FR2580451A1 - Heating resistor. - Google Patents

Abstract

The present invention relates to a heating resistor, in particular for an electric convector or any other appliance for heating utilising electricity through the Joule effect, including a heating element traversed by an electric current and a body serving as heat exchanger. This heating resistor is characterised in that it includes a heating element 10 consisting of a positive temperature coefficient electrical resistor 10 cooperating with electricity supply means 12, means of electrical insulation 17 and a body 6 forming a heat exchanger. The invention relates to the electrical heating industry.

Description

 The present invention relates to a heating resistor, in particular for an electric convector or any other heating device using electricity by the Joule effect, comprising a heating element traversed by an electric current and a body serving as a heat exchanger.

 There are already known, in the current state of the art, a large number of heating resistors intended for electric convectors.

 Armored resistors are frequently used for this type of application, essentially consisting of a metal tube, in which are placed, on the one hand, an electrical resistance supplied with current, and, on the other hand, magnesia which serves to fill the gap existing between the electrical conductor and the tube, so as to ensure thermal continuity and electrical insulation.

 During the operation of this type of heating resistor, the heat emitted by the electrical resistance is transmitted to the metal tube via magnesia, then dissipated in the ambient air using an exchanger integral with said metal tube. Several drawbacks are linked to the shielded resistors known in the current state of the art, in particular because of their electrical characteristics, and their method of manufacture.

 Indeed, the manufacture of armored resistors as described above is relatively complex and costly since the magnesia which is introduced between the electrical resistance and the aluminum outer sheath must be compressed under high pressure to ensure good thermal conductivity.

 In addition, the ohmic curve, that is to say the variation of the resistance of such a heating element with temperature is of the linear type slightly increasing. As a result, there is a risk of overheating during an increase in the applied voltage, which requires the use of a thermal safety device placed on the heating resistor to prevent its destruction.

 The object of the present invention is to remedy these drawbacks and proposes to provide a heating resistor which is easy and inexpensive to manufacture, and which moreover has an ohmic curve such as to protect it automatically against overheating, even in this case. lack of ventilation or when the electric convector is accidentally covered.

 Another object of the present invention is to provide a heating resistor which makes it possible, as a function of the ohmic characteristics and of the dimensions of the heating element, to determine the maximum temperature reached by the heating element, according to the specific application of the heating resistance.

 To this end, the invention relates to a heating resistor, in particular for an electric convector or any other heating device using electricity by the Joule effect, comprising a heating element traversed by an electric current and a body serving as a heat exchanger. , heating resistor characterized in that it comprises a heating element constituted by an electrical resistance with a positive temperature coefficient, and cooperating with electrical supply means, electrical insulation means and a heat exchanger.

 The invention will be better understood by referring to the following description given by way of nonlimiting example and to the appended drawing in which - Figure 1 shows the ohmic characteristic of the heating element used in the heating resistor according to l 'invention; - Figure 2 is a perspective view of the heating resistor according to the invention.

 We refer to figure 1.

 According to the invention, a heating element whose resistance varies with temperature is used in the heating resistor shown in FIG. 2, in accordance with the characteristic shown in FIG. 1.

 This characteristic 1 is that of a resistance with a positive temperature coefficient, which is a thermistor, known per se, whose resistance increases with temperature, within a determined range of the characteristic. The temperature variation of the thermistor is obtained either by the passage of a current (Joule effect), or by a variation of the ambient temperature, or by a combination of these two factors.

 According to characteristic 1 represented in FIG. 1, which is in particular that of a semiconductor resistor or of a composite material such as a ceramic, the resistance of the heating element first decreases slightly when the temperature increases (zone 2 of characteristic 1), which corresponds to a slightly negative temperature coefficient. Then, the temperature rising above Tm corresponding to the minimum male resistance Rm, there is an inversion of the slope of characteristic 1 (zone 3), that is to say that the temperature coefficient becomes positive, and then increases strongly (zone 4), in a ratio of 10 to 100% per degree Cel sius. A maximum resistance value RM is quickly reached, which corresponds to a temperature TM, beyond which the temperature coefficient becomes negative again.

 When a heating resistor having an ohmic characteristic such as that shown in Figure 1, is energized, it is crossed by an electric current which produces a Joule effect. As a result, the heating element sees its temperature increase, and, consequently, its resistance decrease. However, the decrease in the resistance of the heating element ceases for a determined value Tm of the temperature, depending moreover on the material used, which corresponds to zone 3 of characteristic 1.

 Then, the resistance of the heating element increases rapidly, and therefore, this heating element is crossed by a weaker electric current, from where a reduction of the Joule effect, and a fall or a stabilization of the temperature.

 The ohmic characteristic 1 is therefore particularly advantageous when it is used, according to the invention, in particular in electric convectors, since it eliminates any risk of overheating. Furthermore, because the resistance of the heating element begins to decrease, the current draw, when the electric convector is energized, is lower than for normal resistance, which has advantages for the network. electricity distributor.

 We refer to figure 2.

