifting movements transversely from the floor 7 are secured substantially free of play. The resistors 10, which are provided here at least partially as heating resistors lying freely within the cup space, can be arranged approximately parallel to the edge 8 in single or multiple spiral windings or spirals which are located one inside the other. The resistors 10 are preferably distributed substantially uniformly over a field which approximately adjoins the inner circumference of the edge 8 over the entire circumference and extends to the center of the base 7.

Each resistor 10 has exactly the same, approximately rectangular, flat cross-sections throughout its entire length in that it is made from a flat strip that is not processed in a cutting manner or with the removal of material parts in order to produce the heating resistor.

Rather, the flat strip is only deformed in a bending manner. It has two side surfaces 12, 13 which are parallel in cross-section and two very narrow edge surfaces 14, 15 connecting them, its thickness 29, for. B. about 0.07 mm and its largest cross-sectional width or width 28 z. B. can be about 3 mm. The respective band end of the resistor 10 can be formed directly and without additional intermediate members as an electrical connection end 16 and can be brought into a position by bending or interleaving with the rest of the resistor 10, in which it is contact-free with respect to the insulation 3 and is particularly suitable for the electrical connection well suited.

A one-piece, continuous flat strip can also form two mutually adjacent, separately switchable resistors, if these at one end merge into one another via a cross section and / or these individual resistors connecting cross section is integrally formed with a corresponding connection end.

The respective resistor 10 forms a fastening section 17 which is continuous over most of its length or its entire length by virtue of the fact that it is continuously in engagement with the support body 4 over this length in such a way that it is secured against movement in the directions mentioned is. For this purpose, an engagement section 18 adjoining an edge surface 14 in the form of a strip is continuously embedded in a corresponding groove-shaped depression 19 of the supporting body 4. The flat cross section 11 continuously forms resistance-active cross sections between the two edge surfaces 14, 15, which is why the engagement section 18 is also resistant to the same extent as the sections of the flat cross section 11 projecting freely above the bottom 7.

The depth of engagement of the engaging portion 18 may e.g. about 2 mm or two thirds of the total width of the flat band. The two side surfaces 12, 13 can rest in the area of the respective common longitudinal section at different heights on the insulating material of the support body 4 or at the same height, depending on which radiation conditions or coupling effects are to be achieved. Depending on whether the respective spiral section is elastically prestressed in an area by widening or narrowing, it rests under spring tension with the inner or outer side surface 13 or 12.

The resistors 10 are located on the heating side 20 of the base 7 or the base body 2 facing the cup opening and, for example, with their edge surfaces 15 closer to the thermal output, determine a heating plane approximately parallel to the base 7 21. The radiator 1 has a central axis 22, which is perpendicular to this heating plane 21 and about which the resistors 10 are curved. In addition to its large elastic curvature, each resistor 10 has a course which changes in its longitudinal direction, for example a sinusoidal curve, in that, in view of the heating plane 21, it is alternately provided with opposite, but essentially the same curvatures 23 and adjacent curvatures with their approximately straight or planar legs 24 merge into one piece.

Correspondingly, the engagement section 18 and the groove-shaped recess 19 are curved permanently or intrinsically stiff, the legs 24 diverge from the respective curvature 23, expediently at an angle of more than 30 °, 60 ° or 90 °. As a result, thermal elongations of the resistor are transmitted to the supporting body 4 in a relatively unproblematic manner, namely mainly in the longitudinal direction of the depression 19. The fastening section can also be biased in the longitudinal direction by stretching and / or compressing the corrugation or the resistance 10 in individual partial or all longitudinal sections, so that it resiliently rests with tension on corresponding transverse flanks of one or both side surfaces of the recess 19. The two legs 24 of a wave arc can each form a correspondingly narrowed or widened pretensioned clamp, which rests with the prestress on the associated side surface of the recess 19. At least in the area of these side surfaces, the support body 4 is resiliently resilient under these tensioning forces, so that there is a very secure clawing of the resistor 10. In contrast, the compressive strength of the material of the resistor 10 is significantly higher.

