EP2109344A2 - Heating body of an electric radiator comprising a metal filament with helical coiling with differentiated spire zones - Google Patents

Abstract

The heating body (1) has an electric resistance heater (3) associated with a metallic diffuser (2) in the form of rectangular steel plates or sheds. The heater comprises a core formed of a metallic filament (5) i.e. continuous filament, with a helical winding embedded in a wire setting made of electrical insulating and thermal conducting material e.g. magnesia. The helical winding of the filament has two differentiated turn zones i.e. end zones (Ze1, Ze2), where turns are differentiated from one zone to another zone by linear heating power of the zones. An independent claim is also included for a method for forming a helical winding of a metallic filament with two differentiated turn zones for a heating body.

Description

The present invention relates to the field of electric radiator heaters, more particularly the heaters of the type comprising an electric heating resistor associated with a metal diffuser, as well as radiators incorporating such heating bodies.

Conventionally, the heating resistors of the electric radiator heating bodies comprise a core formed of at least one metal filament which is embedded in a lining of both thermal conductor material and electrical insulator (dielectric material). The most frequently used packing is magnesia (MgO) in the form of compacted grains. The metal filament connected to the power supply serves as an electrical resistance and is usually in the form of a regular helical winding.

According to a first embodiment of the heating resistor, the metal filament is introduced into one or more recesses formed directly in the metal diffuser of generally flat shape. The housing is then filled with magnesia which is compacted by surrounding the filament and holding it in place along the longitudinal axis of said housing.

According to a second variant embodiment of the heating resistor, the helically wound metal filament is placed in a metal tube, along the longitudinal axis of said tube and surrounded by compacted magnesia. The filament / magnesia / tube assembly here constitutes a tubular heating resistor which is directly fixed, for example by welding, to the surface of the metal diffuser to form the heating body of the electric radiator.

The heating element may comprise either a single heating resistor disposed in the central part of the diffuser, for example according to a single central longitudinal positioning, or several heating resistors according to parallel longitudinal positions extending between the two transverse edges of the diffuser.

In the case of the second variant embodiment of the heating resistor, said tubular resistor may meander on at least one of the faces of the diffuser, with rectilinear portions, preferably parallel and arranged longitudinally and curved portions located near the transverse edges of the diffuser.

The main function of the metal diffuser is to diffuse and distribute the calories emitted by the heating resistor by increasing the exchange surface with its environment. Conventionally, the diffuser may be in the form of a substantially flat plate for the insertion of the heating body preferably in radiating electric radiators, or be in the form of perforated fins as in electric convectors.

It has been found that with this type of heating resistor comprising a core formed of a metal filament with a regular helical winding, the temperature of the diffuser is not homogeneous over its entire surface. In particular along the heating resistance, the central zone of the diffuser is, for the same distance from said resistance, hotter than the end zones of the filament located near the transverse edges of the diffuser.

• elle génère des contraintes mécaniques qui peuvent avec le temps détériorer ou déformer le diffuseur, les soudures, voire la résistance chauffante et son filament métallique ;
• en outre, pour permettre au diffuseur de ne pas dépasser la température admissible par les matériaux des éléments constituants du corps de chauffe, le concepteur est amené à surdimensionner ces derniers, ainsi que les résistances chauffantes. Ce surdimensionnement influe directement sur la dimension totale de l'appareil de chauffage ainsi que sur son prix de revient.

This lack of homogeneity of the diffuser temperature has several disadvantages:

• it generates mechanical stresses that can with time deteriorate or deform the diffuser, the welds, or even the heating resistance and its metallic filament;
• in addition, to allow the diffuser not to exceed the temperature allowable by the materials of the components of the heating body, the designer is made to oversize them, as well as the heating resistors. This oversizing directly affects the total size of the heater and its cost.

