JP2019092952A - Wearable potential therapeutic instrument - Google Patents

Abstract

To provide a potential therapeutic instrument that enables moving while performing potential treatment.SOLUTION: A potential therapeutic instrument comprises a therapeutic instrument body 11 for generating and supplying a high-voltage potential, and an energizing mat 2 attached with a therapeutic instrument body and for applying the high voltage potential generated in the therapeutic instrument body to a therapy target. The therapeutic instrument body comprises a battery, a DC/DC converter for converting a power supply supplied from the battery into a direct current power supply of a predetermined voltage, voltage control means for generating a waveform of the predetermined voltage by using the DC power supply supplied from the DC/DC converter, and high-voltage potential generating means for converting the power supply being output from the voltage control means into the high voltage to output it to the energizing mat. The energizing mat has an insulating region 4 for installing the therapeutic instrument body and an energization area 3 for receiving the supply of the potential from the therapeutic instrument body and applying the potential to the therapy target, and has locking means 7 being deformable in a cylindrical shape and maintaining a state of being deformed in the cylindrical shape.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electric potential treatment apparatus which enables electric potential treatment by applying high voltage direct current or alternating electric potential to a treatment object, and more specifically, performing electric potential treatment with the treatment device attached to the treatment object The invention relates to a wearable electric potential treatment device.

  BACKGROUND ART Conventionally, as a device for treating headache, shoulder stiffness, insomnia and the like, a high pressure electric potential treatment device having an effect of improving blood circulation and improving physical constitution has been used. And, this high voltage electric potential treatment device is a device which applies high voltage electric potential to the body to be treated, and by performing treatment using this high pressure electric potential treatment device, the blood circulation becomes better and the constitution is improved. Can be expected to be effective in eliminating headaches, stiff shoulders and sleeplessness.

  However, the high voltage electric potential treatment device converts the supplied power supply voltage to a high voltage and outputs it, and as a method of converting to this high voltage conventionally, a large-sized transformer is used, so the entire treatment device becomes large. It had been heavy.

  Therefore, in the conventional high voltage electric potential treatment device, a method of receiving treatment while sitting using a dedicated chair, or placing on a futon, and performing treatment while sleeping is performed. Therefore, with the conventional electric potential treatment device, it was necessary to concentrate on the treatment when performing the treatment, and it was not possible to perform the treatment while performing household affairs and the like.

  In this respect, in the past, the present applicant controls the voltage of the input power supply to a preset voltage, and then converts the power supply into high voltage direct current or alternating current to use the power supply voltage without using a large transformer. Although a digital type high voltage electric potential treatment device that can be converted to high pressure has been proposed, even in this case, since the power cord or the like is provided, it is difficult to treat while performing housework and the like.

  Also, recently, potential treatments for pets such as dogs and cats have begun to be considered, but as mentioned above, conventional potential treatment devices are installed in chairs etc. because the entire treatment device is large and heavy. It is impossible to use effective potential treatment with animals such as dogs and cats, even if they are treated on a chair or bed, because they move quickly. .

JP, 2005-40241, A Japanese Patent Application Publication No. 2007-117606 JP 2012-24128 A JP, 2017-6422, A

  Therefore, an object of the present invention is to provide a wearable electric potential treatment device that enables electric potential treatment while performing household chores etc. and electric potential treatment to a pet.

