ELECTRICAL CIRCUITAccording to a fi

ELECTRICAL CIRCUIT

According to a first embodiment, the power supply circuit comprises a plurality of current generators that are each connected to an electrode. In this case, each electrode is managed by its own current generator. This embodiment has a simple design. According to a second embodiment of the invention, the power supply circuit comprises at least one sensor for measuring the current (im) between each electrode and the keratin materials.

Advantageously, the power supply circuit comprises a microcontroller designed to control the voltage between each electrode and the counter electrode, thereby making it possible to control the current. Said voltage is regulated on the basis of the current (im) measured by the sensor.

In this case, the power supply circuit comprises at least one current generator connected to a plurality of electrodes. In other words, the electrodes are connected in parallel to at least one current generator.

Advantageously, the device according to the invention comprises an electronic unit designed to put the power supply of the electrodes on standby if the current detected between an electrode and the skin is below a predetermined threshold value (is). The potential difference between the electrode and counter electrode is kept at a threshold value (Us) by the power supply circuit, with the power supply on standby.

By contrast, if the current (im) detected between an electrode and the skin is above this threshold value (is), the generator increases the current to a predetermined value (Ii) higher than is. The current flows between the electrode and the counter electrode through the skin.

More advantageously, the electronic unit comprises a plurality of current sensors for detecting the current value between each electrode and the skin.

Preferably, the power supply circuit comprises a microcontroller.

Preferably, the threshold current (is) is between 5 μΑ and 10 μΑ. The power supply at each electrode is regulated on the basis of the current measurement (im) detected between the electrode and the skin. This current is advantageously detected by a sensor.

The current (im) is compared with the threshold current value (is) by a microprocessor.

If (im) > (is), then the generator delivers a power supply current at the electrode that ranges up to a predetermined value (Ii).

If (im) < (is), then the generator does not deliver any additional current at the electrode. A standby situation is then the case. Preferably, the current (Ii) is identified in order to reach a current intensity per unit area that ranges from 0.01 mA/cm2 to 0.5 mA/cm2, preferably from 0.1 mA/cm2 to 0.3 mA/cm2.

It will be understood that the term "microcontroller" corresponds to a single electronic device, for example a microprocessor chip, or to a set of programmable electronic elements, for example communication gateways that allow management by a third party item of equipment (such as a PC, PDA, etc.).

More preferably, each electrode is connected to a switch. The latter forms a means for detecting the presence of the current. It acts as a current sensor.

Even more advantageously, each electrode is surface mounted on an electronic board.

ELECTRICAL PARAMETERS

The electrical power source may comprise any non-rechargeable battery or any storage battery. The voltage between the electrodes is for example between 1.2 V and 24 V, preferably between 1.2 and 3.3 V. If appropriate, the passage of the current can create spot heating.

The electrical power source may comprise, for example, a DC voltage source. In a variant, the electrical power source may comprise an electronic circuit for varying the amplitude of the voltage generated over time. This electronic circuit may be a chopper, for example.

At an equivalent current density, the device can in particular deliver a current density, at the skin, of preferably less than or equal to 0.500 mA/cm2, for example between 0.1 mA/cm2 and 0.500 mA/cm2, for example between 0.1 mA/cm2 and 0.30 mA/cm2.

ELECTRODES

The electrodes have a visible free surface allowing them to come into direct contact with the skin.

The device can be used in a dabbing manner, the user holding the device in one hand and bringing the electrodes into contact with the skin. The user can move the device while keeping the electrodes in contact with the skin or move the electrodes away from the skin while the device is being moved between a first area and a second area.

The electrode may be flat, for example in the form of a flat disc or polygon.

The electrode may be porous. The electrodes may have various shapes and for example a surface intended to come into contact with the skin which is convex towards the outside, concave towards the outside, or flat. Preferably, the electrodes are smooth so as not to hurt the skin.

The electrodes may be formed by two spheres or rollers, being able to rotate or not rotate in respective housings.

The electrode may be hollow, being formed for example