JP4126195B2 - Electrode holding sheet device for multi-channel low frequency therapy device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an electrode holding sheet device for a multi-channel type low frequency treatment device.
[0002]
[Prior art]
  Conventionally, a low frequency treatment device is known as a kind of treatment device (physical therapy device) using an electric signal. In this low frequency treatment device, a low frequency electrical signal (low frequency treatment signal) is applied between a pair of electrodes (conductors) attached to the body surface of a patient. A multi-channel low-frequency treatment device having a plurality of pairs of electrodes is also in practical use.
[0003]
  Moreover, there is an interference low frequency treatment device as a kind of low frequency treatment device. This applies a low-frequency electrical signal to one pair of electrodes, while applying a high-frequency electrical signal to the other pair of electrodes, and substantially interferes with the low-frequency electrical signal and the high-frequency electrical signal. In particular, a low-frequency electrical signal for treatment is generated.
[0004]
  As described above, in a low-frequency treatment device, a plurality of, in particular, a large number of electrodes are often mounted on the patient's body surface. In order to quickly mount many electrodes on the patient's body surface, An electrode is held on an insulating holding sheet body. As described above, when many electrodes are mounted on the holding sheet main body, each electrode can be detachably attached to the holding sheet main body in order to clean or replace the electrodes.
[0005]
[Problems to be solved by the invention]
  In order to easily attach and detach a plurality of electrodes to and from the holding sheet main body, the present applicant has developed an electrode in which the electrodes are attached to the holding sheet main body by an uneven fitting type. That is, a concave or convex portion as a locking portion is formed on the holding sheet body side, while each electrode is developed with an engaging portion composed of a convex or concave portion that is engaged with the locking portion. did. In this case, the electrode can be attached simply by pressing the electrode against the holding sheet main body, and the electrode can be removed from the holding sheet main body only by applying an external force to peel the electrode from the holding sheet main body. Is possible. And, by configuring the locking portion and the engaging portion so as to have conductivity, and connecting the energization arrangement disposed in the holding sheet body to the locking portion, from this wiring, We have developed a device that can be energized to the electrode through the locking part and the engaging part.
[0006]
  By the way, in order to improve conductivity between the electrode and the patient body surface, a plurality of electrodes are covered with a conductive sheet for improving conductivity. This conductive sheet is formed of, for example, a sponge sheet having a conductive sheet, and the conductivity is further improved by, for example, immersing water. In this case, since the engaging portion and the engaging portion constitute an energization path, when moisture of the conductive sheet adheres to the engaging mechanism, or sweat generated from the body surface of the patient adheres to the electrode, It is conceivable that an electrical signal leaks between the electrodes, and some countermeasure is desired in this respect.
[0007]
  On the other hand, for simplification of attachment and the like, it is desirable to provide only one locking portion and engaging portion constituting the locking mechanism for one electrode. In this case, when the electrode is attached to the holding sheet main body, the electrode may be inadvertently rotated around the locking mechanism. If the electrode is circular, there is no particular problem even if it rotates, but if the electrode is formed in an irregular shape such as a rectangle, for example, if the electrode rotates carelessly, the energization position to the patient is Not only is this slightly different, but when the gap between the electrodes is small, the electrodes come into contact with each other, causing a problem of leakage of electrical signals, and some countermeasure is desired in this respect.
[0008]
  The present invention has been made in view of the above circumstances.EyesSpecifically, when the locking mechanism for attaching the electrode to the holding sheet body is also used as an energization path for applying an electrical signal for treatment to the electrode, carelessly via the locking mechanism Prevent electrical signals from leakingTogether withAn object of the present invention is to provide an electrode holding sheet device for a multi-channel low-frequency treatment device that can reliably prevent a situation in which an electrode attached to a holding sheet body rotates inadvertently.