• ils décentrent le positionnement des résistances chauffantes sur les diffuseurs : par exemple pour certains corps de chauffe constitués de deux résistances rectilignes disposées horizontalement l'une au-dessus de l'autre sur un diffuseur plan rectangulaire vertical, ils prévoient un décentrage des deux résistances vers le bas, la zone supérieure du diffuseur étant en effet naturellement plus chaude que la zone inférieure en raison de la convection naturelle de la chaleur diffusée par les résistances ; ce décentrage permet d'équilibrer quelque peu les températures entre les deux zones supérieure et inférieure du diffuseur. Néanmoins, cette solution n'a qu'une influence limitée sur l'homogénéité des températures du diffuseur et ne permet pas de réaliser des gains significatifs sur la dimension globale du corps de chauffe.
• ils reportent en dehors du diffuseur les deux extrémités des résistances chauffantes qui sont des zones mortes (c'est-à-dire pas ou très peu chauffantes) destinées à relier ces dernières à l'alimentation électrique. Il en résulte des longueurs de résistance supplémentaires et par conséquent un coût supplémentaire et un encombrement accru du corps de chauffe.

To improve the homogeneity of the temperature of the diffusers, the manufacturers implement at present the following solutions:

• they decenter the positioning of the heating resistors on the diffusers: for example for certain heating bodies consisting of two straight resistors arranged horizontally one above the other on a rectangular vertical plane diffuser, they provide for a decentering of the two resistances towards the bottom, the upper zone of the diffuser being indeed naturally warmer than the lower zone due to the natural convection of the heat diffused by the resistances; this decentering makes it possible to balance the temperatures between the two upper and lower zones of the diffuser. Nevertheless, this solution has only a limited influence on the homogeneity of the diffuser temperatures and does not make it possible to make significant gains on the overall dimension of the heating body.
• they post outside the diffuser both ends of the heating elements that are dead zones (that is to say, not or very little heat) for connecting them to the power supply. This results in additional resistance lengths and therefore additional cost and increased size of the heater.

An object of the present invention is therefore to improve the homogeneity of the diffuser temperature of the electric radiator heater body, without increasing the dimensions of the diffuser or the associated heating resistor (s) (s) ( s).

Another object of the present invention is to improve the homogeneity of the temperature of the diffuser without modifying the positioning of the electric heating resistance nor the structure of the diffuser, with respect to the current heating bodies.

Since the improvement of the homogeneity of the diffuser temperatures makes it possible to reduce the value of the maximum temperature zone of the diffuser, another object of the present invention is to reduce the dimensions of the diffuser and therefore of the heating element in order to achieve material and cost.

For this purpose, the present invention relates to an electric radiator heater body, of the type comprising an electric heating resistance associated with a metal diffuser, in the form of a plate or fins, the heating resistor comprising a core formed of at least a helically wound metal filament embedded in a lining of electrically conductive thermal and insulating material, such as magnesia, characterized in that the helical winding of the metallic filament has at least two zones of differentiated turns, differing from a zone to another by their linear power of heating. This differentiation of the linear heating power of said zones can be obtained by turns differentiating from one zone to another by parameters geometric (eg arrangement of turns, shape of turns, diameters of filament) and / or the nature of their constituent material.

Advantageously, the helical winding comprises two zones of turns, called end zones of the winding, disposed near at least one of the edges of the diffuser, and at least one intermediate coil zone, disposed between said zones. end, the turns of said intermediate zone being different from the turns of at least one of said end zones of the winding.

Several parameters define the winding of the turns, in particular its pitch, its diameter, the section of the filament, and the constituent material of the filament.

According to a first embodiment of the invention, the winding of the turns of at least one of said end zones has a pitch different from that of the turns of at least one intermediate zone.

Advantageously, the pitch of the turns of at least one of the end zones of the helical winding is less than the pitch of the turns of at least one intermediate zone of said winding.

Thus, the helical winding is tighter in at least one of the end zones near a transverse edge of the diffuser; the linear power of the diffuser is then increased in this or these zone (s), making it possible to compensate, at least partially, the heat losses.

In a preferred variant of this first embodiment, the pitch of the turns is progressively decreasing from said at least one intermediate zone to at least one of the end zones of the helical winding.

According to a second embodiment of the invention, the turns of at least one of the end zones of the helical winding have a diameter different from that of the turns of at least one intermediate zone. The diameter of the turns corresponds to the diameter of the helical winding of the metallic filament.

Preferably, the diameter of the turns of at least one of the end zones of the helical winding is greater than that of the turns of the at least one intermediate zone, and even more preferably the diameter of the turns is progressively increasing from said at least one intermediate zone to at least one of the end zones of the helical winding.

