EP0730813A1 - Touch control supply system for electrical equipment, method of manufacture and applications - Google Patents

Abstract

A system for supplying at least one electrical apparatus provides touch control and can be used in particular in home automation for supplying electrical equipment such as light bulbs, strip lights, electrical power points, motors, etc., or can form part of equipment such as lamps and lamp stands. The system comprises zones (such as continuous strips B1... B4 on partitions) chemically treated to reduce impedance and to allow leakage currents to flow to the detection inputs of static modules ( M1... M4) providing a switching or dimming function. The treated strips (B1... B4) comprise user accessible portions (A1... A4) which, when touched, generate leakage currents and control the electrical equipment.

Description

INSTALLATION FOR SUPPLYING AN ELECTRICAL MEMBER ALLOWING A TOUCH CONTROL, METHOD FOR PRODUCING THE SAME

AND APPLICATIONS

The invention relates to a method for producing an installation for supplying an electrical member such as a lighting member, electrical outlet, relay, electromechanical switch, contactor, electric motor, etc., making it possible to control by touch. energizing or de-energizing said member and, where appropriate, generating variations in intensity of the supply current thereof. The invention extends to installations thus produced as well as to advantageous applications in particular in the field of home automation or that of the manufacture of lamps and luminaires.

Electronic devices are known which make it possible to control a lighting member by simple touch of a sensitive conducting element. For example, US Pat. No. 4,211,959 describes a control module for an electric lamp which makes it possible to switch it on or off by touching a metal rod. The company "SIEMENS" manufactures and sells an electronic module under the reference "CMOS DIMMER SLB0586" which includes a static switch, an electronic power variator and an electronic circuit for controlling these components; this circuit is provided with a detection input connected to a metal pad forming a touch sensor in order to deliver control pulses which are a function of the leakage currents generated on said detection input when an operator touches the metal pad; these pulses are shaped by the control circuit so as to open or close the static switch in the event of brief contact on the metal pad, or to control a cyclic variation of the power at the output of the variator in the event of prolonged contact. Such a control module is produced by the manufacturer to be used in particular in the field of home automation in order to replace the wall switches, and allow to switch on or off a lighting device, and adjust the brightness in the absence of any device with mechanical movement. The control module is generally embedded in the wall or applied against it (in place of the electromechanical switch) so that its metal patch is visible; the power supply installation for the lighting device also remains traditional; it requires, in particular, the installation of power conductors connecting the lighting member, the control module, the metal pad of which serves as a contactor, and the electrical supply network.

Furthermore, this type of module is applied in the certificate of utility FR 2.574.157 to a mood lamp with a metal base, the latter playing the role of touch sensor with a view to creating leakage currents when the operator touches him. However, this use remains very limited since few lamps have a metal base suitable for this application. To overcome this limitation, US Patents 4,507,716 and DE 2,641,105 recommend coating an insulating lamp base in order to make it conductive, or else equipping it with a conductive sheet or conductive electrodes, the control module having a sensitive input which is electrically connected to these conductive elements. However, these transformations that the lamps must undergo are expensive and modify the appearance of them, and cannot be envisaged for old lamps.

The object of the present invention is to apply in a new way the control modules of the aforementioned type in order to produce supply installations of new design, capable of leading, in particular in the field of home automation, to considerable advantages, in particular to a significant simplification of power lines, a reduction in technical constraints, and significant savings in installation (reduction and even elimination of bloodletting, moldings, chutes, ...). Another objective of the invention is to considerably widen the possibilities of application of such modules, in particular application to lamps with insulating plinth, various home automation applications, certain industrial applications, application to the control of certain electronic equipment.

The method of the invention for producing an installation for supplying at least one electrical member enabling it to be controlled by touch is of the type in which said electrical member is connected to an electrical source by means of a line of power, a static switch is inserted on said power line so as to be able to open or close the latter, and said static switch is controlled by means of an electronic circuit provided with a detection input, this electronic circuit being adapted to generate switches of said static switch as a function of low intensity leakage currents appearing at its detection input; according to the method of the present invention, the detection input of the electronic control circuit is connected to a support made of a material of an electrically insulating nature, and a chemical treatment is applied to said support so as to reduce the electrical impedance of the one of its zones below a threshold adapted for said zone to be able to conduct leakage currents, said chemical treatment of the support being carried out so that the reduced impedance zone is electrically isolated, qu 'It is brought into electrical contact with the detection input of the electronic circuit and it has a portion accessible to the touch, so as to allow the appearance of leakage currents when the said portion is touched by an operator.