[0009]
[Means for Solving the Problems]
  in frontNoteIn order to achieve the objective, the present invention provides the following solutions. That is, as described in claim 1 in the claims,
  In an electrode holding sheet device for a multi-channel type low frequency treatment device, wherein a plurality of electrodes are provided on one surface side of an insulating holding sheet body, and the plurality of electrodes are positioned on the patient's body surface side and are attached to the patient. ,
  Each of the electrodes is detachably attached to the holding sheet body by a concave-convex fitting locking mechanism with respect to the holding sheet body,
  The locking mechanism includes a locking portion formed of a concave portion or a convex portion provided on the one surface side of the holding sheet body, and a convex portion or a concave portion provided on each of the electrodes and fitted to the locking portion. And an engaging portion.In addition, only one of the locking portion and the engaging portion constituting the locking mechanism is provided for one electrode,
  Each of the locking portion and the engaging portion has conductivity, and a current-carrying wiring to each electrode is connected to the locking portion in the holding sheet body,
  Between the holding sheet main body and each electrode, there is a seal mechanism for liquid-tightly blocking the locking mechanism from the outside when the electrode is locked to the holding sheet main body by the locking mechanism. ComposedAnd
  The seal mechanism includes a first convex seal portion that is integrally formed with the holding sheet body and surrounds the locking portion, and a second convex seal portion that is integrally formed with the electrode and surrounds the engagement portion. When the engaging portion is engaged with the locking portion, the first convex seal portion and the second convex seal portion are set to be fitted in an inner / outer dual structure. And
The first convex seal portion and the second convex seal portion each have elasticity and are formed in an annular shape centering on the locking mechanism,
Between the holding sheet body and the electrode, when the electrode is locked to the holding sheet body by the locking mechanism, the electrode is centered on the locking mechanism with respect to the holding sheet body. A detent mechanism that restricts rotation is configured,
The anti-rotation mechanism is formed on the electrode at a position that is eccentric from the engaging portion, a first fitting portion that is formed in the holding sheet body at a position that is eccentric from the locking portion, and that is formed from a concave portion or a convex portion. And a second fitting part comprising a convex part or a concave part fitted into the first fitting part,
A fitting direction between the engaging portion and the locking portion; a fitting direction between the first convex seal portion and the second convex seal portion; and the first fitting portion and the second fitting portion. Are set to be in the same direction as each other,
It is like that. Accordingly, the locking mechanism can be used also as an energization path to the electrode while facilitating the attachment and removal of the electrode from the holding sheet main body using the locking mechanism that is unevenly fitted. And the situation where the electrical signal for treatment leaks through the locking mechanism is prevented by blocking the locking mechanism liquid-tightly from the outside by the sealing mechanism.Further, the rotation preventing mechanism can prevent a situation where the electrode is inadvertently rotated with respect to the holding sheet main body.
[0010]
  A preferred mode based on the above solution is as described in claim 2 and the following claims. That is,
  The holding sheet main body may be formed with a clamping portion that cooperates with the first convex seal portion to clamp the second convex seal portion from the radial direction ( Claim2Correspondence). In this case, the first convex seal portion and the second convex seal portion are firmly adhered to each other in the radial direction by the sandwiching portion, which is preferable for further improving the sealing performance.
[0011]
  The electrode may be formed with a sandwiching portion that cooperates with the second projecting seal portion to sandwich the first projecting seal portion from the radial direction.3Correspondence). In this case, the first convex seal portion and the second convex seal portion are firmly adhered to each other in the radial direction by the sandwiching portion, which is preferable for further improving the sealing performance.
[0012]
  Each of the electrodes may have an irregular shape.4Correspondence). In this case, since the electrode has an irregular shape, it is possible to prevent inadvertent rotation of the electrode that is particularly desired to prevent inadvertent rotation.
[0013]
【The invention's effect】
According to the present invention, the locking mechanism can be used also as a current-carrying path to the electrode while facilitating attachment and removal of the electrode from the holding sheet body using a locking mechanism that is unevenly fitted. And the situation where the electrical signal for treatment leaks through the locking mechanism is prevented by blocking the locking mechanism liquid-tightly from the outside by the sealing mechanism. Further, the rotation preventing mechanism can prevent a situation where the electrode is inadvertently rotated with respect to the holding sheet main body.
  The present invention also has the following various effects. That is,
  The sealing mechanism is capable of shutting off the locking mechanism more reliably and externally by a fitting method that has a double structure inside and outside,In particularSince it has elasticity and is formed in an annular shape, the sealing performance of the sealing mechanism can be more sufficiently ensured.