The wearable electric potential treatment device of the present invention is a wearable electric potential treatment device used for applying electric potential at high pressure to a treatment subject to perform electric potential treatment,
A treatment unit body for supplying a high voltage potential;
An electrification mat attached to the treatment device body for receiving a supply of a high voltage potential generated by the treatment device body to perform potential treatment on a treatment subject;
The treatment device body is
With a battery,
A DC / DC converter for converting DC power supplied from the battery into DC power of a predetermined voltage;
Voltage control means for generating and outputting a waveform of a predetermined voltage using a DC power supply supplied from the DC / DC converter;
High voltage potential generating means for converting a power supply converted to a predetermined voltage by the voltage control means into high voltage direct current or alternating current and outputting the same to the conductive mat;
And control means for controlling the operation of the voltage control means and the high voltage potential generation means,
The voltage control means
A transistor supplied with direct current of a predetermined voltage as a main power source from the battery;
A control IC for switching the transistor according to a control signal from the control means;
And a smoothing circuit that receives an input of a power supply from the transistor and generates the input power supply to a predetermined voltage.
The high voltage potential generating means
A pulse conversion circuit for converting the output of the voltage control means into a pulse, and a high voltage generation circuit having a transformer for converting a pulse waveform converted by the pulse conversion circuit into a high voltage;
A multiplier circuit for multiplying the output waveform of the high voltage generation circuit by a predetermined factor;
When adding an alternating current to the treatment target, alternately output each signal of the plus waveform and the minus waveform multiplied by a predetermined ratio by the multiplication circuit, and combine the output zero point of the plus waveform and the minus waveform. An output control circuit that generates and outputs an alternating current waveform, and generates and outputs a direct current waveform using a negative side waveform multiplied by a predetermined factor when applying direct current to a treatment target;
When an alternating current is added to the object to be treated, the positive and negative waveforms alternately multiplied by a predetermined ratio by the multiplication circuit are output alternately, and the alternating current waveform is synthesized by combining the output positive waveform and the negative waveform with the zero point. An output control circuit for generating and outputting a direct current waveform using a minus side waveform multiplied by a predetermined factor by a multiplying circuit when generating and outputting a direct current;
The conductive mat has an insulating region for installing the treatment device main body, and a conductive region for receiving potential supply from the treatment device main body and applying a potential to the object to be treated, and is deformed into a cylindrical shape It is characterized in that it has a locking means which is flexible and maintains the cylindrically deformed state.

  In the wearable potential treatment device of the present invention, a treatment device main body that supplies a high voltage potential is attached to a current-carrying mat. The current-carrying mat has an insulating area and a current-carrying area, and the treatment apparatus main body is installed in the insulating area, and the current-carrying area receives the supply of electric potential from the treatment apparatus main body installed in the insulating area. It is used to apply a potential. Furthermore, the current transmission mat has a locking means that is deformable in a cylindrical shape and maintains a deformed state in a cylindrical shape. Therefore, it is possible to perform electric potential treatment while performing household chores, etc., and electric potential treatment to pets by winding the conduction mat around the arms and torso. At this time, in the wearable electric potential treatment device of the present invention, a battery is used as a power source of the treatment device main body, and since the electric wire does not come out of the treatment device, it can move with the treatment device main body attached. Furthermore, the pet can move freely while treating it.

FIG. 1 is a plan view of an embodiment of a wearable potential treatment device of the present invention. FIG. 1 is a side view of an embodiment of a wearable potential treatment device of the present invention. It is a figure for demonstrating the effect | action of the Example of the mounting | wearing type | mold electric potential treatment apparatus of this invention. It is the block diagram which showed the circuit structure of the treatment device main body in the Example of the mounted | worn-type electric potential treatment device of this invention. It is the block diagram which showed the structure of the voltage control means in the Example of the mounting | wearing type | mold electric potential treatment apparatus of this invention. It is the block diagram which showed the structure of the high voltage | pressure electric potential generation means in the Example of the mounting | wearing type | mold electric potential treatment apparatus of this invention. It is a flowchart for demonstrating the effect | action of the Example of the mounting | wearing type | mold electric potential treatment apparatus of this invention. It is an output example of the voltage control means in the Example of the mounting | wearing type | mold electric potential therapeutic device of this invention. It is an example of an output of a high voltage generation circuit in an embodiment of a wearable electric potential treatment apparatus of the present invention. It is an example of an output of the multiplication circuit in the example of the wearing type electric potential therapeutic device of the present invention. It is the figure which showed the control waveform of the output control circuit in the Example of the mounting | wearing type | mold electric potential therapy apparatus of this invention. 11 is an output example of the output control circuit in the embodiment of the wearable potential treatment device of the present invention,

  The wearable potential treatment device of the present invention comprises a treatment device main body for supplying a high voltage potential and a current-carrying mat to which the treatment device main body is attached. The current-carrying mat is used to perform potential treatment on the treatment target by receiving the supply of the high voltage potential generated in the treatment unit main body, and an insulating area for installing the treatment unit main body and the potential of the treatment unit main body It has an electrification region for receiving supply and applying an electric potential to a treatment object, and has a locking means which is deformable in a cylindrical shape and maintains a deformed state in a cylindrical shape.

  Further, the treatment device main body is provided with a battery as a power source, and a DC / DC converter for converting a DC power source supplied from the battery into a DC power source of a predetermined voltage is connected to the battery.