The inner circumference 27 of the edge 8, which according to FIG. 3 can also form a component separate from the supporting body 4, practically limits the thermal output of the heating element 1 on the outer circumference. According to FIG. 3, the free end face 25 of the edge 8 projects a small amount beyond the end face of the edge 9, so that a radiation-permeable cover plate 26 made of glass ceramic or the like is prestressed with its flat back or underside under pressure on this end face 25 can concern. The measure of leadership, e.g. about the sheet thickness of the socket 6 can be so great that there is only a gap distance between the back of the cover plate 26 and the edge 9. If the end face 25 diverts to the heating plane 21 under the pressure or due to the aging of the edge 8, the edge 9 cannot come into direct contact with the cover plate 26, but the gap distance can at most be reduced to a minimum of e.g. Reduce 1 mm or the like.

The heating plane 21 is set back at a distance from the end face 25 or the cover plate 26. However, the respective heating resistor or separate heating resistors can protrude freely to different degrees from the bottom 7 to the heating side 20, engage in the support body 4 at different depths, have different bandwidths and / or different strip thicknesses, as a result of which areas of the heating field with different power density or different sensitivity the heating effect and the glowing can be created.

The corrugated resistance can be pressed into the dry prefabricated or still moist-formable support body 4 without prior production of the recess 19. When pressed into the supporting body 4, the insulating material diverts in a compressive manner, after which it springs back or flows back against the engagement section 18, so that the resistor 10 then prevents it from being lifted off from the floor 7 is secured very positively. The resistance 10 can be pressed in until its edge surface 14 or the fastening projections on the insulating body 5 and / or until the edge surface 14 stops on the support body 4.

All described configurations, components, units or rooms can only be provided once or in a plurality of two or more, e.g. to be able to switch several heating fields and / or heating circuits in different power levels.

Claims (10)