Thus, the length of the filament and thus the linear power of the helical winding is increased in the end zone (s) relative to the intermediate zone, allowing an increased heating of the edges of the diffuser and thus a better homogenization of the the temperature on the surface of the entire diffuser.

According to a third embodiment of the heating body according to the invention, the zones of differentiated turns of the helical winding are differentiated from one zone to another by the nature of their constituent materials. Thus, the turns of at least one of the end zones of the helical winding can be made of a material with a lower electrical conductivity than the constituent material of the turns of the at least one intermediate zone.

According to a fourth embodiment, it is also possible for the helically wound metal filament to have a larger filament section in at least one of the end zones of said winding than in said at least one intermediate zone. Thus, the resistivity of the filament is increased in the end zone (s) and consequently the linear power of heating.

In all of the above embodiments, the helically wound metal filament may be either a continuous filament of a single section, or may consist of a filament comprising at least two sections arranged in series and interconnected. by electrical conductive connection means, each section substantially corresponding to a differentiated turn zone.

For the same heating body, the turns of two end zones of the helical winding may be identical or different from each other by their arrangement, their shape, the nature of their constituent material, or the diameter of the filament, or by several of these parameters.

The present invention also relates to a method for producing the helical winding of the metal filament with zones of differentiated turns for a heating body as described above. The method is characterized in that it consists, from a uniform helical winding, of selectively stretching or tightening at least a portion of the turns of the helical winding corresponding to said zones, for example by selectively stretching the turns of the central area intermediate of the helical winding or by "compressing" (or "compacting") the turns of said helical winding in the end zones, before or during filling with the electrical insulating material.

The method according to the present invention, may also consist, from a uniform helical winding, to increase the diameter of at least a portion of the turns of the helical winding corresponding to said end zones.

Thus, with a standard helical winding metal filament it is possible to improve the homogeneity of the diffuser temperature by increasing the linear power at the edges of said diffuser in order to at least partially recover the temperature difference existing between the region central and the transverse edges of the diffuser.

The present invention also relates to any electric radiator, radiator type electric radiator or electric convector, comprising a heating body disposed in an envelope, the heating body being as described above.

• Les figures 1 et 2 présentent respectivement une vue en coupe verticale et de côté d'un corps de chauffe dont le diffuseur comporte des logements de résistances chauffantes ;
• Les figures 3 et 4 présentent respectivement une vue en coupe et de côté d'un corps de chauffe avec une résistance chauffante soudée à la surface du diffuseur ;
• La figure 5 est une coupe transversale selon AA d'un détail du corps de chauffe de la figure 3 montrant la résistance soudée sur le diffuseur ;
• La figure 6 est une vue en coupe longitudinale selon BB de la résistance chauffante présentée à la figure 3 ;
• Les figures 7, 8 et 9 schématisent différents modes de réalisation de l'enroulement hélicoïdal du filament métallique servant à réaliser un corps de chauffe selon la présente invention ;
• La figure 10 schématise les isothermes relevées sur un demi-corps de chauffe selon l'art antérieur en fonctionnement ;
• La figure 11 schématise les isothermes relevées sur un demi-corps de chauffe selon l'invention en fonctionnement.

Other features and advantages of the invention will emerge from the following description of the various embodiments given as non-limiting examples and shown in the accompanying drawings, in which:

• The Figures 1 and 2 respectively show a vertical and side sectional view of a heating body whose diffuser comprises housing of heating resistors;
• The Figures 3 and 4 respectively show a sectional and side view of a heating body with a heating resistor welded to the surface of the diffuser;
• The figure 5 is a cross-section along AA of a detail of the heating body of the figure 3 showing the solder resistance on the diffuser;
• The figure 6 is a longitudinal sectional view along BB of the heating resistor presented in FIG. figure 3 ;
• The Figures 7, 8 and 9 schematize various embodiments of the helical winding of the metal filament for producing a heater according to the present invention;
• The figure 10 schematizes the isotherms recorded on a half-heater according to the prior art in operation;
• The figure 11 schematizes the isotherms recorded on a half-heater according to the invention in operation.

On the Figures 1 to 4 are schematized heating bodies 1 according to the present invention, in which a diffuser 2, here of substantially flat and rectangular shape is associated with one or more heating resistors 3.