  The DC / DC converter is connected to voltage control means for controlling the voltage of the power supply converted to direct current of a predetermined voltage in the DC / DC converter to a predetermined voltage.

  Further, the voltage control means is connected to high voltage potential generating means for converting a power source transformed to a predetermined voltage in the voltage control means into high voltage direct current or alternating current and outputting the same.

  Further, the wearable potential treatment apparatus of the present invention is provided with control means for controlling the operation of the voltage control means and the high voltage potential generation means.

  The voltage control means includes a transistor to which direct current of a predetermined voltage is supplied from the DC / DC converter, a control IC for switching the transistor according to a control signal from the control means, and a power supply from the transistor. A smoothing circuit is provided which receives an input and generates an input power supply to a predetermined voltage, and generates and outputs a waveform of a predetermined voltage using direct current supplied from a DC / DC converter with this configuration. There is.

  Further, the high voltage potential generation means has a high voltage generation circuit, and the high voltage generation circuit includes a pulse conversion circuit for converting the output of the voltage control means into a pulse and a pulse shape converted by the pulse conversion circuit. It has a transformer that converts the waveform to high voltage.

  A multiplier circuit is connected to the high voltage generation circuit, and the multiplier circuit multiplies the output waveform of the high voltage generation circuit by a predetermined factor.

  Next, an output control circuit is connected to the multiplying circuit, and when adding an alternating current to the object to be treated, the output control circuit converts the respective signals of the plus waveform and the minus waveform multiplied by a predetermined factor by the multiplying circuit. The alternating waveform is generated by alternately combining the zero points of the alternately output waveforms to generate and output an alternating current waveform, and when adding a direct current to the treatment target, the negative side waveform multiplied by a predetermined ratio by the multiplying circuit Function to generate and output a direct current waveform.

  Here, the locking means provided in the current-carrying mat may be any means as long as it is a means for maintaining the current-carrying mat in a cylindrical shape, but it is preferable to use, for example, a surface fastener.

  An embodiment of a wearable potential treatment device (hereinafter simply referred to as "potential treatment device") of the present invention will be described with reference to the drawings. Fig. 1 is a plan view of the potential treatment device of the present embodiment. FIG. 3 is a side view of an example potential treatment device, and FIG. 3 is a view for explaining how to use the potential treatment device of the present example.

  And in the figure, 1 is an electric potential treatment apparatus of a present Example, and the electric potential treatment apparatus 1 of a present Example has a conduction mat. Then, a treatment device main body for generating a high voltage potential and supplying the generated high voltage to the conduction mat is attached on the conduction mat, and by attaching the conduction mat to the body, housework and the like can be performed. It is possible to perform potential treatment while performing, and potential treatment for pets.

  That is, in the figure, 2 is a conductive mat, and in the present embodiment, the conductive mat 2 has a rectangular shape, a copper foil is provided on a vinyl cover, and a resin sheet is further stacked thereon. The entire sheet is conductive, with the resin sheet side as the surface side.

  In addition, an insulator is provided at the central portion on the surface side of the conductive mat 2, and the region provided with the insulator is an insulating region 4, and the periphery of the insulating region 4 is a conductive region 3.

  Next, in the figure, 11 is a therapeutic device main body. That is, in the potential treatment apparatus 1 of the present embodiment, the treatment apparatus main body 11 is mounted on the insulating area 4, and the high voltage generated in the treatment apparatus main body 11 can be supplied to the conduction area 3 There is. In the figure, 6 is the ground.

  Next, in FIG. 3, the current-carrying mat 2 is deformable in a cylindrical shape with the treatment device main body 11 up, whereby the potential treatment device 1 of this embodiment is wound around an arm or torso. By putting it on, potential treatment while doing housework is possible. In addition, electric potential treatment can be performed on moving animals such as dogs and cats by moving it around the body of pets such as dogs and cats, and electric potential treatment on pets that was impossible with conventional electric potential treatment devices. It is possible to

  In FIG. 1, reference numeral 7 denotes a surface fastener. That is, in the present embodiment, a surface fastener 7 as a locking means is provided at the end portion on the front surface side of the conduction mat, and when the conduction mat 2 is deformed into a cylindrical shape on the back surface side, A material that can be locked to the surface fastener 7, such as a surface fastener, is provided in a wide area at a location where the surface fastener 7 faces. Therefore, it is possible to maintain the conductive mat 2 in a cylindrical shape by the surface fastener 7, and a wide area where the surface fastener 7 faces on the back surface of the current transmission mat can be maintained. Since the material that can be locked to the surface fastener 7 is provided, it is possible to freely adjust the diameter when the state of being deformed into the cylindrical shape is maintained. However, the locking means need not necessarily be surface fasteners, and any means may be used as long as they can be locked to each other, and it is also possible to maintain a state of being deformed into a cylindrical shape by a tape or a cord. .

