KR200377009Y1 - A complex medical pad apparatus which have ultrasonic transducers, electric stimulative carbon pads, and laser exciters with laser diodes. - Google Patents

Abstract

The present invention is a device characterized in that the pad of the electrical stimulator attached to the abdomen, arms and legs of the human body, the ultrasonic transducer of the ultrasonic therapy device and the laser diode irradiation unit for generating the laser is mounted on the silicone rubber pad which is less harmful to the human body. . If each device is used to stimulate the human body for about 20 minutes, so if you apply the above three stimulation will require 60 minutes of stimulation time. When the pad of the present invention is used, three stimuli are simultaneously driven and used to reduce stimulation time in 20 minutes. The pad of the present invention has an exterior using silicone rubber, and is easily attached to the curved surface of the abdomen, arms, and legs of the human body to be banded so that the human hand can use it during electric stimulation, ultrasound therapy, and laser diode irradiation. It is a medical pad characterized by the convenience of attaching and using without inconvenience.

Description

A complex medical pad apparatus which have ultrasonic transducers, electric stimulative carbon pads, and laser exciters with laser diodes.

In general, the electrical stimulator structure is an electrical signal generated by the electrical signal generator 1 as shown in Figure 1 supplies an electrical signal to the silicon carbon pad 4 through the output line 3 and the electrical signal output port (5). . The silicon carbon pad is composed of carbon mixed with silicon rubber, so that the silicon carbon pad is electrically conductive. Two silicon carbon pads (4) is to apply the electrical stimulation (6) to the part of the human body (2).

The structure of the silicon carbon pad is composed of a carbon rubber that can be combined with a metal-removable socket 14 connected to an electrical signal transmission wire 13 and a contact carbon rubber 10 plate in which carbon is mixed with silicon rubber as shown in FIG. 2. The detachable socket 12 is formed to be a configuration. In order to insulate and fix the sheath of the carbon rubber part, the sheath 11 made of purely silicon rubber, which is not electrically conductive, is formed, thereby obtaining the desired silicon carbon pad structure. Figure 3 shows the configuration of a commonly used ultrasound therapy device. The ultrasonic therapy device generates a signal having a frequency corresponding to the frequency generated by the continuous wave oscillator 20 on the ultrasonic piezoelectric body 21. When the generated signal is applied to the ultrasonic piezoelectric body through the ultrasonic piezoelectric driving wire 22, the ultrasonic wave 25 is generated. The ultrasonic transducer 24 to which the ultrasonic piezoelectric body 21 and the exterior and the driving wire 22 are connected is configured as shown in FIG. 3. The ultrasound therapy device is configured as shown in FIG. 3 and the head of the ultrasound transducer is held and moved during the treatment time by holding the head by hand, thereby achieving the therapeutic purpose.

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FIG. 4 relates to a configuration of a laser irradiator for irradiating a human body, which transmits a signal generated by the laser diode driver 30 and the driver 30 to generate an electrical signal corresponding to the laser output to be transmitted to the laser diode 31. The laser diode driving wire 32 is formed. The laser diode 31 is located in the laser irradiator 33 and the laser 35 is irradiated to the front through the laser output port 34. The laser irradiator as shown in FIG. 4 is used in monochromatic, narrow band, and low level, and the effect of laser can be seen as a skin regeneration effect, which promotes blood circulation and enzymes. Activation and increased collagen production have the effect of skin regeneration.

Ultrasonic stimulation and ultrasonic stimulation without the help of human hands are made by combining the ultrasonic transducer and laser irradiator with the silicone rubber pad which are operated by human hands independently of the conventional silicone rubber pad of the electro-stimulation treatment device used alone. In addition, the laser stimulation is characterized by the present invention to reduce the treatment time by giving three stimulation at the same time and a convenient configuration without using the hand.

In the present invention, since various parts of the human body have a curved shape, it is characterized by having the smoothness of attachment by constructing the exterior with silicone rubber in consideration of the sizes of the three magnetic pole magnetic poles.

