JP5872526B2 - Potential therapy device - Google Patents

Description

  The present invention relates to an electric potential treatment device for applying electric potential treatment by applying an alternating high voltage to the body of a therapist (patient).

The electric potential treatment device applies an alternating voltage to the body of a therapist (hereinafter referred to as “living body”) to perform an electric potential treatment. However, in Patent Document 1 below, a positive voltage of an alternating voltage is applied to the living body. There is a description that an excitatory effect is brought about when applied, and a sedative effect is brought about when a negative voltage of an alternating voltage is applied to the living body.
In general, the waveform of the high voltage applied to the living body by the potential treatment device is such that a waveform having a larger negative voltage peak value than the positive voltage peak value of the AC voltage promotes the metabolism of the living body. It is desirable.

In Patent Document 1 below, in order to obtain the above-described excitatory action and sedative action, an AC voltage generator that generates an AC voltage input to the primary side of the transformer, and a secondary side of the transformer An electric potential treatment device is disclosed that includes an electric field forming unit that forms an electric field by an output AC voltage.
This AC voltage generator has a waveform generator that forms a positive and negative asymmetric waveform in which the positive voltage region in the AC voltage and the negative voltage region in the AC voltage have the same area, and the waveform generator The offset waveform set so that the peak value of the negative voltage of the AC voltage is larger than the peak value of the positive voltage is input to the primary side of the transformer.
Patent Document 1 describes that the ratio between the peak value of the positive voltage and the peak value of the negative voltage in the AC voltage can be switched in the range of 50:50 to 10:90.

Japanese Patent No. 4246664 (paragraph numbers [0011] to [0013])

  Since the conventional potential treatment device is configured as described above, the ratio between the peak value of the positive voltage and the peak value of the negative voltage in the AC voltage can be switched in the range of 50:50 to 10:90. When the ratio of the peak value is switched within the variable range of the ratio, the drop (peak to peak value) between the peak value of the positive voltage and the peak value of the negative voltage may be reduced. When the drop of the peak value is small, there is a problem that energy affecting the living body is lowered and the experience of the therapist may be reduced.

  The present invention has been made in order to solve the above-described problems, and can increase the difference between the peak value of the positive voltage and the peak value of the negative voltage in the alternating voltage, and can enhance the experience of the therapist. The purpose is to obtain a treatment device.

  The potential treatment device according to the present invention includes an AC voltage generation circuit that generates an AC voltage, and a transformer that boosts the AC voltage generated by the AC voltage generation circuit and outputs the AC voltage after the boosting. Just before the circuit controls the AC voltage generated by the AC voltage generation circuit and the waveform of the AC voltage starts to decrease from the peak value of the positive voltage, the positive voltage is superimposed on the AC voltage and the waveform peaks. Or just before the waveform of the alternating voltage starts to increase from the peak value of the negative voltage, the negative voltage is superimposed on the alternating voltage to form a trough of the waveform.

  The potential treatment device according to the present invention includes a DC voltage generation circuit that applies a DC voltage between an output terminal on the side that is not connected to the potential output terminal of the two output terminals on the secondary side of the transformer and the ground. The control circuit controls the DC voltage applied by the DC voltage generating circuit so as to adjust the ratio between the peak value of the positive voltage and the peak value of the negative voltage in the AC voltage output from the potential output terminal. It is a thing.

  The potential treatment device according to the present invention includes a DC voltage generating circuit that applies a fixed DC voltage between two output terminals on the secondary side of the transformer.

  According to the present invention, there is an effect that the difference between the peak value of the positive voltage and the peak value of the negative voltage in the AC voltage can be increased to enhance the experience of the therapist.