By "operator" is meant both a human person and any material element capable of moving to come into contact with the accessible portion of the treated area. In home automation applications or concerning lamps and luminaires which are more particularly described below, the operator will generally be a man touching the accessible portion of the treated area with his finger; in certain industrial applications (limit switch device for example), the operator can be a lug placed on a mobile assembly to come into contact with this treated area.

According to an advantageous characteristic of the invention, means are inserted in series on the detection input of the electronic control circuit, for measuring the variations in the leakage current Δi and

Δt inhibit said leakage current in the event of variations below a predetermined threshold. This thus eliminates the appearance of parasitic leakage currents, due for example to climatic changes (temperature, humidity), which could inadvertently trigger the control of the electric organ: these parasitic leakage currents indeed exhibit slow variations and are inhibited by the above means.

According to another advantageous characteristic of the invention, the zone or zones of reduced impedance are polarized by connecting them to the electric source through a resistive bridge (R- |, R2) and a diode bridge (D- |) of so that the said zone or zones are permanently referenced to the phase of the electric source. The installation can thus be connected to the electrical source (electrical supply network or other) without worrying about the phase / neutral connection direction.

With the static switch inserted on the power line, it is possible to associate an electronic power variator; the electronic control circuit is then adapted to control said variator as a function of the leakage currents appearing at its detection input in order to allow variations in the intensity of the supply current of the electrical component. In particular, it is possible to use an electronic circuit of the "CMOS DIMMER SLB0586" type manufactured by the "SIEMENS" company adapted to deliver control pulses to leakage currents to the static switch and the power variator. In this circuit, the switch function and the variator function are provided by a Triac, the trigger of which receives control pulses shaped by an integrated circuit. It is thus possible not only to obtain a power up or off of the electrical member, but also to vary the power supply thereof. It is thus possible, by touch, to adjust the intensity of the lighting of a lamp or the speed of rotation of a motor. In this type of circuit, the cyclic variation of power is obtained by a prolonged contact on the accessible portion of the treated area, the operator stopping the contact when the power reaches the desired value; the closing or opening of the power line is obtained by rapid contact.

According to a preferred embodiment, the support is chemically treated so that the electrical impedance of the zone situated between the accessible portion and the detection input has a value below a threshold of the order of 20 megaohms and preferably around 5 megaohms. In particular, a value between 0.1 and 5 megaohms gives good results in most applications (absence of nuisance tripping; safe and reproductive control when touched, producing sufficient leakage currents to be detected by the electronic circuit and generate the generation of control pulses for the static switch or drive).

Preferably, the electronic control circuit is fitted with a resistive bridge composed of resistors, connected between the detection input and the electrical source; in each application, the values of the resistances of this bridge can thus be adjusted as a function of the impedance between the accessible portion and the detection input, in order to optimize the appearance of the leakage currents. Depending on the application, the insulating support consists of a base, possibly a lampshade (lamp), a wall, a partition or a ceiling (home automation application) or any other insulating element (keyboard keys, ...); this support can be of a very diverse type of insulating material and in particular of wood, ceramic, earthenware, porcelain, stoneware, plastic, glass, granite, marble, plaster, cement, concrete, terracotta, paper, fabric, leather, rubber, paint, synthetic foam or a derivative of these materials. In a preferred embodiment, the support is treated by means of an ionic solution, in particular acid solution or saturated saline solution; an aqueous solution based on iron perchloride, hydrochloric acid or a chloride is advantageously used. Tests have shown that the impregnation of the area to be treated with the support by means of such solutions for durations depending on the nature of the support makes it possible to reduce the impedance of this area to give it a satisfactory value in the ranges of values mentioned above, and this, permanently.

The method of the invention can in particular be applied to produce a lamp controllable by touch, comprising a hollow base made of a material of an electrically insulating nature and a lighting member carried by said base; in this app:

the wall of the hollow base is chemically treated to reduce its impedance over the entire surface with the exception of the lower part intended to serve as a base,

- the electronic circuit, the static switch and if necessary the power variator are secured inside the base, the detection input being electrically connected to the inside of the latter at the level of the treated area.

According to a variant, it is the lampshade made of an insulating material (fabric, cardboard, plastic) which is chemically treated to allow control. In this In this case, the detection input is connected to the treated area of the lampshade, for example by a conducting wire carried inside the lampshade by the support of the latter.