1. Configuration

The configuration of the present invention is to attach to the human body as shown in Fig. 5 to the silicon high plate 40, a plurality of electrical stimulation carbon rubber 10, a plurality of ultrasonic transducers 24 and a plurality of laser irradiator 33 Consists of a fixing connector 45 to configure and to attach it to the human body. A plurality of electrical stimulation carbon rubbers and driving wires of the ultrasonic transducer and the laser diode are characterized in that each signal is supplied through the signal transmission line 44. The structure of the silicon rubber plate as shown in FIG. As shown in Fig. 6, the lower silicon rubber plate 40-1 in contact with the human body and the upper silicon rubber plate 40-2 are externally protected to protect the electrical signal wiring. The carbon rubber 10 is manufactured by adding carbon to the silicone rubber. To produce a silicone rubber and by adjusting the synthesis ratio of carbon and silicone rubber, it is possible to produce a carbon rubber 10 having a resistance of tens of ohms to several kilos of ohms. The electric signal connecting wire is formed in the carbon rubber by inserting the electric wire when the carbon rubber is manufactured. The preparation of the present invention prepares the carbon rubber in which the upper and lower silicon rubber plates and the driving wire are connected. The drive wires for the transducer and the laser irradiator are connected to the signal transmission line 44, and the carbon rubbers and the carbon rubber drive wires are also connected to the signal transmission line 44. The upper and lower sides of the bonding mold are prepared. The silicon rubber plate, the ultrasonic transducer, the drive wire of the laser irradiator, the signal transmission line 44 and the carbon rubber connected thereto are positioned at a fixed position of the bonding mold, and then the bonding mold is bonded to the upper silicon rubber sheet 40-2. Only the edge portion of the lower silicon rubber plate 40-1, the signal transmission line 44 entry portion, and the portion with the carbon rubber 10 are bonded to each other. The ultrasonic transducer 24 and the ray The fastening part of the low irradiator 33, the drive wires of the ultrasonic transducer, and the laser irradiator are made of a mold having no structure. The upper and lower silicon rubber plates, carbon rubber, and signal transmission line 44 prepared in the bonding mold simultaneously undergo a bonding process at a temperature of 150 to 200 degrees Celsius. After the bonding process, the ultrasonic transducer and the laser irradiator are applied to the upper and lower parts. It is connected to the drive lines prepared in the middle of the silicon rubber plate and fastened. [0025] The carbon rubber and the upper and lower silicon rubber plates are bonded to each other in detail. Referring to FIG. 9, the carbon rubber of FIG. ), The first carbon rubber 10-1, the first carbon rubber driving wire 10-100, and the upper silicon rubber plate divided into the second (10-2) and the third (10-3) carbon rubbers. Referring to the bonding method of the (40-2) and the lower silicon rubber plate (40-1) as an example, as shown in Figure 6 that the drive wire 10-100 is composed of the carbon rubber (10-1) upper and lower silicon rubber plate And the carbon rubber is placed on the lower silicone rubber sheet and bonded to the above temperature. 0-1 is bonded to the lower silicon rubber plate 40-1, and the driving wires 10-100 are connected to the signal transmission lines 44 to complete the configuration. The ultrasonic transducer 24 of FIG. As shown in FIG. 2, the first ultrasonic transducers 24-1, the second 2424 and the third 24-3 are respectively separated into ultrasonic transducers, and only the first ultrasonic transducer 24-1 is fastened to the silicon rubber plate. The method is as follows. As shown in FIG. 6, since only a portion of the upper and lower silicon rubber plates where the bonding process is completed are bonded together, the ultrasonic driving wires 22-100 of the ultrasonic transducer 24-1 are replaced by the ultrasonic transducer 24-as shown in FIG. 7. 1) by using the ultrasonic transducer fixing screw 110 and the ultrasonic transducer fixing nut 100 to connect the ultrasonic transducer (24-1) with an external jaw so that foreign matter such as water does not invade As shown in FIG. 8, the first laser irradiator 33-1 also includes a laser driving wire 32-formed in the bonding process, similarly to the structure of the ultrasonic transducer. 100) is an embodiment in which a simple fastening structure can be constructed using the laser irradiator fixing screw 210 and the laser irradiator fixing nut 200 using the external jaw of the laser irradiator.