It is a block diagram which shows the electric potential therapeutic device by Embodiment 1 of this invention. It is explanatory drawing which shows the waveform (simulation waveform) example of the alternating voltage before forming a peak in a waveform. It is explanatory drawing which shows the waveform (simulation waveform) example of the alternating voltage after forming the peak in a waveform. It is explanatory drawing which shows the waveform (simulation waveform) example of the alternating voltage before forming a peak in a waveform. It is explanatory drawing which shows the waveform (simulation waveform) example of the alternating voltage after forming the peak in a waveform. It is a block diagram which shows the other electric potential treatment apparatus by Embodiment 1 of this invention. It is a block diagram which shows the electric potential therapeutic device by Embodiment 2 of this invention.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing an electric potential treatment device according to Embodiment 1 of the present invention.
In FIG. 1, a power supply circuit 2 receives supply of AC power from an AC power supply 1 and drives each device (for example, AC voltage generation circuit 3, DC voltage generation circuit 5, and control circuit 6) of a potential treatment device. This is a circuit for supplying electric power.
The AC voltage generation circuit 3 is a circuit that generates an _AC voltage VAC in accordance with an AC voltage control signal output from the control circuit 6.

The step-up transformer 4 has a primary side connected to the AC voltage generation circuit 3, and a secondary output terminal 4 a connected to the potential output terminal 8 via the current limiting resistor 7, and is generated by the AC voltage generation circuit 3. It boosts the AC voltage V _AC, and outputs the AC voltage V _{AC 'after} boosting the secondary side.
The DC voltage generating circuit 5 is composed of, for example, an output variable type DC power supply (hereinafter referred to as “DC variable power supply”), and the like, and the secondary of the step-up transformer 4 according to the DC voltage control signal output from the control circuit 6. This is a circuit for applying a DC voltage V _DC between the output terminal 4b on the side and the ground.

The control circuit 6 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted or a one-chip microcomputer, and controls the _AC voltage VAC generated by the AC voltage generation circuit 3 so as to have a sine waveform or rectangular waveform. Alternatively, an AC voltage having a waveform composed of a combination of a sine wave and a rectangular wave is generated, and the DC voltage V _DC applied by the DC voltage generation circuit 5 is controlled to output an AC voltage V output from the potential output terminal 8. _This is a circuit for adjusting the ratio R between the positive voltage peak value and the negative voltage peak value in _AC ′.
The control circuit 6 is a waveform of the AC voltage V _AC generated by the AC voltage generator circuit 3 immediately before the begin to decline from the peak value of the positive voltage, positive mountain superimposed to the waveform to an AC voltage V _AC voltage formed, or immediately before the waveform of the AC voltage V _AC turns to increase from the peak value of the negative voltage, and carries out a process of forming a valley of the waveform by superimposing a negative voltage to an AC voltage V _AC.
The current limiting resistor 7 is a resistor inserted between the output terminal 4a on the secondary side of the step-up transformer 4 and the potential output terminal 8 in order to limit the leakage current.
The potential output terminal 8 is connected to a conductive electrode plate housed in an energization mat (not shown). When the therapist gets on the energization mat, the AC voltage output from the potential output terminal 8 is output. V _AC 'is given to the therapist.

Next, the operation will be described.
First, the process of adjusting the ratio R between the peak value of the peak value and the negative voltage of the positive voltage at the AC voltage V _AC will be described.
First, the control circuit 6 generates an AC voltage control signal indicating an AC voltage waveform shape (for example, a sine waveform, a rectangular waveform, or a combination of a sine wave and a rectangular wave), an AC voltage frequency f, and the like. Output to circuit 3.
AC voltage generating circuit 3 receives the AC voltage control signal from the control circuit 6, generates an AC voltage V _AC in accordance with the AC voltage control signal.
The AC voltage generation circuit 3 only needs to be able to generate an _AC voltage VAC having a desired waveform shape under the instruction of the control circuit 6, and the circuit configuration of the AC voltage generation circuit 3 is not particularly limited.

Step-up transformer 4 is the primary side is connected to the AC voltage generating circuit 3, the AC voltage generating circuit 3 generates an AC voltage V _AC, and boosting the AC voltage V _AC, the AC voltage V _AC after boosting ' Is output to the secondary side.
V _AC '= K ・_VAC
Here, K is a gain of the step-up transformer 4.
In the first embodiment, the secondary but primary DC voltage generating circuit 5 to the output terminal 4b of the connected, if not connected to DC voltage generating circuit 5, an AC voltage V _AC generated by the step-up transformer 4 The ratio R between the peak value of the positive voltage and the peak value of the negative voltage at 'is not changed and is output to the potential output terminal 8.