The method of the invention can also be applied to produce in a building the supply of at least one electrical member, in particular a bulb, lighting tube or electrical outlet; in this app:

- the electrical component is connected to the network by a power line at least partially carried by one or more walls of the building, which are made of a material of an electrically insulating nature, the electronic circuit, the static switch and, where appropriate the drive module being associated with said power line,

- One or more said walls are subjected to a chemical treatment along at least one continuous strip to achieve the reduced impedance zone, said chemical treatment being carried out so that said strip has a portion close to the electronic circuit and a portion accessible to touch,

- the portion close to the electronic circuit is electrically connected to the detection input of said circuit, - the portion accessible to the touch is marked to allow it to be identified.

Such an installation can also be used to power certain motors used in home automation (roller shutter motors, fan motors, etc.).

In such an installation, the power lines can remain inaccessible (lines housed between floor and ceiling, or housed between partitions, ...): these lines devoid of any surface extension (at least extensions of significant length) are easy to set up in the traditional way without the need to make grooves, moldings ... on the wall surfaces; orders are made in the absence electric wires (at least of appreciable length) thanks to the treated bands of reduced impedance, which are produced directly on the walls of the building so as to connect the detection input of the electronic circuit and the portion accessible to the touch. These strips obtained by simple impregnation are invisible after drying and impose no particular technical subjection, the accessible portion being simply identified so that the user can touch it with their finger. II. it should be emphasized that this portion does not include any added element, such as a contactor or recessed or projecting metal pad.

Of course, several electrical components can be controlled from several accessible portions thanks to a network of treated continuous strips having a reduced impedance, said network connecting the accessible portions and the electronic circuits associated with the various electrical components to be controlled according to an arrangement depending on the desired control plan. The method of the invention can also be applied for the control of certain electronic equipment, for example keys made of insulating material from computer keyboards, fax machines, telephones, typewriters, etc. The keys or portions thereof ( which are then fixed in the absence of any displacement switch) are processed to lower the impedance and are connected to the detection inputs of the electronic control circuits; this connection can be made by a conductor or by chemical treatment of areas of the support means which carry said keys, in order to lower the impedance.

The invention extends to installations carried out by implementing the above-defined method: home automation installation for supplying electrical organs in a building, lamp and luminaire, installation with fixed keys for controlling electronic or other materials. ..

The invention set out above in its form general will be better understood on reading the description which follows and on examining the appended drawings which present, by way of non-limiting examples, embodiments; in these drawings: FIG. 1 is a schematic perspective view of an installation in accordance with the invention, arranged in a dwelling house for supplying various electrical components thereof,

FIG. 2 is a schematic detail view of a circuit,

FIG. 3 partially shows a treated strip and its accessible portion,

FIG. 4 illustrates the operation for processing this strip, FIGS. 5 and 6 are block diagrams of electronic units equipping the circuit,

FIG. 7 is a schematic view in axial section of a lamp according to the invention,

FIG. 8 is a detailed view of said lamp on a larger scale,

- Figure 9 illustrates the processing operation of the base of said lamp.

The power supply installation shown schematically in Figure 1 includes power power lines such as L-j, L2, L3, L4 which are connected to the electrical network E.D.F. through the usual equipment housed in a box 1 (circuit breakers, meters ...). These lines supply various electrical components equipping the house, in the example a light bulb G-] housed in a globe, a motor G2 of a roller shutter, lighting tubes G3 and G'3 arranged in parallel and sockets G4, G'4, G "4 arranged in parallel.

The power lines Lj ... L4 are arranged to connect the members which they supply, by the shortest and most practical route without taking account of the control switches. For example, the line L-] is first applied vertically to the back of a wall (in particular in the space reserved for this purpose in current construction processes), then runs above the false ceiling. It passes in the vicinity of a wall P- _| supposed to be a plaster partition (prefabricated elements or wall made of building elements whose surface is plastered); in this portion, the line L- | is equipped with an electronic module M- _| of the type "CMOS DIMMER SLB0586" sold by "SIEMENS". Similarly, the line L2 is equipped with a similar module M2 in the vicinity of the wall P2 which one can assume is coated with a tapestry paper; line L3 is equipped with an M3 module near the wall P3 assumed to be dressed with facing briquettes; line L4 is equipped with a module M4 placed at the base of the wall P ₃ .