  Next, the therapeutic device main body 11 will be described with reference to the drawings. FIG. 4 is a block diagram for explaining the circuit configuration of the potential treatment device 1 of this embodiment. Then, it is possible to switch between direct current and alternating current based on the selection of the treatment target.

  That is, the potential treatment apparatus 1 of the present embodiment is provided with the microcomputer 12 as a control means, and in the present embodiment, the microcomputer 12 includes the power switch 31 and the mode switch 32 for selecting AC and DC and various settings. , A start switch 33 for starting treatment, a display means 34, a speaker 35 as a voice generation means, etc. are connected, and a mode switch while referring to a display on the display means 34, a buzzer by the speaker 35, etc. The selection of the alternating current and the direct current, the voltage value and the like can be set by the reference numeral 32. The voltage value that can be set in the present embodiment is about 1,000 V at maximum.

  Next, the circuit configuration of the electric potential treatment device 1 of this embodiment will be described. In FIG. 4, reference numeral 13 denotes a battery as a power source. That is, in the potential treatment device 1 of the present embodiment, a battery is used as a power source, and the battery 13 is mounted on the treatment device main body 11. Therefore, the electric wire for supplying the power does not get out of the electric potential treatment device 1 and get in the way, so it can move with the electric potential treatment device 1 attached. Furthermore, even when attached to a pet, the pet It is possible to move around freely.

  Next, the battery 13 is connected to a main power DC / DC converter 14 and a control power DC / DC converter 15. In the control power DC / DC converter 15, DC power supplied from the battery 13 is used. The power supply is converted to a direct current of 3.3 V, and the converted direct current of 3.3 V is supplied to the microcomputer 12.

  On the other hand, in the main power DC / DC converter 14, the DC power supplied from the battery 13 is converted into an arbitrary voltage, and the power converted into the arbitrary voltage is regarded as the main power. Then, the main power is supplied to the voltage control means 16 connected to the main power supply DC / DC converter 14. In the voltage control means 16, the main power supplied from the main power DC / DC converter 14 is , Converted to any value.

  Then, in the present embodiment, under the control of the microcomputer 12, the voltage control means 16 converts the main power output from the main power DC / DC converter 14 into an arbitrary voltage and outputs it. That is, in the case of outputting an alternating current, the direct current is converted into a waveform that is a result of decomposition of a sine wave and output, and in the case of outputting a direct current, a direct current is output. FIG. 8 is a diagram showing an output waveform of the voltage control means 16 in the case of outputting an alternating current.

  Here, assuming that the direct current 24 V is supplied to the voltage control means 16 as the main power supply, the configuration of the voltage control means 16 will be described with reference to FIG. 16 has a first transistor 17 and a second transistor 18, and both of the first and second transistors 17 and 18 are FETs (field effect transistors, hereinafter simply referred to as "transistors"). It is used.

  The main power of 24 V DC supplied from the main power supply DC / DC converter 14 is supplied to the first transistor 17, and the output of the first transistor 17 is supplied to the smoothing circuit 19 and the second transistor 18. And the output of the second transistor 18 is to flow to ground.

  Further, a first control IC 20 and a second control IC 21 are connected to the gates of the first transistor 17 and the second transistor 18, respectively. The first control IC 20 and the second control IC 21 are connected to the microcomputer 12, receive control signals from the microcomputer 12, and receive the gates of the first transistor 17 and the second transistor 18. Power supply, thereby switching the first transistor 17 and the second transistor 18.

  Therefore, in the high voltage electric potential treatment apparatus of the present embodiment, the switching of the first transistor 17 is finely performed by finely controlling the ON and OFF time of the control signal supplied from the microcomputer 12, thereby the first It is possible to control the supply time of the main power output from the transistor 17 and control the voltage of the power output from the smoothing circuit 19 to an arbitrary voltage.