 According to the invention, the heating resistor 5 mainly comprises a body 6 formed of two flanges 7 and 8. These flanges 7 and 8 can take any known manner capable of facilitating heat exchange with the ambient air, and can also to this end have vents 9 allowing better heat distribution.

 The heating resistor 1 according to the invention further comprises a heating element 10, made of a material whose ohmic characteristic is of the type shown in FIG. 1, that is to say that the heating element 10 is constituted by an electrical resistance with a positive temperature coefficient.

 In a particularly advantageous embodiment of the present invention, the heating resistor 10 is constituted by a longitudinal bar il of rectangular section, and cooperating with electrical supply means 12. These consist of two studs affecting the shape of two aluminum bars 13, 14 of rectangular section.

These bars 13 and 14 made of aluminum or another conductive metal, are pressed against the side faces 15 and 16 of the heating element 10, so that when they are connected to a source of electricity, the current electric pass from one to the other of the bars 13 and 14 by crossing transversely the heating element 10.

 Of course, it is necessary to electrically isolate the heating element 10, as well as the aluminum bars 13 and 14 serving for the supply. To this end, the heating resistor 1 also comprises electrical insulation means 17, constituted by two bars 18 and 19 which are made of an electrically insulating, thermally conductive material, and which are pressed against the external faces 20 and 21 of the aluminum bars 13 and 14.

 In a particularly advantageous embodiment of the present invention, the material used to make the bars 18 and 19 is samicanite.

 Obviously, electrical continuity and thermal continuity between the different facing elements can only be achieved if these are strongly pressed against each other. To this end, the assembly obtained by juxtaposing the heating element 10, the aluminum bars 13 and 14 and the samicanite bars 18 and 19 is crimped in a housing 22 obtained by back-to-back joining the two flanges 7 and 8, in which grooves 23 are made beforehand, for example by folding.

 To ensure the joining and tightening of the assembly, the lateral flanges 7 and 8 are assembled by any means, in particular by spot welding.

 The heating resistor 5 described above has a number of advantages. It allows in particular an easy manufacture by assembly, and this whatever the length desired for the resistance.

 It also makes it possible to remove the additional thermal safety devices normally used, since there is no longer any risk of overheating, even in the absence of ventilation of the heating resistance or when the device is accidentally recovered. In fact, in this case, the temperature tending to rise, the resistance of the heating element increases very quickly, which automatically drops the dissipated electrical power to a very low and harmless value.

 Furthermore, the heating resistor according to the invention can be supplied at different voltages, and even high voltages, without being exposed to destruction. In addition, a judicious choice of the numerical values of the ohmic characteristic of the heating element makes it possible to determine in each specific case of use, the maximum and optimal temperature to be reached by the heating element.

In addition, the heating resistor according to the invention can easily operate with or without forced ventilation, the equilibrium temperature reached being in both cases the same and determined by the ohmic characteristic of the heating element.

 Although the invention has been described in connection with a particular embodiment, it is understood that it is in no way limited thereto and that it is possible to make various modifications to the forms, materials and combinations of these. elements, without departing from the scope and spirit of the present invention.

Claims (10)

Claims  1. Heating resistance, in particular for an electric convector or any other heating device using electricity by effect Jouie, comprising a heating element traversed by an electric current and a body serving as a heat exchanger, heating resistance characterized in that it comprises a heating element (10) constituted by an electrical resistance with positive temperature coefficient (10) , and cooperating with electrical supply means (12), electrical insulation means (17) and a body (6) forming a heat exchanger.  --2. Heating resistor according to claim 1, characterized in that the heating element (10) has an ohmic characteristic (1) first linearly decreasing with temperature (zone 2), then strongly increasing (zone 4) after a bend ( zone 3) joining the decreasing part (zone 2) to the increasing part (zone 4) of the characteristic (1).  3. Heating resistor according to claim 1, characterized in that said electrical resistance with positive temperature coefficient (10) consists of a longitudinal bar (11) with rectangular section, made of composite material with positive temperature coefficient.  4. Heating resistor according to claim 1, characterized in that said composite material with positive temperature coefficient is a ceramic.  5. Heating resistor according to claims 1 and 3, characterized in that said longitudinal bar (11) is placed between two electrical supply pads (12) pressed against its lateral faces (15) and (16).  6. Heating resistor according to claim 5, characterized in that said electrical supply pads (12) are constituted by two aluminum bars (13) and (14) of rectangular section.  7. Heating resistor according to claim 1, characterized in that said electrical insulation means (17) are constituted by two bars (18) and (19) electrically insulating, pressed against the external faces (20) and (21) aluminum bars (t3) and (14).  8. Heating resistor according to claim 7, characterized in that said bars (18) and (19) electrically insulating, are thermal conductors.  9. Heating resistor according to claims 1 to 7, characterized by! E fact that the heating element (10), successively surrounded by said aluminum bars (13) and (14), then by the electrically insulating bars (18) and (19), is crimped in a housing (22) arranged in the body (6) forming a heat exchanger 5 and the flanges (7) and (8) are secured by spot welding.  10. Heating resistor according to claim 8, characterized in that the insulating bars (18) and (19) are made of samicanite.