Line L- | and its module Mj are symbolized in FIG. 2. The module comprises: a printed circuit C ^ essentially composed, on the one hand, of a Triac associated with a power electronics in order to act as static switch and variator , on the other hand, an electronic control circuit in order to control the Triac,

. a circuit H ^ for measuring and inhibiting leakage current, connected to the detection input of circuit Ci in order to measure the variations in the leakage current Δi and to inhibit the leakage current in the event of

Δt variations below a determined threshold,

. a polarization circuit POi in order to continuously supply the measurement circuit H ^ and to polarize the treated areas of reduced impedance,

. finally a resistive bridge symbolized by the resistors R-j and R2, connected to the measurement circuit H ± and to the bias circuit PO ± as shown in FIG. 2.

Resistances R- | and R2 of the bridge are adjusted to a value close to 10.10 ° ohms for the resistance R- and from 0.3.10 ⁶ to 0.8.10 ⁶ ohms for resistance R2-

The detection input E <j is connected through the measurement circuit H ± and the resistive bridge Ri to the surface of the wall Pj by means of a fastening member fitted in the upper part F of this wall in the vicinity of the module M- _d . This fixing member comprises a metal head to allow the passage of leakage currents.

The wall P-] is treated along a continuous strip B-j having a width of one to a few centimeters. This strip extends from the portion F close to the module M-j to a lower portion A-j accessible by the users.

Treatment of area B- | of the wall can be carried out by impregnation by means of an application instrument T as shown diagrammatically in FIG. 4 (or possibly by means of a brush).

This impregnation is carried out by spreading over the width of the strip Bj an ionic solution, in particular an aqueous solution of iron perchloride, with a density of the order of 1.3. The impregnation is carried out by several passages; after drying, the impedance between the portion F and the portion A-] is measured and it is found that its impedance is no longer infinite (as was the case for the initial plaster partition) but has decreased; ion treatment of band B- | (number of impregnations) is carried out until reaching, after drying, an impedance having a value between 0.1 and 5 Megaohms between the two aforementioned portions. In addition, the accessible portion A- | is marked by any means to allow it to be identified (after drying, the strip B- | is no longer visible). For example, a border can be drawn or glued around this portion A-]. The other supply lines L2 ... are treated in an analogous manner so that the walls concerned P2 --- are provided with continuous strips B2 ... of reduced impedance connecting the detection inputs of the circuits concerned to accessible portions A2 ... which are identified on the walls concerned.

It is possible, as is the case of the module M2 which is associated with the line L2 for supplying the roller shutter G2, to process two (or more) continuous strips B2, B'2 which meet so as to have a common portion close to the M2 module, common portion to which the detection input of said module is connected. Each continuous strip B2, B'2 has an accessible portion marked A2, A'2: it is thus possible to control the electrical component concerned from several portions located at different locations. Where appropriate, the treated continuous strip may have an accessible portion of considerable length (extending in particular in the horizontal direction) with a view to authorizing control by touch from any point of this portion, this accessible portion being of course identified along its length by any appropriate means.

Several organs in parallel can be controlled simultaneously from the same accessible portion, as is the case for the tubes G3 and G'3 which are supplied by the line L3 and controlled from the portion A3 of the treated strip. B3 which is connected to the detection input of the module M3. The arrangement is similar for sockets G4, G'4 and G "4.

Different arrangements of continuous strips can be combined to obtain a desired control plane; the building wall (s) are then treated along a network of continuous strips which are connected to the detection inputs of a set of electronic modules and which have accessible portions located according to the desired control plane.

Touching a portion accessible by a user generates the appearance of very low intensity leakage currents along the continuous strip or strips which are connected to this accessible portion and on the detection input or inputs of the electronic circuit or circuits. partners; these currents are translated into this or these circuits by control pulses of the Triac (s) which generate an opening or closing of the power line (s) concerned or a variation in the transmitted power. The function of the measurement circuit H is to prevent small variations in the leakage current from being taken into account, in particular slow variations due to climatic changes (humidity, temperature). These slow modifications by nature generate variations in the leakage current which extend over several minutes and the measurement circuit Hi inhibits them. The variation threshold Δi beyond which the current

Δt of leakage is validated can be of the order of 10 ^{~ 6} amperes per second: it is thus ensured that a signal (representative of the appearance of a sufficient leakage current) is created on the detection input of the circuit Ci only in case of voluntary action on the portion A-]. An embodiment of the measurement circuit

Hi is shown in FIG. 5. The power supply for this circuit (not shown in this figure) is carried out continuously by the bias circuit POi (an example of which is described below with reference to FIG. 6). The resistive bridge (R- |, R2) translates the leakage current into a voltage signal which is picked up by an impedance adapter 11 of conventional type. At the output of the adapter 11, the image voltage of the leakage current is processed by a high-pass filter 12 which removes the DC component in order to center the signal.

