FR2566985A1 - Heating panel for electrical heating installation - Google Patents

Abstract

The invention relates to heating panels of the electrical resistor type making it possible to produce heating installations integrated into floors or the walls of a construction. To improve the reliability of the presently produced heating installations, the invention consists in using, as heating element, the concrete-reinforcing steel rods 2 customarily incorporated in the panels 1, by assembling the rods end to end and arranging them in concertina fashion to form a continuous electrical circuit which is connected via the two ends 4, 5 to the terminals of the secondary winding of a step-down voltage transformer 6. The invention finds applications in multifarious fields such as the construction of buildings for living, business or agricultural use.

Description

 The invention relates to electric heating panels making it possible to produce heating installations integrated in floors or in the walls of a building.

 It finds applications in the construction of buildings for residential or professional use as well as in very varied fields such as those of animal husbandry or market gardening.

Many techniques have already been proposed and used to achieve this mode of electric heating.

 A known method consists in generating heat by Joule effect by means of an electric cable having a high ohmic resistance, insulated or not, embedded in a concrete slab at the time of construction and supplied with 110 or 220 V effective , (EDF network).

 This method has the drawbacks due in particular to insulation faults or to ruptures of the heating circuit caused during installation or subsequently by cracks in the concrete slab.

 We have also proposed in French patent No. 2511.485 electric heating installations in which the generation of heat by the Joule effect is caused by the passage of a current through the thickness of an electrically resistant concrete (for example a slab) comprising parallel conductive faces each connected to a terminal of a low electrical voltage source. The installations thus produced have the drawbacks of cracks in the concrete slab which will oppose the flow of current due to the discontinuity of the electrical resistance. In addition, there is a fear in the long term of a disintegration of the material by electrochemistry.

 The invention overcomes these drawbacks.

 Its purpose is to provide an electric heating installation carried out by means of very reliable, inexpensive and maintenance-free heating panels.

 It relates to an electrical heating installation made using panels manufactured in situ or prefabricated which directly use the usual components used in the building industry. In particular, the heating element is shaped to form the reinforcements of the reinforced concrete, giving the panels their mechanical properties.

 Each of the electrical resistance type heating panels embedded in a rigid insulating material and comprising means for connection to a source of electrical energy comprises at least one rigid conductive element chosen to have a very low ohmic resistance value, and shaped to play the role of mechanical reinforcement of the panel.

 Advantageously, the conductive reinforcement regularly winds through the thickness of the panel so as to ensure a homogeneous distribution of the heat over the useful face of the heating panel.

 Depending on the desired application, this frame is embedded in a mass of concrete or plastic such as, for example, polyester.

 The material constituting the metal frame and the dimensioning of this frame are chosen according to the required mechanical and electrical properties.

 Advantageously, the panel is made of concrete and the rigid reinforcement is formed by the irons usually incorporated to give the panels determined mechanical properties.

 To obtain the desired thermal effect, the concrete irons arranged so as to form a continuous circuit are supplied with alternating electric current at very low voltage (12 to 50 V rms) by means of a transformer whose primary is connected to the local electricity distribution network.

 To make the heating circuit, it is planned to assemble the linear elements of iron, end to end, by means of welds (autogenous or electric) so as to form a continuous circuit, the two ends of which are brought back to the point of connection provided with the transformer.

 The concrete is then poured to completely coat the heating network, so that it is embedded approximately half the thickness of the panel.

Other characteristic objects and advantages of the present invention will be specified in the following description, with reference to the accompanying drawings which represent
Figure la and lb: a plan and section view respectively of a panel
intended to be placed on the ground.

Figure 2: a first alternative embodiment comprising three
panels each with a heating power
annuity.

Figure 3: a second alternative embodiment comprising three
panels each with a different heating power
rent and individual start-up.

Figure 4: a third alternative embodiment comprising two
heating networks superimposed in the thickness of the panel.

Figure 5: an installation comprising jux heating panels
taposable for greenhouses or growing frames.

In the embodiment shown in FIGS. 1a and 1b, a heating panel 1 comprises an electrical conductor 2, constituted by a reinforcing iron embedded in a concrete screed 3 and determined to give the panel its desired mechanical properties. The concrete used is a
3 common type concrete, consisting of CPA cement dosed at 350 Kg / m and river sand aggregate.

In this example, the heating panel is a floating screed supported by a layer of thermal and / or phonic insulator 31 disposed on a support structure
The conductor 2, arranged in an accordion, winds regularly with a pitch 7 of about 0.5 m, in the concrete mass 3, and its two ends 4 and 5 are respectively connected to the terminals of the secondary winding of a step-down transformer voltage 6.

The length of the conductor is 70 m and its diameter 6 mm. The ohmic resistance of the electric circuit is 0.42) L. Powered by a voltage of 30 V eff., The circuit dissipates 2,000 W taking into account the increase
2 tation of the ohmic resistance due to the temperature, that is to say approximately 35 W / m2.

 A first alternative embodiment, FIG. 2, comprises 3 panels 10, 11, 12 each having a different heating power, obtained by adjusting the pitch 13 of the conductor 14. The conductor of each panel is connected to that of the neighboring panel by means of 'A weld 15, autogenous or electric. This welding is not necessary if the concrete constituting the three panels is poured in one go. This alternative embodiment could be applied to domestic heating depending on the destination of the rooms in an apartment: for example, the panel 10 could be the floor of a living room, the panel 11 that of a bathroom. , panel 12 that of a bedroom.