According to a first construction variant of the heating body 1 presented to Figures 1 and 2 , the diffuser 2 consists of extruded profiles (for example aluminum) or two stamped plates (for example aluminum or steel) contiguous, assembled by welding or screwing and leaving between them longitudinal housing 10. In each of these dwellings 10, prior to filling them with the electrically insulating material, a spiral-wound metal filament 5 is disposed along the longitudinal axis of said housing. The filament / dielectric material assembly forms a heating resistor 3 connected to the power supply 4.

The Figures 3 and 4 show a second variant of construction of the heating body 1. In this variant, the heating resistor 3 is in the form of a metal tube 6 curved U-shaped, the two rectilinear branches are arranged parallel to the longitudinal edges of the diffuser, said tube being fixed for example by welding on one of the faces of the diffuser 2. The diffuser 2 may be here, for example, a rectangular steel plate.

The figure 5 in section according to AA, a welding detail of the heating resistor 3 presented to the figure 3 . The heating resistor 3 consists of a metal tube 6 in which is disposed, in its axial part, a metal filament 5 wound helically wound in a dielectric material (electrically insulating) 7, here a packing consisting of grains of magnesia (MgO ) compacted. The tube 6 is fixed by welding points 8 to the metal plate forming the diffuser 2.

The figure 6 is a sectional view along BB of a portion of the heating resistor 3 of the figure 5 showing the helical winding of the filament 5 developing along a coaxial line, here rectilinear, of the tube 6. In the portion shown in FIG. figure 6 , this helical winding has a diameter d of turns of constant value and a regular winding, that is to say a constant pitch p between the turns. The metal filament 5 forming the core of the heating resistor 6 is thus characterized by its pitch p which corresponds to the distance between two adjacent turns and its diameter d.

For a given heating resistor length, the linear heating power of the resistor and therefore of the heating element is substantially proportional to the length of the metal filament 5. This linear heating power increases when the diameter d of the helical winding increases or when his step p decreases.

According to the present invention, the diameter and / or the pitch of the helical winding are modified so as to vary the linear power of heating, and therefore the temperature of the heating resistor, and thus of the associated diffuser, in specific zones.

For example, as schematized on the figure 7 the turns of the end zones Ze of the helical winding have a pitch Pe less than the pitch Pi of the turns of the intermediate zone Zi. This modification of the pitch of the turns can be obtained by stretching the filament in the central intermediate zone Zi of said winding or by, as shown on FIG. figure 8 , the series series of helical windings sections of different pitch. These sections are put in series and interconnected by electrically conductive fixing strips 9.

The embodiment of the metallic filament schematized at figure 7 can be implemented in the heating bodies as presented to the Figures 1 and 3 .

In the heating body 1 of the figure 1 , the helical winding of each metal filament 5 is more "tight", that is to say no shorter, in its end zones Ze ₁ and Ze ₂ , and more "loose", that is, that is to say, no larger, in the intermediate zone Zi, located between the two end zones Ze ₁ and Ze ₂ .

Similarly, for the heating body of the figure 3 the helical winding of the metal filament 5 is not shorter in the end zones Ze ₁ and Ze ₂ (where the helical winding develops around a straight coaxial line) located near a transverse edge 12 of the diffuser, with respect to the pitch of the turns of the intermediate zones Zi ₁ and Zi ₂ .

Advantageously, it is also desirable to have a further differentiated helical winding of the filament in a particular intermediate zone Zi ₃ approximately corresponding to the curved portion of the electrical resistance, namely a "looser" winding, that is to say say at no longer than the pitch of the turns of the intermediate zones Zi ₁ and Zi ₂ substantially rectilinear. Indeed, it has been found that the region of the diffuser receiving the curved portion of electrical resistance is generally warmer when the turns of the helical winding of the metal filament there are identical to those of the intermediate zones Zi ₁ and Zi ₂ rectilinear; this intermediate zone Zi ₃ curve of the helical winding is actually on a relatively narrow region of the diffuser.

So, as represented on the figure 3 at the rectilinear ends of the heating resistor 3 (left on the figure 3 ), the turns of the helical winding of the metal filament are closer together and induce a higher linear power of heating, and at the curved portion of the resistance, the turns of the helical winding of the metal filament are further apart inducing a linear heating power lower than that of the intermediate zones Zi ₁ , Zi ₂ , in order to rebalance the temperature differences between the different regions of the diffuser, and to achieve greater homogeneity.