The signal is then stored by a blocking sampler 13; the control unit 13c of this sampler delivers a control pulse at the frequency of the network in order to carry out storage at this frequency. The leakage current image signal is a mono-alternation signal (due to the polarization produced by the POi circuit) and the maximum value of this signal is thus memorized by the blocking sampler (in itself of conventional structure). The signal from The sampler 13 is processed by a low-pass filter 14 which suppresses the parasitic high frequencies and by an amplifier 15 which adjusts the maximum amplitude thereof.

The signal thus processed is delivered to the input of a differentiator 16 which calculates the derivative thereof and provides at output an image signal of the variation of the leakage current at the frequency of the network. This signal is compared in a comparator 17 to a reference signal generated by a reference generator 18, in order to output a logic signal as a function of the position of the input signal relative to the reference signal: the signal from the comparator 17 controls an output stage 19 consisting of an optocoupler which delivers a zero signal to the detection input of the circuit Ci in the event of Δi below a threshold

Δt (10 ^-6 amps per second, for example) or a positive signal capable of triggering the circuit Ci in the opposite case. FIG. 6 illustrates an embodiment of the polarization circuit POi. This circuit allows, on the one hand, to polarize across the resistive bridge R- | , R2 the reduced impedance zone Bj in order to reference it with respect to the phase of the sector and thus to generate single-alternation leakage currents, on the other hand, to supply the measurement circuit Hi with a direct, floating voltage relative to the network and referenced to leakage currents.

For this purpose, the circuit POi which is connected to the network comprises a diode bridge D- | whose output + is connected to zone B- | across the resistive bridge R-], R2. In addition, a transformer T- | has a primary winding connected to the electrical network and two secondary windings connected to conventional RD regulation modules in order to generate three DC voltage levels - 12 V, 0 and + 12 V to supply the Hi measurement circuit. The positive voltage level is referenced at the output of the diode bridge by an electrical connection. The process of the invention has many advantages compared to the traditional power supply process: great flexibility for carrying out complex installations with a minimum of equipment, limitation of technical constraints such as tapping, moldings, etc., considerable simplification of the layout of power lines, ease to modify the control network without destroying the walls ...

Figures 7 and 8 illustrate an embodiment of the method of the invention for producing a lamp.

This lamp comprises a base S made of a traditional electrically insulating material, for example porcelain. This base S is treated with an ionic solution to reduce its impedance over the entire surface S ^ with the exception of the base Sfc.

This treatment can be carried out as shown in FIG. 9 by inverting the base, closing off its neck and pouring the ionic solution up to the limit of the base S ^ ,. In the example, the solution can be an aqueous solution of iron perchloride with a density of approximately 1.3. The solution can be left for about 1 hour in the base. After drying, it is found that the material has a non-infinite impedance at the level of the zone S _n ; a measurement by means of an electrode in contact with the internal surface of the base (zone S _n ) and another electrode placed 3 cm from the first in contact with the external surface of the base (always at the level of the treated zone S ^) gives an impedance of the order of 10 ° ohms for a Limoges porcelain ("Ceradel-KPCL" manufacture, ref .: "TM10").

The base thus treated is conventionally equipped with a socket device 3 at its neck to support and supply a bulb 4. An electrical power cable 5 provided with a connection socket 6 crosses the base and is connected to the socket device 3. This cable carries an electronic module 5 (of the same type as the MJ ... M4 modules) interposed on the cable 5: the input of detection E '^ of this module M5 is connected to the internal surface of the base at the level of the high treated area S _n , by means of spring rods 7, 8 made of metallic material (for example three in number at 120 °) . The module M5 can be fixed on these rods with its detection input E '< _j welded onto them. The rods 7, 8 are arranged to come into contact with the internal surface of the base (treated area S _n ) by a non-point area.

In the example described, the resistances R- | and R2 of the resistive bridge of the M5 module can be adjusted to the following values: R- \ = 10.10 ⁶ ohms; R ₂ = 0.5.10 ⁶ ohms.

Furthermore, in the example, a layer 9 of an electrically insulating material (for example foam of synthetic material) is glued to the base of the base to close the latter and improve the quality of the electrical insulation of the base which serves of base.