Heater (1), in particular for kitchen appliances, characterized in that, in an operating state, it is composed of at least one base body (2) and a plurality of structural segments or components (10, 17, 18), at least two of which at least partially in one assembled assembly state of the heater (1) separated from each other and / or connected to each other to form an assembly. Heater (1), preferably with a heating field (20) provided on at least one base body (2), at least one counter surface (19) provided in the area of the heating field (20) and a plurality of, an assembled operating state, an unassembled assembly state and in each case components (10, 17, 18) defining a length extension with components (10, 17, 18), namely at least one structure (10), a support device (17) and at least one support leg (18) and alternately in succession by at least one of the Components (10, 17, 18) formed first and second longitudinal sections, wherein at least one of the components (10, 17, 18) on both sides of the middle leg planes in a flat-shaped area facing away from each other larger side surfaces (12, 13) and an edge boundary with side edge surfaces adjoining side edge planes and with one in the operating state on The end of a leg longitudinal direction determining and transverse to the length extension lying linear longitudinal extension, essentially outermost apex end (14), wherein at least one of the components (10, 17, 18) operational sectional configurations, in at least one longitudinal section parallel to the leg longitudinal direction and at least in a cross section transverse to the longitudinal direction of the leg and in at least one of these sectional configurations between the side surfaces (12, 13) determines a material thickness (29), wherein at least one of the side surfaces (12, 13) also has a support flank (12, 13) r supports at least one of the components (10, 17, 18) against at least one counter surface (19) in a support zone which is at least at a distance from the edge boundary (14) corresponding to the material thickness (29), and at least one of the components (10, 17, 18) is made from a starting material which has starting cross-sections, an starting thickness and an starting length which differs substantially from the length, in particular according to claim 1, characterized in that in the assembled state at least one supporting flank (12, 13) o. At least one prefabricated profile or the like is assigned, which lies at least partially along the longitudinal direction of the leg between the edge planes and forms profile sections or the like, and in particular in at least one of the sectional configurations at least one Profile section is approximately between the edge planes transverse to at least one of the leg planes. Heater according to Claim 1 or 2, characterized in that at least one of the components (10, 17, 80) has an edge surface (14, 15) which is resistant to resistance and which is at least partially directly secured, essentially at least over an elongated, uncoiled section (17) engages in the insulation (3) or lies approximately in a single plane, that in particular this fastening section (17) belonging to the supporting device is arranged approximately over its entire cross-sectional height relative to the heating plane (21) and that this fastening section (17) is preferably between its Has edge surfaces (14, 15) or essentially continuous or flat full cross sections (11) over its length and / or that at least one of the components (10, 17, 18) has essentially inherently rigid cross sections transverse to the heating plane (21) and / or is attached as a prefabricated strand to an insulation (3) that in particular mi at least one of the components (20, 17, 18) forms two approximately parallel edge surfaces (14, 15) on the outermost sides of its cross section facing away from one another, and that the edge surface (14) associated with the support device (17) preferably passes continuously over its length, essentially without a step or at least one support device (17) is essentially free of resistance-inactive fastening members and / or that at least one of the components (10, 17, 18) is closely fitting with at least one side surface (12, 13) at a distance from the associated edge surface (14) supported on the counter surface (19), that in particular at least one fastening section (17) to approximately to this edge surface (14) with both side surfaces (12, 13) on the counter surface (19) is substantially full-surface and that preferably at least one side surface (12, 13) in cross-section across its height is essentially continuously continuous or almost rectilinearly gradation-free is. Heater according to one of the preceding claims, characterized in that at least one of the components (10, 17, 18) extends in alternating directions when viewed on an edge surface (14, 15) or on the heating plane (21), in particular that at least one of the Components (10, 17, 18) is curved in a meandering or wave-like manner and that preferably at least one of the components (10, 17, 18) has approximately sinusoidal longitudinal sections or divergent curvature legs (24) and / or that at least one of the components ( 10, 17, 18) or essentially an entire resistor (10) is formed from a one-piece rectilinearly stretchable flat material, such as a flat strip or flat strip, that in particular at least one of the components (10, 17, 18) has a greatest material thickness in the Order of a tenth of a millimeter or the flat cross-section (11) has a greatest material width (28) in the order of 30 to 50 times the material thickness (29) st and that preferably at least one of the components (10, 17, 18) engages in an insulation (3) over a height which is at least in the order of 20 to 30 times the material thickness (29). Heater according to one of the preceding claims, characterized in that at least one of the components (10, 17, 18) extends substantially over a length which is stretched between one tenth of its straight line without tension Operating length and its entire operating length, engages approximately uniformly in the base body (2) and forms fastening sections (17), which has a smaller cross-sectional height than its length, that in particular at least one of the components (10, 17, 18) essentially exclusively by frictional engagement on at least one side surface (12, 13) is secured against lifting transversely to the heating plane (21) and that preferably at least one of the components (10, 17, 18) in its cross sections perpendicular to the heating plane (21) is free of bends and / or openings . Heater according to one of the preceding claims, characterized in that it is a radiant heater (11) and in that at least one resistor (10) is a radiant heating resistor or a series resistor for a heating resistor or the like, such as for a bright radiator, that in particular an insulation (3) at least in the engagement area of the respective component (10, 17, 18) is at least partially unfiltered for its visible heating radiation, and that preferably in an area of at least one resistance-active component (10, 17, 18) of opacifiers in the essentially free insulation (3) contains a radiation-permeable grain or