According to a second embodiment of the invention, the diameter of the turns of the helical winding is variable. It may be, for example, of value of the ends of the helical winding and of value di at least in the intermediate zone Zi, as shown in FIG. figure 9 .

In both embodiments described above, the metal filament is made of a homogeneous metal material, for example a nickel-chromium alloy, containing 80% by weight of nickel.

According to a third embodiment, the sections of the helical winding corresponding to zones Ze and Zi may be of different natures, namely of material of different electrical conductivity, for example by varying the percentages of the constituents of the alloy forming the filament.

According to a fourth embodiment of the heating body according to the invention, the sections of the helical winding corresponding to zones Ze and Zi can have a filament of different diameter, between 0.10 and 0.50 mm, for example respectively 0.20 mm for the Ze zone and 0.40 for the Zi zone.

However, the nature of the filament material and its diameter must be compatible for use as an electric heater heater electrical resistance component, that is to say able to withstand without damage temperatures up to 450 to 500 ° C about.

Example 1 (comparative)

The heating body consists of a diffuser of the type shown at figure 1 , plane, length 700 mm and width 260 mm, made of extruded aluminum having two housings for electric heating resistors 3. Each of the two heating resistors 3 comprises a metal filament core with uniform and uniform helical winding with a constant pitch of approximately 1 mm and with a diameter of 2.5 mm, which corresponds to a total filament length of approximately 5.10 m. The filament itself is made of nickel-chromium alloy with 80% nickel and a diameter of about 0.50 mm. The electrical power of each resistor is 375 W. The linear power of the heater is 1.07 W / mm.

The figure 10 schematizes the isotherms on the surface of the diffuser.

Note that the hottest region (point Tmax = 292.3 ° C) is near the middle region at the level of the upper heating resistor. The further away from this median region, the lower the temperature and the minimum temperature value located at the bottom right end, along the transverse edge of the diffuser, is Tmin = 208 ° C. Thus, for the heating element of the prior art, a value of ΔT of 84.3 ° C. is obtained.

The average temperature of this heater was 184.6 ° C.

Example 2

The broadcaster as presented to the figure 1 is flat, 640 mm long and 260 mm wide, in extruded aluminum. Each of the two heating resistors 3 comprises a metal filament core (of the same type and diameter as in Comparative Example 1) with a helical winding with a constant pitch of approximately 0.95 mm in the intermediate zone Zi (corresponding to a linear heating power of 1.19 W / mm over a length of 220 mm), and of steps of about 0.65 mm in the end zones Ze ₁ and Ze ₂ (corresponding to a linear heating power of 1.68 W / mm over a length of 65 mm). The diameter of the turns of this helical winding is 2.5 mm, which corresponds to a total filament length of approximately 5.10 m. The electrical power of each resistor is 375 W.

The results are presented on the figure 11 . We notice that the hot spot and the cold point of the diffuser of the figure 11 are in the same regions as for the broadcaster of the figure 10 corresponding to comparative example 1.

The hottest point (Tmax = 286.9 ° C) is of value lower than that of the hottest point of Example 1, while the coldest point is of equal value: Tmin = 208 ° C (thank you confirm) . The ΔT of only 78.9 ° C is reduced compared to that of Example 1.

The average temperature is 194 ° C.

It has therefore improved the homogeneity of the diffuser as shown by the curves of the figure 11 . Despite a total length decreased by 60 mm (that is to say decreased by 9%), the maximum temperature of the diffuser according to the invention (example 2) is only 5.4 ° C lower than the basic model (Example 1), while ΔT (Tmax - Tmin) also dropped by 5.4 ° C and the average temperature increased by nearly 10 ° C. It is therefore possible to have heating bodies of reduced dimensions relative to the heating bodies of the prior art with a better homogeneity of the temperature.

More generally, the invention is applicable to all types of heating bodies for radiators or electric convectors existing currently on the market, consisting of an envelope in which is housed this heating body.

The present invention also relates to processes for producing helically wound filaments of shape corresponding for example to the winding shown in FIG. figure 7 .