The lamp can be supplemented in a conventional manner by a lampshade 10 supported by the socket device 3.

When an operator touches the external surface of the base at the level of the treated area S ^ (that is to say at the level of the entire surface with the exception of the base Sj-), it creates leakage currents very low intensity through the wall of the base, the rods 7, 8 and the detection input of the M5 module. As before, these leakage currents are translated by the electronic circuit of the module by control pulses which generate an electric opening or closing on the cable 5, or a variation of the transmitted power.

Furthermore, treatment tests have been carried out with different types of electrically insulating material, with a view to reducing the impedance thereof and making them capable of conducting leakage currents capable of triggering the abovementioned electronic modules. These tests consisted in making test pieces in the form of a strip in these materials, measuring the impedance on the one hand between two points on the same face. 3.6 cm apart (Z-]), on the other hand, between two points opposite the two faces (Z2), to treat the test pieces using ionic solutions Ij, I2 brought into contact with one face for a time T and to measure again the impedance between the same points Z'-j, Z'2.

The solution Ij consists of pure hydrochloric acid. Solution I2 consists of an aqueous solution of iron perchloride (density: 1.33). Functional tests of an electronic module "SIEMENS CMOS DIMMER SLB0586" were carried out with untreated test specimens and treated test specimens. In all cases, the impedances Zj and Z2 of the untreated test pieces are too high to allow the passage of leakage currents sufficient to trigger the module; on the other hand, with the treated specimens, a reproducible operation of the module is obtained (the resistances R- \ and R2 of the resistive bridge of the module had the following values in these tests: R- | = 20.2.10 ⁶ ohms; R ₂ = 0 , 47.10 ⁶ ohms.

The table below summarizes the results obtained.

Solution

Nature of Ionic thickness Duration T of the test piece ohms o hhm ² s used treatment ohms o Hhm ² s earthenware 10 mm 226.10 ⁶ 45.10 ⁶ '1 20 minutes 1, 2.10 ⁶ 10 ⁶ earthenware 10 mm 226.10 ⁶ 45.10 ⁶ ' 2 20 minutes 10 ⁶ 10 ⁶ earthenware 226.10 ⁶ 10 ⁶ enamelled on 10 mm (non-facing side 45.10 ⁶ '2 20 minutes (non-facing side 6.10 ⁶ one enameled side) enamelled) double thickness glass treatment 6 mm 555.10 ⁶ 85.10 ⁶ ' 2 - 6.3.10 ⁶ 5.10 ⁶ between wood thicknesses (poplar) 8 mm 49.10 ⁶ 46.10 ⁶ "2 60 minutes - 13.10 ⁶ plaster 35 mm 19.10 ⁶ 21.10 ⁶ l2 brush - 1, 2.10 ⁶ 10.7.10 ⁶ a porcelain layer 10 mm 222.10 ⁶ 58.10 ⁶ ' 2 20 minutes 10. ⁶ 10 ⁶ wallpaper 19.10 ⁶ I2 brush on plaster - paper side - one coat - 0.29.10 ⁶ - painted

Claims

CLAIMS 1 / - Method for producing an installation for the supply of at least one electrical component allowing control thereof by touch, in which said electrical component is connected to an electrical source by means of a line of power, a static switch is inserted on said power line so that it can be opened or closed, and said static switch is controlled by means of an electronic circuit provided with a detection input, this electronic circuit being adapted to generate switching operations of said static switch as a function of low intensity leakage currents appearing at its detection input, said method being characterized in that the detection input of the electronic control circuit is connected to a support made of a material of an electric nature insulator (Pj, P2, P3; S), and a chemical treatment is carried out on said support so as to reduce the electrical impedance e of one of its zones (Bj ...; S ^) below a threshold adapted so that said zone is able to conduct the leakage currents, the chemical treatment of the support being carried out so that the zone d 'reduced impedance (Bj ...; S _n ) is electrically isolated, that it is brought into electrical contact with the detection input of the electronic circuit and that it has a portion accessible to the touch (A- | ...; S ^), of so as to allow the appearance of leakage currents when said portion is touched by an operator.

2 / - Method according to claim 1, characterized in that is inserted in series on the detection input of the electronic control circuit, means for measuring the variations in the leakage current Δi and

Δt inhibit said leakage current in the event of variations below a predetermined threshold.

3 / - Method according to one of claims 1 or 2, wherein the polarized zone (s) of reduced impedance is polarized by connecting them to the electrical source through a resistive bridge (Rj, 2) and through a diode bridge (Dj) so that the said zone or zones are permanently referenced to the phase of the electric source.