2. Description of operation

Each of the driving wires of the electrical stimulation carbon rubber of FIG. 5 is supplied as a bundle of signal transmission lines 44 and attached to the human body to apply electrical stimulation signals to the carbon rubbers. At the same time, the driving wires of each of the ultrasonic transducers 24 are connected by a bundle of signal transmission lines 44 to generate ultrasonic waves by the ultrasonic driving wires to supply ultrasonic waves to the human body. The laser irradiator 33 is also configured in the silicon rubber plate 40 in the form of the laser irradiator 33 of FIG. 4, and each laser diode receives a signal through a laser drive wire connected by a bundle of signal transmission lines 44. Will occur. In the above operation, the carbon rubber for electrical stimulation, the ultrasonic transducer, and the laser irradiator are configured on one silicon rubber plate to generate three signals at the same time. When the above operation description is described in detail, there is an example of connecting the combined drive system 400 and the output line of the combined medical pad device used in the present invention as shown in FIG. 10. The combined drive system 400 of FIG. Is the same configuration as the continuous wave oscillator 20 for generating the ultrasonic wave 25 of FIG. 3, and the continuous wave oscillator 20-1 and the second ultrasonic wave converter for the first ultrasonic transducer 24-1 of FIG. 9. A continuous wave oscillator 20-2 for the ruler 24-2 and a continuous wave oscillator 20-3 for the third ultrasonic transducer 24-3. Since the continuous wave output from the continuous wave oscillator drives the ultrasonic transducer with two wires, respectively, the output lines (2-100, 22-200, 22-300) of the continuous wave oscillators 20-1, 20-2, and 20-3. Is output to the signal transmission line 44 through the output connector 450. The signal transmission line 44 of the complex drive system 400 of FIG. 10 is connected to the signal transmission line 44 of the complex medical cessation 40 of FIG. 9 to connect the first, second, and third ultrasonic transducers 24. -1, 24-2, 24-3) are connected to the drive wires (22-100, 22-200, 22-300) and operate. The laser diode is operated by applying a rated voltage and current similar to a general diode. As shown in FIG. 5, the plurality of laser diodes of FIG. 5 are divided into a first laser diode 33-1 and a second laser diode 33-2 as shown in FIG. 9. Have Each laser diode driving wire is configured and connected to the first laser diode driving wire 32-100 and the second laser diode driving wire 32-200, which are connected to the signal transmission line 44 of the composite pad. . As shown in FIG. 10, a first laser diode driver 30-1 and a second laser diode driver 30-2, which are driving circuits of the laser diodes, are provided in the complex driving system 400, and the first output line is the first laser diode driver 30-2. A laser diode output line 32-100 and a second laser diode output line 32-200, and the laser diode drive wires transmit signals through the output connector 450 of the hybrid drive system 400 of FIG. It is connected to the signal transmission line 44 of the composite medical pad of FIG. 9 by a line 44 and driven. The electrical stimulation carbon rubber 10 constituted in the pad formed of the silicone rubber of FIG. When divided into 1 (10-1), second (10-2), and third carbon rubber (10-3), the driving wire connected to the carbon rubber is one wire, each of the first carbon rubber driving wire ( 10-100), the second carbon rubber driving wire 10-200, and the third carbon rubber driving wire 10-300. The carbon rubber driving wires of FIG. 9 are connected to the signal transmission line 44 of FIG. 9 and to the output connector 450 of FIG. 10. The low frequency signal of FIG. 1 is generated in the complex driving system 400 of FIG. 10. The first electric signal generator 1-1 and the second electric signal generator 1-2 are provided as driving circuits, and the output of each electric signal generator is output to two output lines. As shown in FIG. 1, the electrical signal gives an electrical stimulus through two lines of the output line 3, so that when the even-numbered carbon rubber 10 is configured in the composite medical pad of FIG. 5, two carbon rubbers are divided and driven. It is a known embodiment. In the example of the present invention, since three carbon rubbers are formed, one common line is connected to each of the output lines output from the first and second electric signal generators 1-1 and 1-2 as shown in FIG. A common electrical signal driving wire 10-200 for outputting a signal, and outputting a non-common output line among the outputs of each of the electrical signal generators 1-1 and 1-2, respectively. -100), the second electric signal driving wire (10-200) is configured and connected to the signal transmission line 44 through the output connector of FIG. 10 to the respective carbon rubber through the signal transmission line 44 of FIG. Is connected to. The driving wires 10-100 of the first electric signal generator 1-1 of FIG. 10 are connected to the first carbon rubber 10-1, and the electric wires of the electric signal generators 1-1, 1-2 of FIG. The common electrical signal driving wires 10-200 are connected to the second carbon rubber 10-2. The electric signal driving wires 10-300 of the second electric signal generator 1-2 of FIG. 10 are connected to the third carbon rubber 10-3 of FIG. 9. The output of the electrical signal generator 1-1 of FIG. 10 is supplied between the first carbon rubber 10-1 and the second carbon rubber 10-2 among the carbon rubbers of FIG. 9 by the above connection. The output of the electrical signal generator 1-2 of FIG. 10 is supplied to and operated between the third carbon rubber 10-3 and the second carbon rubber 10-2. It can be seen that the complex drive system 400 of FIG. 10 and the medical complex pad device 40 of FIG. 5 are connected and operated at the same time. The present invention is limited by the embodiments and drawings of the present invention described above. In addition, various substitutions, modifications, and changes that can be made without departing from the technical details of the present invention will be apparent to those skilled in the art.

