ES1063601U - Electronic device for diatermia (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Diathermy apparatus, characterized in that it comprises an enveloping body, manually operable, equipped inside it with the electric power supply and with the electronic means generating the radiofrequency pulses, connected to two active metallic electrodes adjacent to each other, for application to the subcutaneous zone comprising the defect to be treated, said electrodes occupying separate areas of the surface of the housing of the apparatus, determining a unique intermediate zone between both electrodes for its application to the skin defect to be treated. (Machine-translation by Google Translate, not legally binding)

Description

Electronic device for diathermy.

Object of the invention

This device, by diathermy by led currents, it is effective in multiple applications in the field of electromedicine and in the field of electrostatics.

Background of the invention

Diathermy is the use of currents special electric to raise the temperature of living tissues for therapeutic purposes.

The increase in the temperature of living tissues  It may be unintended as in the case of devices electrosurgery, or intentional as with devices with therapeutic or electrostatic uses.

The rising temperature of living tissue by diathermy is achieved by transmitting energy to it by two methods: by induced currents (electrodes without tissue contact) and by conducted currents.

In diathermy by conducted currents apply two electrodes in contact with living tissue and it is produced a current flow between the two electrodes that it crosses the living tissue it finds in its path. Current flowing the tissue temperature rises due to the Joule effect due to the resistance of the fabric itself. With contact coupling (conducted currents) there are two methods of application: the capacitive method and resistive method. In diathermy with contact coupling electrodes are usually asymmetric, in that case, and due to the current density, the higher temperature rise occurs in more tissues next to the active electrode (the smaller one). In the method resistive the two electrodes are metallic without insulating. In the method capacitive the two electrodes are metallic, but one of them It has an insulating layer.

In general, the frequency of the signal applied in  the contactless coupling method must be far superior to the signal frequency applied in the coupling method with Contact.

Diathermy by conducted currents has shown as a very effective tool in multiple applications of the field of electromedicine and electrostatics.

Several diathermy devices are known, some of them portable, applicable to electrosurgery with electrocoagulation function, for hematogenous purposes or for promote healing, not producing in any of them a increased temperature of living tissue for therapy.

Summary of the invention

The object of the present invention is a new and small portable and manual diathermy device suitable for the epidermal care, mainly for the facial area, but not exclusive of other body areas, in order to decrease wrinkles, stretch marks, sagging, scars, etc., and increased hydration.

The device in question produces an increase in the temperature in: the dermis, the epidermis and in deeper layers such as muscle depending on its resistance electrical to the passage of the electric current through it, by An applicator handle. With this increase in temperature you get a significant increase in blood circulation. I also know produces a pleasant feeling of relaxation and an increase in oxygen level, providing a very important revitalization in the treated area that can be seen a few minutes from treatment.

Although fundamentally the device is designed For facial use in people, it can also be applied to others body parts and even animals.

The device is formed by an ergonomic handle that integrates two metal electrodes in contact with the living tissue to be treated, the current flowing through the tissue by conduction. The goal is to increase the temperature locally. The indicated handle comprises a control knob that regulates the output power, being able to hold the handle and operate the device with one hand. The device is preferably powered by rechargeable batteries or batteries integrated in the same applicator handle, so it can be autonomous from the mains, although it could also be powered directly from the mains via a connection cable
flexible.

The treatments are carried out using a handle applicator in which at one end the two are located metal electrodes without insulating layer, although in a variant one or both electrodes can have an insulating layer. Both electrodes they must be of suitable biocompatible material for the treatment of diathermy on the human body.

The maximum output power can be of the order of 20 W, however a typical value can be 6 W. The power of output can be variable by means of a regulating control.

The frequency of the applied signal can be in  a range of 100 kHz to 10 MHz so that a nerve stimulation, and its value is not essential for Correct device functionality.

These and other features will come off better than the detailed description that follows, to facilitate which It is accompanied by three sheets of drawings in which it has been represented a case study that is cited only by way of non-limiting example of the scope of the present invention.

Description of the drawings

In the drawings:

Figures 1 and 2 illustrate schematically, in side and front elevations respectively, the device subject to the invention.

Figure 3 shows a signal that can be of current or voltage normalized to the unit for maximum power delivered to the output.

Figure 4 shows a signal that can be of current or voltage normalized to the unit for 30% approximately of the power delivered to the output.

Figures 5 and 6 show signals for different  powers delivered by varying the modulation of the voltage or of the output signal current.

Detailed description

According to the drawings, the device electronic for diathermy comprises two electrodes (1) and (2) installed next to each other in a tool (3) by which apply together in the area to be treated. The two electrodes are preferably metallic, however one or both could have an insulating layer

The tool (3) consists of an ergonomic handle (4) forming an inclined head (5) with an application plane (6) where the two electrodes (1) and (2) next to each other are installed yes.