 A third alternative embodiment in FIG. 3 comprises three panels 20, 21, 22 identical to those proposed in the second alternative embodiment, but the heating circuit of each panel can be put into service separately by means of switches 23, 24, 25 In this embodiment, the transformer 26 has three secondary windings.

 FIGS. 4a and 4b illustrate a third alternative embodiment presented respectively in plan view and in section and which comprises two superimposed heating networks 30 and 31 arranged in the same panel 32. The two networks are braced with insulating shims 33, produced in wood for example, used during installation. This embodiment finds applications to panels whose mechanical properties must be identical in two directions.

 FIG. 5 illustrates an installation comprising juxtaposable heating panels. It is presented as an application for heating greenhouses and frames.

 The arming iron 40 of each panel 41 is connected to the iron of the following panel, at the time of installation, by means of an autogenous weld 42.

The return conductor 44 connected to a terminal of the secondary of the transformer 43 is produced with a copper wire of adequate section.

 If the panels are intended to be placed on the floor, it is preferable to interpose polystyrene between the floor and the panels.

 In these exemplary embodiments, it is always possible to adjust the voltage applied to the heating network as a function of the ohmic resistance of the circuit produced, either to obtain the desired power, or on the contrary, to adjust it to the local conditions observed.

 The power dissipated in the panel is determined according to the desired use: auxiliary heating, main heating or comfort heating (heating a tiled floor). It will also be necessary to take into account the thermal insulation of the construction carried out. For example, for the production of a 7 cm thick concrete slab, isolated from the ground by a 5 cm thick layer of polystyrene, the dissipated power which is approximately 35 W / m is sufficient to heat a tiling and bring its temperature around 180C.

The ohmic resistance of the heating circuit is determined by means of the known formula R = and / s, formula in which R is the resistance of the heating circuit, e is the resistivity of the iron at
6 2 concrete (about 15.106JL / cm / cm2 at OC) ss is the length of the circuit, s is the section of the iron.

 A circuit made with concrete iron with a diameter of 6 mm and a length of 70 m then has an electrical resistance of 0.4L.

 With irons of double diameter, the ohmic resistance would be 4 times lower and to dissipate the same power, that is to say to obtain the same thermal effect, it would be advisable to supply the circuit with a voltage twice as low .

The supply voltage to the heating network is determined by
2 the relation P = U2 / R, formula in which P is the dissipated power,
U is the effective secondary voltage of the transformer, R is the ohmic resistance of the heating circuit.

 Knowing U, P and R, the transformer can be defined.

 It is possible to regulate the temperature of the panel using a thermostat placed in series in the supply circuit of the transformer primary winding. In practice, this regulation is not always necessary. It is often preferable to determine the optimal power adapted to the desired goal (main heating, backup, comfort). This parameter can also be sought experimentally after production by means of sockets on the secondary of the transformer.

 Among the many advantages of this type of heating, it should be emphasized that there is no danger of electric shock due to the use of a very low voltage supply (max. 50 volts).

 In addition, thanks to the use of a transformer, there is no risk of loss of electrical energy by bypass to earth.

 Furthermore, the low ohmic resistance of the heating circuit makes the possible presence of moisture in the concrete without disadvantage on the operation.

 Finally, the concrete reinforcing iron being very robust, any cracks in the slab cannot cause the electrical circuit to break.

On the other hand, given the large diameter of the heating element, its mass, that of concrete and the evacuation of calories by conduction, convection and radiation, the temperature of the heating circuit remains low (less than 500C) unlike that of the heating wires usually used.

 This is particularly advantageous because, on the one hand the mechanical properties of the iron are not altered, on the other hand, there is no problem of relative expansion between the concrete and the iron, nor of the behavior of the concrete at the temperature.

 This new means of heating is therefore very reliable, clean, requires no maintenance and presents no danger. I1 contributes, with a good return, to the heating of the dwellings. Its use is very flexible, and allows for example, to provide maintenance heating in the event of prolonged absence or commissioning by remote control.

 This heating process can be used for heating greenhouses and growing frames. The presence of moisture necessary for the vegetation being without disadvantage on the operation. The prefabricated heating tiles are then placed on a sheet of thermal insulating material and covered with topsoil.

Claims (9)

 1- Composite heating panel (1) of the electrical resistance type embedded in a rigid insulating material and comprising means for connection to a source of electrical energy, characterized in that the electrical resistance consists of at least one conductive element (2 ) shaped to play the role of mechanical reinforcement of the panel.  2- composite heating panel (1) according to claim 1 characterized in that the conductive element (2) forming the frame is shaped according to a coil and has an ohmic resistance of very low value.  3- composite heating panel (1) according to claim 1 characterized in that the frame is embedded in concrete.  4 Composite heating panel (1) according to claim 1 characterized in that the frame is embedded in a plastic material.  5- composite heating panel (1) according to any one of claims 1 to 3, characterized in that the frame is constituted by metal son.  6- composite heating panel (1) according to any one of claims 1 to 3, characterized in that the frame is constituted by concrete irons (2).  7- Heating panel according to any one of claims 1 i 6 characterized in that it comprises several frames (30, 31).  8- Electric heating installation characterized in that it comprises at least one heating panel according to any one of claims 1 to 7 and means for connection to a low voltage electric source.  9- Installation according to claim 8 characterized in that the heating panel is supported by a layer of insulating material.  10- Installation according to any one of claims 8 to 9 characterized in that the heating panels consist of prefabricated elements assembled.