  Then, as a switching method of the first transistor 17, in the present embodiment, the control signal from the microcomputer 12 is supplied to the first control IC 20, and the control signal is not supplied to the second control IC 21. The main power supply DC 24 V is output from the first transistor 17, while the control signal from the microcomputer 12 is supplied to the second control IC 21 and the control signal is supplied to the first control IC 20. Otherwise, the output from the first transistor 17 is turned off and the second transistor 18 is connected to ground.

  Therefore, for example, taking the output of the first transistor 17 as an example, if 50% is turned on and 50% is turned off, the output from the smoothing circuit 19 is 12 V and 25%. When 75% is turned on and 75% is turned off, the output from the smoothing circuit 19 is 6V, and when 75% is turned on and 25% is turned off, the output from the smoothing circuit 9 is 18V become. Therefore, in the present embodiment, by controlling the control ICs 20 and 21 to switch the transistors 17 and 18, it becomes possible to convert 24 V of the main power supply to an arbitrary voltage. Further, in the potential treatment apparatus of the present embodiment, unlike the conventional high voltage potential treatment apparatus, a ladder circuit is not used, and the digital signal from the microcomputer 12 is supplied to the control ICs 20 and 21 without being converted to analog. Since the control of the voltage is performed in digital, fine control of the voltage is possible, and since the heat generation is small, the heat sink can be made small, and the weight reduction of the device can be achieved.

  In the figure, reference numeral 22 denotes a DC / DC converter for reliably outputting 24 V DC of the main power supply from the transistor 17. The DC / DC converter 22 generates 29 V DC as a control voltage, and this 29 V DC is generated. Is supplied to the first IC 20 to enable the direct supply of 24 V DC of the main power supply to be reliably output. That is, when the output from the first IC 20 is not about 29 V DC, it is difficult to output 24 V DC from the first transistor 17 due to the influence of various resistances and the like. Therefore, in the present embodiment, 29 V DC is generated as a control voltage, and the 29 V DC is supplied to the first IC 20 so that 24 V DC of the main power supply can be reliably output.

  Next, in FIG. 4, reference numeral 23 denotes a high voltage potential generating means. That is, in the present embodiment, the high voltage potential generating means 23 is connected to the voltage control means 1, and the output from the voltage control means 16 is converted into high voltage in the high voltage potential generating means 23.

  Here, the high voltage potential generating means 23 will be described with reference to FIG. 6. FIG. 6 is a block diagram for explaining the configuration of the high voltage potential generating means 23. In the figure, the high voltage potential generating means 23 is shown. Has a high voltage generation circuit 24 for setting the waveform generated by the voltage control means 6 to a high voltage.

  Here, the high voltage generation circuit 24 will be described. In the present embodiment, the high voltage generation circuit 24 converts the output from the voltage control means 16 into a pulse shape under the control of the microcomputer 12. have.

  A transformer 26 is connected to the pulse conversion circuit 25. In the transformer 26, the voltage converted into a pulse in the pulse conversion circuit 25 is expanded by about 100 times. FIG. 9 is a waveform showing an output example of the high voltage generation circuit 24. The high voltage generation circuit 24 converts the output from the voltage control circuit 16 into a pulse shape, and this voltage is multiplied by 100. Output to the multiplier circuit.

  Next, in the figure, reference numeral 27 denotes a multiplier circuit. In this embodiment, the multiplier circuit 27 has a plus side multiplier circuit 27a and a minus side multiplier circuit 27b. When an alternating current is to be output, the voltage on the positive side of the output of the high voltage generation circuit 24 is expanded in the positive side multiplication circuit 27a, and the output of the high voltage generation circuit 24 in the negative side multiplication circuit 27b. The negative voltage of is expanded and output. An output example of the multiplying circuit 27 is shown in FIG. 10, (a) is an output example of the plus side multiplying circuit 27a, and (b) is an output example of the minus side multiplying circuit 27b.

  In the present embodiment, the multiplier circuit 27 uses a Cockcroft-Walton circuit, and in the multiplier circuit 27, the output of the high voltage generation circuit 24 is converted to a voltage of about three times.

  Next, an output control circuit 28 having a plus side output control circuit 28a and a minus side output control circuit 28b is connected to the multiplying circuit 27, and the plus side output control circuit 28a is connected to the plus side multiplying circuit 27a. The negative side output control circuit 28b is connected to the negative side multiplier circuit 27b, and the output of the multiplier circuit 27 is supplied.