4 / - Method according to one of claims 1, 2 or 3 in which an electronic power variator is associated with the static switch interposed on the power line, the electronic control circuit being adapted to control said variator according to leakage currents appearing at its detection input in order to allow variations in the intensity of the supply current to the electrical component.

5 / - Method according to claim 4, in which an electronic circuit of the "CMOS DIMMER SLB0586" type is used, manufactured by the company "SIEMENS" suitable for delivering control pulses as a function of currents to the static switch and the power variator. leak.

6 / - Method according to one of claims 1, 2, 3, 4 or 5, characterized in that the chemical treatment of the support is carried out so that the electrical impedance of the area between the accessible portion and the input detection has a value below a threshold of the order of 20 megaohms and preferably of the order of 5 megaohms. 7 / - Method according to one of claims

1, 2, 3, 4, 5 or 6 characterized in that the electronic control circuit is fitted with a resistive bridge composed of resistors (R- |, R2); connected between the detection input and the electrical source, and in that the value of the resistances of this bridge is adjusted as a function of the impedance between the accessible portion and the detection input.

8 / - Method according to one of claims 1, 2, 3, 4, 5, 6 or 7, characterized in that the support is treated with an ionic solution, in particular acid solution, saturated saline solution.

9 / - Method according to claim 8, characterized in that the support is treated by means of a aqueous solution based on iron perchloride, hydrochloric acid or a chloride.

10 / - Method according to one of claims 1 to 9 for the production of a lamp controllable by touch comprising a hollow base (S) in a material of electrically insulating nature and a lighting member (4) carried by said base , characterized in that:

the wall of the hollow base is chemically treated to reduce its impedance over the entire surface (S _n ) with the exception of the lower part (S5) intended to serve as a base,

- the electronic circuit, the static switch and if necessary the power variator are secured inside the base, the detection input being electrically connected to the inside of the latter at the level of the treated area (S _n ).

11 / - A method according to claim 10, characterized in that the chemical treatment is carried out by disposing for a determined period inside the base in the inverted position, a bath of ionic solution up to a level located below the part intended to serve as a base.

12 / - Method according to one of claims 1 to 9, for carrying out in a building the supply of at least one electrical member (G- | ... G4), in particular bulb, lighting tube, electrical outlet , electric motor, characterized in that:

- the electrical component is connected to the network by a power line (L- | ... L4) at least partially carried by one or more walls (P- | ... P3) of the building made of a material of nature electrically insulating, the electronic circuit, the static switch and if necessary the variator module being associated with said power line,

- one or more said walls are subjected to a chemical treatment along at least one continuous strip (B- | ... B4) in order to produce the zone of reduced impedance, the processing being carried out so that said strip has a portion close to the electronic circuit (F) and a portion accessible to the touch (Aj ... A4),

- the portion close to the electronic circuit is electrically connected to the detection input of said circuit,

- We mark the accessible portion to touch to allow its location.

13 / - Method according to claim 12 allowing the control of an electrical member from several portions accessible to the touch, characterized in that one or more walls are chemically treated along several continuous strips each having a portion accessible to the touch and meeting so as to present a common portion close to the electronic circuit connected to the detection input of the latter.

14 / - Method according to one of claims 12 or 13 for controlling several electrical components, characterized in that each electrical component is connected to the network by a power line of its own or common to one or more other electrical components, and in that that the wall (s) is chemically treated along a network of continuous strips electrically connected to the electronic control circuits as a function of the desired control plane.

15 / - Method according to one of claims 12, 13 or 14, characterized in that the chemical treatment is carried out by spreading the ionic solution along the continuous strip (s) by means of an appropriate application instrument (T ).

16 / - Method according to one of claims 1 to 15, wherein the treated support is made of a material or a material derivative of the following group: wood, ceramic, earthenware, porcelain, stoneware, plastic, glass, granite, marble , plaster, cement, concrete, terracotta, paper, fabric, leather, rubber, paint, synthetic foam.