quartz which is resistant to the operating temperatures of the support device (17) and / or that insulation (3) at least in the engagement area of the respective component (10, 17, 18) in the direction of thermal expansion-related Changes in shape of the component are essentially compliant, especially in a temperature-neutral manner re resiliently elastic or unsinterable under the operating conditions, preferably at least one of the components (10, 17, 18) as a mold for producing at least one closely matched to it Receiving recess (19) is formed in an insulation (3) or the like, in particular a receiving recess (19) is limited in one piece to the bottom surface or the side surfaces, the recess (19) essentially over the entire length of at least one of the components ( 10, 17, 18) passes through in a groove-like manner and / or at least one resistor (10) forms at least one resistance-active fastening section (17) which directly engages in the insulation (3) with resistance-active cross sections to prevent it from being lifted off an insulation (3). Heater according to one of the preceding claims, characterized in that at least one profiling means for changing the strength, such as for increasing the stiffness, at least one of the components (10, 17, 18) against pressure loads parallel to the longitudinal direction of the legs, supporting flanks (12, 13) for at a distance from the end apex (14) or from the edge limitation, large-area support of the support device (17), a guide profile for non-positive engagement and for displaceably guiding at least one of the components (10, 17, 18) on at least one counter surface (19), one Deviating from the initial cross-section, a prefabricated sectional configuration, a curved profile formed by permanent and non-resilient deformation of the starting material, a resiliently stretchable compensation profile for stresses, a material thickness (29) essentially the same as the initial thickness over most of its extent, a thermal coupling test Ofil, stiffening of at least one of the components (10, 17, 18), continuation of a profile deformation of essentially the entire initial cross section of at least one of the components (10, 17, 18), forms an electrically resistive section of at least one component (10, 17, 18) or the like, that in particular at least one profiling in the installed state is connected to at least one of the components (10, 17, 18) essentially firmly or stiffly and / or that at least one profiling is provided in at least one cross-section transverse to the longitudinal direction of the leg, that in particular the side surface (12, 13) in the area of the profiling and in at least one longitudinal section parallel to the longitudinal direction of the leg is substantially straight from the end apex (14) and that preferably the side surface (12, 13) lies in the area of the profile legs at an angle to the leg plane, which connects the flank ends of the profile sections to one another when the component is stress-free or linearly stretched or in the longitudinal direction of the structure (10) at a distance one behind the other, preferably at least one side surface ( 12, 13) in one of the sectional configurations essentially continuously and / or without gradations, essentially over the entire extent of at least one of the components (10, 12, 18) parallel to the sectional plane of this sectional configuration. Heater according to one of the preceding claims, characterized in that at least one profile with at least one of the components (10, 17, 18) forms a prefabricated assembly unit or is formed in one piece with the component (10, 17, 18) and that preferably at least one Support leg (18) forms a projection and / or that the respective support leg (18) at least over part of its longitudinal extent in a sectional configuration has leg sections lying at an angle to one another or at least one curvature. Heater according to one of the preceding claims, characterized in that at least one profiling or the respective support leg (18) has cross sections over most of the leg longitudinal extension, the extent of which in two mutually perpendicular directions is greater than the material thickness (29) of the starting material that in particular the profiling forms at least one curvature (23) of at least one side surface (13, 14) in cross-section over substantially the entire longitudinal extent of at least one of the components (10, 17, 18) and that in particular at least one of the components (10, 17 , 18) in the direction of the longitudinal extent of the building body (10) is extensible or the respective support leg (18) is curved in a channel shape and / or that the longitudinal extent of the respective support leg (18) is greater than the remaining height of the building body (10), that preferably the respective support leg (18) with the end apex (14) one transverse to the operation -Long extension protruding plug-in edge forms that in particular the respective plate-shaped support leg (18) in view parallel to the leg longitudinal direction is provided essentially within the outer boundaries (12, 13) of the associated longitudinal section of the structure (10), in particular at least one of the components (10, 17, 18) is secured against lifting movements solely by frictional engagement of at least one support flank (13, 14) and / or in the linear length orientation the length extension of at least one of the components (10, 17, 28, 38, 39) is smaller than the associated output length. Heater according to one of the preceding claims, characterized in that at least one of the components (10, 17, 18) is at least partially exposed on at least one carrier (3) of the base body (2) and thermally distributed over its length with the carrier (3) is coupled that in particular at least one of the components (10, 17, 18) is formed in one piece between length ends, or that at least one of the components (10, 17, 18) is fixed over its length and directly fixed to at least one carrier (4) and / or that the distance of the support area from the edge boundary (14) corresponds to a multiple of the material thickness (29) and the multiple includes every integer multiplier between 20 and 80, that in particular at least one support flank (12, 13) with its total surface extension over the entire area bears on the counter surface (19) and that preferably the material thickness (29) is between at most 0.1 mm and a two Ninetieth to fiftieth part of the longitudinal extension (34) of the support leg (18) and / or that at least one of the components (10, 17, 18) is distributed substantially uniformly over the heating field (20) or the resistor, and in particular that Counter surface (19) of at least one of the components (10, 17, 18) over most of its length, essentially free of play, against movements in essentially all directions parallel to the heating field (20) and / or against tilting movements in essentially all directions Secures positively, the directions being defined by opposite directions approximately parallel to the length extension and / or transversely to the length extension at least one of the components (10, 17, 18).

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