  The plus side output control circuit 28a and the minus side output control circuit 28b alternate the outputs of the plus side multiplying circuit 27a and the minus side multiplying circuit 27b based on the control by the microcomputer 12 when adding alternating current to the treatment target. Output to generate a control waveform. That is, the control waveforms generated by the plus side output control circuit 28 a and the minus side output control circuit 28 b are outputs every other night. On the other hand, when applying direct current to the treatment subject, the output control circuit 28 outputs the output waveform of the multiplier circuit 27b on the negative side.

  Next, when adding an alternating current to the object to be treated, the output control circuit 28 generates and outputs an alternating current waveform by synthesizing a zero point for the generated control waveform. Note that FIG. 11 shows the control waveform, and (a) shows a control waveform of the plus side output control circuit 28 a and (b) shows a control waveform of the minus side output control circuit 28 b. Further, FIG. 12 shows an AC waveform generated by synthesizing the zero points of the control waveform.

  Then, the output of the output control circuit 28 is supplied to the current-carrying mat 2, whereby it is possible to supply a high voltage potential to the object to be treated via the current-carrying mat 2 to perform potential treatment.

  Next, the operation of the high voltage electric potential treatment device 1 of the present embodiment configured as described above will be described using the flowchart of FIG. 7; in the state where the power switch 31 is turned on After setting the type of direct current, voltage value, etc., when the start switch 33 is turned on in step 2, the electric potential treatment device 1 of this embodiment starts to operate.

  That is, in step 3, the DC power output from the battery 13 is converted into an arbitrary voltage in the main power DC / DC converter 14 and supplied to the voltage control means 16 as the main power, while the control power is supplied. In the DC / DC converter 15, the DC power output from the battery 13 is converted to 3.3 VDC and supplied to the microcomputer 12.

  Next, the main power supply supplied to the voltage control means 16 is controlled to a desired voltage in the voltage control means 16 in step 4. That is, as described above, the control signal is output from the microcomputer 12 to the control ICs 20 and 21 according to the user's selection, and the control ICs 20 and 21 perform switching of the transistors 17 and 18 accordingly. Thus, the voltage as the main power supply is converted into a desired voltage and output. At this time, in the case of outputting an alternating current, as shown in FIG. 8, a positive side waveform similar to a sine wave of a predetermined voltage is generated and output from the voltage control means 16.

  At this time, as described above, in the present embodiment, the voltage control means 16 is provided with the DC / DC converter 22. In the DC / DC converter 22, a control voltage is generated and the control voltage is calculated. Since the voltage is supplied to the first IC 20, the voltage of the main power supply is reliably output from the transistor.

  Next, the main power supply controlled to a desired voltage by the voltage control means 16 is supplied to the high voltage potential generating means 23 and converted to a high voltage in the high voltage potential generating means 23. That is, in step 5, the output from the voltage control means 16 is converted into pulses in the pulse converter circuit 25. Next, in step 6, the voltage converted into pulses is expanded about 100 times in the transformer 26. Output. FIG. 9 is an output example of the transformer 26.

  Then, the power supply boosted by about 100 times by the transformer is multiplied by about 3 in step 7. That is, when outputting an alternating current, the voltage on the positive side is expanded in the positive side multiplier circuit 27a, and the voltage on the negative side is expanded in the negative side multiplier circuit 27b, as shown in FIG. Each of the plus waveform and the minus waveform is output, and when a direct current is output, the minus side multiplier circuit 27b functions to expand the minus side voltage and output it.

  Next, when an alternating current is to be added to the object to be treated, in step 8, the output control circuit 28 enlarges the positive waveform and the negative waveform, which are output about three times by the multiplying circuit 27, as shown in FIG. Are alternately output to generate control waveforms, and furthermore, for each control waveform, an AC waveform as shown in FIG. Output to 2. Further, when a direct current is applied to the object to be treated, the output of the multiplier circuit 27 b on the negative side is output to the conduction mat 2 by the conducting wire 5. In this embodiment, when outputting the maximum of 1,000 V, the voltage control means 16 generates a voltage of about 3.33 V, converts it to a voltage of 333 V in the high voltage generation circuit, and It is supposed to generate a voltage of about 1,000V.