As shown in FIG. 5, a plurality of electrical stimulation carbon rubbers 10, a plurality of ultrasonic transducers 24, and a plurality of laser irradiators 33 are formed on the silicon rubber plate 40 to the human body using a fixing connector. After attaching, it is characterized in that the operation time is reduced by simultaneously supplying and operating a signal with one operation time of each operation time through the signal transmission line 44.

It is characterized in that the fixing plate attached to the human body to be attached to any part of the human body by using a flexible material such as silicone rubber.

1 is a magnetic pole configuration diagram of an electrical stimulator using a silicon carbon pad.

Figure 2 is a configuration diagram of a silicon carbon pad for electrical stimulation using a typical silicone rubber.

3 is a diagram showing the ultrasonic generation of the ultrasonic therapy device.

4 is a laser irradiation configuration diagram using a laser diode.

5 is a block diagram of a medical silicone rubber pad consisting of a plurality of ultrasonic transducers, a plurality of electro-stimulation carbon pads and a plurality of laser diodes in the present invention. Figure 7 is a configuration diagram for fastening the ultrasonic transducer to the upper and lower silicon rubber plate bonded in the present invention. Figure 8 is a configuration diagram for fastening the laser irradiator to the upper and lower silicon rubber plate bonded in the present invention. Figure 9 is a configuration diagram of the connection line of the ultrasonic transducer, the electrical stimulation carbon pad, and the laser diode in the present invention. Figure 10 is an illustration of the connection of the drive system and the output line of the composite medical pad device used in the present invention.

Claims (1)

In the configuration of a medical silicone rubber pad composed of a silicone rubber plate shape used to be attached to the abdomen and waist of the human body, In the medical silicone rubber pad, two or more low frequency generator stimulation carbon rubbers are formed by consolidating the lower silicon rubber plate, and the stimulation carbon rubber is electrically mixed with silicon rubber and carbon powder, and the electrical resistance is tens of ohms to several tens of minutes. It is composed of a plate type with electric resistance of ohm by key and connects the driving wire, The medical silicone rubber pad is composed of one or more ultrasonic transducers.The ultrasonic transducer includes an ultrasonic piezoelectric body, and when the ultrasonic transducer is used, it is surrounded by an external body such that external substances such as external water do not invade. In the stacked structure, the ultrasonic transducer is connected to the signal transmission line 44 to drive the drive lines by the output of the external continuous wave oscillator, The medical silicone rubber pad is formed by fastening at least one laser irradiator. The laser irradiator has a built-in laser diode and is enclosed with an external structure so that this material, such as external water, does not invade the inside. Drive wires of the wires to the signal transmission line 44 which can receive a signal input from an external laser diode driving device, The medical silicone rubber pad 40 of the above step is composed of an upper silicon rubber plate and a lower silicon rubber plate, and the driving wires of the electrical stimulation carbon rubber driving wires, the ultrasonic transducers, and the laser irradiators are connected to the upper and lower silicon rubber plates, respectively. Medical pad device characterized in that the signal transmission line is configured to be connected to the external drive unit.