The control circuit 6 outputs a DC voltage control signal indicating the DC voltage _VDC applied by the DC voltage generation circuit 5 to the DC voltage generation circuit 5.
For example, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage in the _AC voltage V _AC ′ is adjusted in the range of 50:50 to 0: 100, 0 V to −XV (in this case, X is V _AC A direct-current voltage control signal indicating the direct-current voltage V _DC is output to the direct-current voltage generation circuit 5.
Further, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage is adjusted in the range of 50:50 to 100: 0, the DC voltage control signal indicating the DC voltage _VDC of 0V to + XV is generated as the DC voltage. Output to the circuit 5.

Specifically, for example, in the case of using 50:50 without changing the ratio R between the peak value of the positive voltage and the peak value of the negative voltage, the direct current voltage control signal indicating the direct current voltage _{VDC of} 0V is applied to the direct current. The voltage is output to the voltage generation circuit 5.
For example, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage is used at 25:75, a DC voltage control signal indicating a DC voltage _VDC of −X / 2V is output to the DC voltage generation circuit 5. .
For example, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage is used at 0: 100, a DC voltage control signal indicating a DC voltage V _{DC of} −XV is output to the DC voltage generation circuit 5.
For example, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage is used at 75:25, a DC voltage control signal indicating a DC voltage V _DC of + X / 2V is output to the DC voltage generation circuit 5.
For example, when the ratio R between the peak value of the positive voltage and the peak value of the negative voltage is used at 100: 0, a DC voltage control signal indicating the DC voltage V _DC of + XV is output to the DC voltage generation circuit 5.

When the DC voltage generation circuit 5 receives the DC voltage control signal from the control circuit 6, it outputs the DC voltage V _DC indicated by the DC voltage control signal from the built-in DC variable power supply, thereby boosting the DC voltage V _DC . The voltage is applied between the output terminal 4b on the secondary side of the transformer 4 and the ground.
Thus, the DC voltage V _DC output from the DC voltage generating circuit 5 _'is superimposed on, by that amount, the AC voltage V _AC' AC voltage V _AC for is shifted, the positive voltage peak value and a negative voltage The ratio R with the peak value is adjusted, and the AC voltage V _AC ′ after the ratio R is adjusted is output from the potential output terminal 8.
For example, if the DC voltage V _DC is a negative voltage, the boosted AC voltage V _AC ′ is offset to the negative side according to the value of the DC voltage V _DC , and the positive voltage peak value and the negative voltage peak value are The ratio R is in the range of 50:50 to 0: 100.
On the other hand, if the DC voltage V _DC is a positive voltage, the boosted AC voltage V _AC ′ is offset to the plus side according to the value of the DC voltage V _DC , and the positive voltage peak value and the negative voltage peak value The ratio R is in the range of 50:50 to 100: 0.

Next, a process for increasing the difference between the peak value of the positive voltage and the peak value of the negative voltage in the _AC voltage VAC will be described.
Here, for convenience of explanation, the waveform of the _AC voltage VAC generated by the AC voltage generating circuit 3 is a rectangular wave, and the AC voltage V _AC ′ after the ratio adjustment is the peak value of the positive voltage as shown in FIG. It is assumed that the ratio R to the negative voltage peak value is 20:80.
In this case, the drop between the peak value of the positive voltage and the peak value of the negative voltage is about 15000V.

In the waveform of the AC voltage V _AC ′ (or the waveform of the AC voltage V _AC ) in FIG. 2, the control circuit 6 is positive immediately before the peak value of the positive voltage starts to decrease (approximately in the vicinity of time 42 to 49). An AC voltage control signal indicating that the voltage is superimposed is output to the AC voltage generation circuit 3.
This AC voltage control signal may be included in the AC voltage control signal indicating the frequency f of the AC voltage in advance and output to the AC voltage generating circuit 3, or the AC voltage control signal indicating the frequency f and the like may be You may make it output to the alternating voltage generation circuit 3 separately.