  As described above, in the potential treatment apparatus of the present embodiment, it is possible to attach the treatment apparatus main body 11 for supplying high voltage potential to the conduction mat 2 and apply the high pressure potential generated by the treatment apparatus main body 11 to the treatment target from the conduction mat 2 Since the current-carrying mat 2 can be deformed into a cylindrical shape and the state can be maintained, by winding the current-carrying mat 2 around the arm or the trunk, electric potential treatment while performing household chores, etc., to a pet Potential treatment can be performed. At this time, in the potential treatment apparatus of the present embodiment, since the battery is used as a power source, no electric wire comes out of the treatment apparatus. Therefore, it is possible to walk freely while performing the potential treatment. Even when attached, the pet can move around freely, so that it is possible to provide effective electric potential treatment to the pet.

  Further, in the potential treatment apparatus of this embodiment, the voltage of the power supply from the battery is controlled to a preset voltage, and thereafter, the power supply is converted to high voltage direct current or alternating current, without using a large transformer. Since a digital type electric potential treatment device capable of converting the power supply voltage to a high voltage is adopted, the treatment device main body is lightened, so electric potential treatment while doing household chores etc. and electric potential treatment for pets are easily performed. It is possible.

  The potential treatment device of the present invention is lightweight and can be attached to the body, thereby enabling potential treatment while performing household chores etc. and potential treatment for pets. Applicable to

DESCRIPTION OF SYMBOLS 1 electric potential treatment device 2 electrification mat 3 electrification area 4 insulation area 5 lead 6 earth 7 surface fastener 11 medical treatment body 12 microcomputer 13 battery 14 DC / DC converter for main power supply 15 DC / DC converter for control 16 voltage control means 17 first Transistor (FET1)
18 Second transistor (FET2)
19 smoothing circuit 20 first control IC
21 Second control IC
22 DC / DC converter 23 high voltage potential generation means 24 high voltage generation circuit 25 pulse conversion circuit 26 transformer 27 frequency multiplication circuit 27a plus side multiplication circuit 27b minus side multiplication circuit 28 output control circuit 28a plus side output control circuit 28b minus side output control circuit 31 power switch 32 mode switch 33 start switch 34 display means 35 speaker

Claims (2)

A wearable potential treatment device used for applying a high voltage potential to a treatment subject to perform potential treatment,
A therapeutic unit body (11) for generating and supplying a high voltage potential;
An electrification mat (2) to which the therapeutic object is to be treated by receiving supply of the high voltage potential generated by the therapeutic device main body (11) to which the therapeutic device main body (11) is attached;
The therapeutic device main body (11) is
With the battery (13),
A DC / DC converter (14) for converting DC power supplied from the battery (13) into DC power of a predetermined voltage;
Voltage control means (16) for generating and outputting a waveform of a predetermined voltage using a DC power supply supplied from the DC / DC converter (14);
A high voltage potential generating means (23) for converting a power source converted into a predetermined voltage by the voltage control means (16) into a high voltage direct current or alternating current and outputting the same to the conductive mat (2);
Control means (12) for controlling the operation of the voltage control means (16) and the high voltage potential generation means (23);
The voltage control means (16)
A transistor (17) to which a direct current of a predetermined voltage as a main power supply is supplied from the battery (13);
A control IC (20) for switching the transistor (17) according to a control signal from the control means (12);
And a smoothing circuit (19) for receiving the input of the power supply from the transistor (17) and generating the input power supply to a predetermined voltage,
The high voltage potential generating means (23)
It has a pulse conversion circuit (25) for converting the output of the voltage control means (16) into a pulse, and a transformer (26) for converting a pulse waveform converted by the pulse conversion circuit (25) into a high voltage A high voltage generation circuit (24),
A multiplication circuit (27) for multiplying the output waveform of the high voltage generation circuit (24) by a predetermined factor;
When an alternating current is added to the object to be treated, each signal of the plus waveform and minus waveform multiplied by a predetermined ratio by the multiplying circuit (27) is alternately output, and the zero point of the output plus waveform and minus waveform To generate and output an AC waveform, and when adding a direct current to the treatment target, an output that generates and outputs a direct current waveform using a negative side waveform multiplied by a predetermined factor in the multiplication circuit (27) And a control circuit (28),
The electrically conductive mat (2) has an insulating area (4) for installing the therapeutic device main body (11), and is supplied with a potential from the therapeutic device main body (11) to apply a potential to the object to be treated. A wearable electric potential treatment device characterized in that it has a current-carrying area (3), and is capable of being deformed into a cylindrical shape and having a locking means (7) for maintaining a state of being deformed into a cylindrical shape.   The wearable electric potential therapeutic device according to claim 1, wherein the locking means (7) is a hook-and-loop fastener.

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