Helical winding metal filaments are made with machines that deform a wire and wind it on itself in one direction longitudinal, such as a coil spring. According to the prior art, the pitch p of the wire is constant. In order to manufacture helically wound metal filaments with variable pitch, from prefabricated metal filaments with constant pitch, several methods can be implemented.

One method consists in pre-stretching certain portions of the metal filament 5, before accommodating it in the tube 6 of the heating resistor 3 (cf. figure 3 ), or the housing 10 of the diffuser 2 (cf. figure 1 ). This stretching could even go as far as to obtain almost rectilinear sections (the pitch p of the metal filament 5 then tending towards infinity), in certain selected zones.

Another method consists in varying the tension of the metal filament 5 during the filling of the tube 6 or the housing 10 with the dielectric material 7. When a portion of the metal filament 5 is surrounded by the dielectric material 7, it is possible to stretching more or less the portion of the metal filament 5, before filling a new section of tube 6 with said material and then compacting it. The final shape of the filament after filling and compacting the dielectric material 7 is for example schematized by the figure 7 .

Claims (15)

Electric heater body (1), of the type comprising an electric heating element (3) associated with a metal diffuser (2), in the form of a plate or fins, the heating resistor (3) comprising a core consisting of at least one helically wound metallic filament (5) embedded in a lining made of thermally conductive and electrically insulating material, such as magnesia, characterized in that the helical winding of the metal filament (5) has at least two zones of turns differentiated, differing from one zone to another by their linear heating power. Heating element (1) according to claim 1, characterized in that the helical winding comprises two zones of turns, called end zones (Ze; Ze ₁ , Ze ₂ ) of the winding, arranged near to at least one of the edges of the diffuser (2), and at least one zone of intermediate turns (Zi; Zi ₁ , Zi ₂ , Zi ₃ ) disposed between said end zones, the turns of said intermediate zone being different from the turns of the at least one of said end zones of the winding. Heating element (1) according to claim 2, characterized in that the winding of the turns of at least one of said end zones (Ze; Ze ₁ , Ze ₂ ) has a pitch (p) different from that of the turns at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ). Heating element (1) according to claim 3, characterized in that the pitch (p) of the turns of at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding is less than the pitch turns of at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ) of said winding. Heating element (1) according to any one of Claims 2 to 4, characterized in that the pitch (p) of the turns is progressively decreasing of the said at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ) to at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding. Heating element (1) according to one of Claims 2 to 5, characterized in that the turns of at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding have a diameter different from that of the turns of at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ). Heating element (1) according to claim 6, characterized in that the diameter of the turns of at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding is greater than that of the turns of said at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ). Heating element (1) according to one of claims 6 or 7, characterized in that the diameter of the turns is progressively increasing by said at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ) towards at least one end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding. Heating element (1) according to any one of claims 2 to 8, characterized in that the turns of at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of the helical winding are made of a material with lower electrical conductivity than the constituent material of the turns of said at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ). Heating element (1) according to one of Claims 2 to 9, characterized in that the helically wound metal filament (5) has a larger section of filament in at least one of the end zones (Ze; Ze ₁ , Ze ₂ ) of said winding than in said at least one intermediate zone (Zi; Zi ₁ , Zi ₂ , Zi ₃ ). Heating element (1) according to any one of the preceding claims, characterized in that the helically wound metal filament (5) is a continuous filament of a single section. Heating element (1) according to any one of claims 1 to 10, characterized in that the helically wound metal filament (5) consists of a filament comprising at least two sections arranged in series and interconnected by means of electrical conductor connecting means, each section substantially corresponding to a differentiated turn zone. Process for producing the helical winding of the metal filament (5) with differentiated turn zones for a heating element (1) according to any one of Claims 1 to 12, characterized in that it consists, from a uniform helical winding, to stretch or selectively tighten at least a portion of the turns of the helical winding corresponding to said zones. Process for producing the helical winding of the metal filament (5) with differentiated turn zones for a heating element (1) according to any one of Claims 1 to 12, characterized in that it consists, from a uniform helical winding, to increase the diameter of at least a portion of the turns of the helical winding corresponding to said end zones. An electric radiator, of the radiating electric radiator or electric convector type, comprising a heating body arranged in an envelope, the heating element being in accordance with any one of Claims 1 to 12.

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