When the AC voltage generation circuit 3 receives an AC voltage control signal indicating that a positive voltage is superimposed from the control circuit 6, the waveform of the _AC voltage VAC decreases from the peak value of the positive voltage as shown in FIG. Just before (near the approximately time 42 to 49) to turn, by superimposing a positive voltage to an AC voltage _{V AC,} to form a mountain AC voltage _{V AC} waveform.
As a method for forming the mountains to the AC voltage V _AC waveforms, such technique that superimposes a harmonic wave with respect to the AC voltage V _AC square wave is considered.
In the example of FIG. 3, a voltage of about 9000 V is superimposed on the _AC voltage VAC, and as a result, the difference between the peak value of the positive voltage and the peak value of the negative voltage is about 24000 V, and the difference in peak value is Is about 9000V larger.

Here, immediately before the waveform of the AC voltage V _AC starts to decrease from the peak value of the positive voltage, by superimposing a positive voltage to an AC voltage V _AC, shows an example of forming a mountain AC voltage V _AC waveform However, immediately before the waveform of the _AC voltage VAC starts to increase from the peak value of the negative voltage, the negative voltage may be superimposed on the _AC voltage VAC to form a trough of the waveform.
In this case, for example, the control circuit 6 indicates that the negative voltage is superimposed on the waveform of the _AC voltage VAC in FIG. 4 immediately before the peak value of the negative voltage starts to increase (approximately in the vicinity of time 42 to 49). The AC voltage control signal shown is output to the AC voltage generation circuit 3.
When the AC voltage generation circuit 3 receives an AC voltage control signal indicating that a negative voltage is superimposed from the control circuit 6, the waveform of the _AC voltage VAC increases from the peak value of the negative voltage as shown in FIG. Just before (near the approximately time 42 to 49) to turn, by superimposing a negative voltage to an AC voltage _{V AC,} to form a valley to an AC voltage _{V AC} waveform.
In the example of FIG. 5, a voltage of about −9000V is superimposed on the _AC voltage VAC, and as a result, the difference between the peak value of the positive voltage and the peak value of the negative voltage is about 24000V, The head is about 9000V larger.

As is apparent from the above, according to the first embodiment, the control circuit 6 performs the positive operation immediately before the waveform of the _AC voltage VAC generated by the AC voltage generation circuit 3 starts to decrease from the peak value of the positive voltage. Is superimposed on the _AC voltage VAC to form a peak of the waveform, or just before the waveform of the _AC voltage VAC starts to increase from the negative voltage peak value, the negative voltage is superimposed on the _AC voltage VAC. Therefore, the gap between the peak value of the positive voltage and the peak value of the negative voltage in the _AC voltage VAC ′ output from the potential output terminal 8 is increased, so that the experience of the therapist is achieved. There is an effect that can be improved.

In the first embodiment, an example in which the waveform of the _AC voltage VAC generated by the AC voltage generation circuit 3 is a rectangular wave is shown, but the waveform of the _AC voltage VAC is not limited to a rectangular wave. For example, even if the waveform of the _AC voltage VAC is a sine wave or a combination of a sine wave and a rectangular wave, peaks and valleys of the waveform can be formed in the same manner as in the case of the rectangular wave.
For example, when the waveform of the _AC voltage VAC is a sine wave, the peak value of the positive voltage and the negative voltage corresponds to the peak value, and the peak value does not continue for a predetermined period as in the case of the rectangular wave. Waveform peaks and valleys are formed by superimposing a positive voltage or a negative voltage on.

  In the first embodiment, the DC voltage generating circuit 5 is connected between the output terminal 4b of the step-up transformer 4 and the ground. However, as shown in FIG. 6, the output terminal 4a of the step-up transformer 4 is shown. DC current generating circuit 5 may be connected between current limiting resistor 7 and current limiting resistor 7.

Embodiment 2. FIG.
FIG. 7 is a block diagram showing a potential treatment device according to Embodiment 2 of the present invention. In the figure, the same reference numerals as those in FIG.
The DC voltage generation circuit 11 is composed of, for example, a fixed DC power supply and the like, and a fixed DC voltage V _DC (a positive voltage peak value and a negative voltage) is connected between the output terminal 4a and the output terminal 4b on the secondary side of the step-up transformer 4. A circuit that applies a direct current voltage (V _DC ) set to an arbitrary fixed ratio in a range R of 50:50 to 0: 100 or a range of 50:50 to 100: 0. is there.