The handle itself (4) comprises, in one version Preferred rechargeable batteries or dry batteries (7) for your operation with sufficient autonomy to carry out one or more complete treatments, a power level display made by an LCD display (8), with segment digits or with LEDs (9), a control (10) control and regulation of the output power, a printed circuit (11) comprising a Oscillator (12) with control circuit, an output amplifier high performance (13) and a battery charger circuit (14).

With reference (15) a control of start-up to be installed on the handle (4) in the event that the device does not include a motion sensor for its connection or disconnection.

Preferably the electrodes (1) and (2) will be installed in fixed mounting on the handle (4) with a separation of for example between 0.3 cm and 1 cm, however if desired could be installed in a mount that allowed to regulate its separation. To vary the width of the application area the device could comprise several aligned electrodes being able to connect two of them with the amplifier of radiofrequency

If appropriate, the possibility also fits of installing the electrodes with an adjustable angle.

The two electrodes (1) and (2) may be the same or similar size, symmetric or asymmetric, and its surface area application will be preferably flat although in some cases may present a convex or other configuration that suits your  application, the preferred surface area being 0.5 cm 2.

With reference (16) a connector of feeding.

The variation of the output power with the command (10) can be achieved by varying the amplitude (modulation of amplitude) (Fig. 3 and Fig. 4), or by modulating the output signal by a pulse or pulse signal (Fig. 5 and Fig. 6) (width modulation PWM pulse). In figures 3, 4, 5 and 6 the axis of abscissa is the time and the axis of ordinates is the amplitude of the signal applied normalized to unity. Figure 3 shows the signal that Provides maximum output power. To reduce this power can decrease the amplitude of the output signal as shows figure 4 (amplitude modulation). Another way to vary the output power is connecting the signal during a certain period of time and disconnecting it for another period of time, so that the average output power is reduced when the Pulse duration is reduced (Figures 5 and 6). The power of output in figures 5 and 6 depends on the time during which Apply the signal. The power that delivers the signal in Figure 6 is  smaller than that of figure 5, this being in turn smaller than the power delivered by the signal in figure 3. This type of output power control is called width modulation Pulse (PWM).

Figures 3, 4, 5 and 6 show a signal sinusoidal example, however the signal also applied It can be square, exponential or triangular.

To vary the power, one acts on a control which can be a push button, a potentiometer, an "encoder" or a little joystick.

The invention, within its essentiality, can be put into practice in other embodiments that differ only in detail from that indicated solely by way of example, which will also achieve the protection that collect. This electronic device can then be made to diathermy with the most appropriate media, components and accessories, the component elements can be replaced by others technically equivalent, because it is all included within of the claims.

Claims (17)

1. Diathermy apparatus, characterized by comprising an enveloping body, manually manageable, equipped inside it with the power supply means and the electronic means generating the radiofrequency pulses, connected to two active metal electrodes adjacent to each other, for application to the subcutaneous zone comprising the defect to be treated, said electrodes occupying separate areas of the surface of the enclosure body of the apparatus, determining a unique intermediate zone between both electrodes intended for application to the skin defect to be treated. 2. Diathermy apparatus according to claim 1 because the power supply means comprise batteries rechargeable or dry batteries. 3. Diathermy apparatus according to claim 1 because the power supply means are connected to the power grid using a flexible cable. 4. Diathermy apparatus according to claim 1, characterized in that the electrodes have no coating and apply the radiofrequency pulses to the cutaneous surface by conduction. 5. Diathermy apparatus according to claim 1, characterized in that the electrodes have a substantially flat surface. 6. Diathermy apparatus according to claim 1, characterized in that the electrodes have a convex surface, with convexity directed outwards. 7. Diathermy apparatus, according to claim 1, characterized in that the body of the apparatus has an ergonomic handle and button, allowing it to be held and operated with only one hand. 8. Diathermy apparatus according to claim 1, characterized by presenting means for regulating the output power with an output power indicator visible on the body of the apparatus. 9. Diathermy apparatus according to claim 8, characterized in that the output power indicator is made by means of an LCD screen with segment digits or with LEDs. 10. Diathermy apparatus according to claim 1, characterized by having a control on the body of the apparatus operable with the same holding hand of the apparatus for the variation of the output power. 11. Diathermy apparatus according to claim 1, characterized in that the electrodes can be graduated in their separation distance. 12. Diathermy apparatus according to claim 1, characterized in that the electrodes can be graduated at the angle that they form with each other. 13. Diathermy apparatus according to claim 1, characterized in that it comprises several electrodes in alignment in the enclosure body of the apparatus, so that any two of said electrodes are connectable with the radiofrequency pulse generating means, to vary the width of the application area 14. Diathermy apparatus according to claim 1, characterized in that the output power can be regulated by varying the amplitude of the output signal. 15. Diathermy apparatus according to claim 1, characterized in that the output power can be regulated by modulating the same output signal by means of a pulse or pulse signal. 16. Diathermy apparatus according to claim 1, characterized in that one of the electrodes has an insulating layer. 17. Diathermy apparatus according to claim 1, characterized in that both electrodes have an insulating layer.