17 / - Installation of power supply at least one electrical member, in particular a lighting member, comprising a power line connecting said electrical member to an electrical source, a module (M- _j ... M5) comprising a static switch interposed on said power line so as to being able to open or close the latter and an electronic control circuit for said static switch, said electronic control circuit being provided with a detection input and being adapted to generate switchings of the static switch as a function of low leakage currents intensity appearing at its detection input, said supply installation being characterized in that:

the detection input of the electronic control circuit is connected to a support made of a material of an electrically insulating nature (P- | ... P3; S),

- said support comprises a chemically treated zone (B- | ... B4; S ^) of reduced electrical impedance such that said zone is capable of conducting leakage currents, - said zone of reduced impedance is isolated on the plane electrical, is in electrical contact with the detection input of the electronic circuit and has a portion accessible to the touch (Aj ... A4; S _n ) so as to allow the appearance of leakage currents when the said portion is touched by an operator.

18 / - Power installation according to claim 17, characterized in that it comprises, arranged in series on the detection input of the electric control circuit, measuring means (H- ^) for measuring the variations of the current leakage Δi and

Δt inhibit said leakage current in the event of variations below a predetermined threshold.

19 / - Power installation according to claim 18, characterized in that the measuring means (Hi) comprise a blocking sampler (13) and its control unit (13c) in order to memorize the current at the frequency of the electrical source, a differentiator (16) receiving the signal from the blocking sampler and delivering at the frequency of the electrical source an image signal of the variation of the leakage current, and a comparator (17) receiving the signal from the differentiator and a reference signal with a view to delivering an inhibition or validation signal according to the difference between the signals received.

20 / - Power supply installation according to one of claims 18 or 19, characterized in that it comprises polarization means (POi) connected to the electric source and comprising a diode bridge (D- |) for polarization zones of reduced impedance and a transformer (T- _| ) with two secondary windings for supplying the measuring means (Hi).

21 / - Power supply installation according to one of claims 17, 18, 19 or 20, in which the module (M-) ... M5) comprises an electronic power variator interposed on the power line, the electronic circuit being adapted to control said variator as a function of the leakage currents appearing at its detection input.

22 / - Power supply installation according to claim 21, comprising a module of the "CMOS DIMMER SLB0586" type manufactured by the company "SIEMENS" comprising an electronic control circuit suitable for delivering pulses to the static switch and the power variator of the leakage currents.

23 / - Power installation according to one of claims 17 to 22, characterized in that the reduced impedance area of the support has between its accessible portion and the detection input an impedance of value less than 20 megaohms and preferably between 0.1 and 5 megaohms. 24 / - Supply installation according to one of claims 17 to 23, characterized in that the electronic control circuit is equipped with a resistive bridge of adaptable resistors (Rj, R2), connected between The detection input and the output connected to the electrical source.

25 / - Lamp controllable by touch comprising a hollow base (S) of an electrically insulating material, a lighting member (4) carried by said base, an electric power cable (5) connecting said lighting member to a connection socket (6), a module (M5) comprising a static switch, and if necessary, a power dimmer interposed on the supply of the lighting member and an electronic circuit for controlling said switch and dimmer depending on the leakage currents appearing at a detection input (E'd), said lamp being characterized in that: - the hollow base has a chemically treated wall (S _n ) of reduced electrical impedance over the entire surface at l except the lower part (S5) intended to serve as a base,

- the module (M5) composed of the electronic control circuit, the static switch and if necessary the power variator is secured inside the base, the detection input being electrically connected to the internal face of said base at level of the treated area (S _n ), - the detection input of the electrical control circuit is provided, in series, with means for detecting variations in the leakage current and for inhibiting said leakage current in the event of variations less than a predetermined threshold. 26 / - Home automation system for supplying at least one electrical component (G- | ... G4), in particular bulb, lighting tube, electrical outlet, or electric motor, comprising an electrical supply line for said component (Lj ... L4) at least partly carried by one or more walls of the building (P- | ... P3) made of a material of an electrically insulating nature, at least one module (M- | ... M4) comprising a static switch and, where appropriate, a power variator interposed on said power supply and an electronic circuit for controlling said switch and variator as a function of the leakage currents appearing at a detection input (Ed) of said circuit, this module being in particular of the "CMOS DIMMER SLB0586" type manufactured by the company "SIEMENS", said installation being characterized in that:

- the wall (s) (Pj ... P3) comprise at least one chemically treated continuous strip (Bj ... B4) of reduced impedance, capable of conducting the leakage currents, - the treated continuous strip has a portion (F ) close to the electronic circuit, electrically connected to its detection input (Ed),

the treated continuous strip has a portion accessible to the touch identified by a marking (A- | ... A4),

- The detection input of the control circuit is provided, in series, with means (Hi) for detecting variations in the leakage current and for inhibiting said leakage current in the event of variations below a predetermined threshold.