The semiconductor integrated circuit control circuit 12 implements the CPU for example, or are composed of such one-chip microcomputer, similarly to the control circuit 6 of FIG. 1, the AC voltage V _AC generated by the AC voltage generator 3 Is a circuit that generates an alternating voltage having a waveform composed of a sine waveform, a rectangular waveform, or a combination of a sine wave and a rectangular wave.
In addition, the control circuit 12 applies the positive voltage to the AC voltage immediately before the waveform of the _AC voltage VAC generated by the AC voltage generation circuit 3 starts to decrease from the peak value of the positive voltage, similarly to the control circuit 6 of FIG. superimposed on V _AC to form a mountain of the waveform, or just before the waveform of the AC voltage V _AC turns to increase from the peak value of the negative voltage, the valley of the waveform by superimposing a negative voltage to the AC voltage V _AC The process to form is implemented.
However, unlike the control circuit 6 of FIG. 1, the control circuit 12 does not perform the process of controlling the DC voltage _VDC applied by the DC voltage generation circuit 11.

In the first embodiment, the control circuit 6 controls the direct current voltage V _DC applied by the direct current voltage generation circuit 5, and the positive voltage peak value in the alternating voltage V _AC ′ output from the potential output terminal 8 is obtained. Although the adjustment of the ratio R to the negative voltage peak value has been shown, a fixed DC voltage V _DC (an arbitrary fixed ratio R between the output terminal 4a and the output terminal 4b on the secondary side of the step-up transformer 4 is shown. Even when the DC voltage generation circuit 11 for applying the DC voltage V _DC ) to be set is provided and the control circuit 12 does not control the DC voltage V _DC applied by the DC voltage generation circuit 11, it is the same as the control circuit 6 of FIG. Further, immediately before the waveform of the _AC voltage VAC generated by the AC voltage generating circuit 3 starts to decrease from the peak value of the positive voltage, the positive voltage is superimposed on the _AC voltage VAC to form a peak of the waveform, or , AC voltage V Just before _{the C} of the waveform changes to increase from the peak value of the negative voltage, by forming the valleys of the waveform by superimposing a negative voltage to the AC voltage V _AC, it is possible to obtain the same advantages as the first embodiment it can.

  In the second embodiment, the DC voltage generation circuit 11 is connected between the output terminal 4a and the output terminal 4b on the secondary side of the step-up transformer 4. However, like the DC voltage generation circuit 5 in FIG. A DC voltage generation circuit 11 may be connected between the output terminal 4b on the secondary side of the transformer 4 and the ground.

DESCRIPTION OF SYMBOLS 1 AC power supply 2 Power supply circuit 3 AC voltage generation circuit 4 Boost transformer 4a Secondary output terminal 4b of boost transformer Secondary output terminal 5,11 of boost transformer DC voltage generation circuits 6, 12 Control circuit 7 Current limiting resistor 8 Potential output terminal

Claims (3)

An AC voltage generating circuit for generating an AC voltage;
A transformer that boosts the AC voltage generated by the AC voltage generation circuit and outputs the boosted AC voltage;
The AC voltage generated by the AC voltage generating circuit is controlled, and a waveform peak is formed by superimposing the positive voltage on the AC voltage immediately before the waveform of the AC voltage starts to decrease from the positive voltage peak value. and, or, immediately before the waveform of the AC voltage starts to increase from the peak value of the negative voltage, the Rukoto and a control circuit for forming the valleys of the waveform by superimposing a negative voltage to the AC voltage, a positive voltage Potential treatment device that increases the difference between the peak value of the negative voltage and the peak value of the negative voltage . Among the two output terminals on the secondary side of the transformer, a DC voltage generating circuit for applying a DC voltage between the output terminal on the side not connected to the potential output terminal and the ground is provided.
The control circuit controls a DC voltage applied by the DC voltage generation circuit to adjust a ratio of a positive voltage peak value and a negative voltage peak value in an AC voltage output from the potential output terminal. The electric potential treatment device according to claim 1.   The potential therapy device according to claim 1, further comprising a DC voltage generation circuit for applying a fixed DC voltage between two output terminals on the secondary side of the transformer.

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