  In addition, with respect to one electrode, it is possible to prevent a situation in which the electrode is inadvertently rotated by the anti-rotation mechanism while the locking mechanism is one of the minimum necessary. In particular, by performing the operation of attaching the electrode to the holding sheet main body, the concave-convex fitting in the anti-rotation mechanism is automatically completed, and by performing the operation of removing the electrode from the holding sheet main body, the anti-rotation mechanism is automatically performed. (The operation for obtaining the anti-rotation and the operation for releasing the anti-rotation function are unnecessary separately from the operation of attaching and removing the electrode). Furthermore, since the locking part is configured in an eccentric position with the locking mechanism, the locking mechanism is designed to prevent rotation while preventing excessive external force from being applied to the locking mechanism as much as possible. This is preferable.
Furthermore, since the fitting directions of the locking mechanism, the seal mechanism, and the anti-rotation mechanism are set in the same direction, the locking mechanism can be obtained by bringing the electrodes closer to the holding sheet body from the position direction. The seal mechanism and the rotation prevention mechanism can be simultaneously fitted, and the engagement mechanism, the seal mechanism, and the rotation prevention mechanism are simultaneously released by releasing the electrode from the holding sheet body. Can be made.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
  First, with reference to FIGS. 1 to 7, a basic configuration for obtaining a massage effect with a sensation of feeling as a special mode as a low-frequency treatment device using a plurality of electrode pairs will be described. Thereafter, the relationship between the plurality of electrodes and the holding sheet body that holds the electrodes will be described with reference to FIG.
[0015]
  In FIG. 1, H is a main body of a multi-channel type low frequency treatment device. The main body H is a four-channel type in the embodiment, and has a total of four output units 1 to 4. A pair of electrodes (conductors) can be connected to each of the output units 1 to 4. That is, a pair of electrodes 1a and 1b is connected to the first output section 1 serving as the first channel via the wirings 1A and 1B. Similarly, a pair of electrodes 2a and 2b are connected to the second output section 2 serving as the second channel via wirings 2A and 2B. A pair of electrodes 3a and 3b are connected to the third output section 3 serving as the third channel via wirings 3A and 3B. A pair of electrodes 4a and 4b are connected to the fourth output section 4 serving as the fourth channel via wirings 4A and 4B. Thus, in the embodiment, a total of four electrode pairs are used.
[0016]
  In FIG. 1, T is a treatment table, and K is a patient lying on the treatment table T. The electrodes 1a, 1b to 4a, 4b are mounted on the back as a treatment site of the patient K by using a holding sheet body described later. Thereby, by outputting a low frequency signal for treatment (low frequency electric signal) to be described later from the output units 1 to 4, between each pair of electrodes 1a and 1b, between 2a and 2b, 3a Stimulation is applied to each site between 3 and 3b and between 4a and 4b.
[0017]
  FIG. 2 is a block diagram showing a control system used in the present invention, and in particular, focuses on a specific mode for performing a massage with a sense of touch (a circuit for normal low-frequency treatment). Some parts are not shown). In FIG. 2, U is a control unit (controller) configured using a microcomputer. The control unit U includes a CPU, a ROM, a RAM, a system timer, and the like. The control unit U receives signals from switches 11 to 14 as independent adjustment means for manually adjusting the magnitudes of outputs from the output units 1 to 4. The switches 11 to 14 include lower operation units 11a to 14a that decrease output and increase operation units 11b to 14b that increase output. The reduction operation unit 11a outputs a command signal for reducing the output to the control unit U by, for example, a pressing operation (the same applies to 12a to 14a). Further, the increase operation unit 11b outputs a command signal to increase the output to the control unit U by, for example, a pressing operation (the same applies to 12b to 14b).
[0018]
  The switch 5 is a decision switch that is manually operated. For example, when the switch 5 is pressed, a command to store the current output state from each output unit 1 to 4, particularly between each output unit 1 to 4, A command signal for storing a ratio of the current output magnitude is output to the control unit U. The switch 6 is a manually operated common switch as common adjustment means, and commands the control unit U to command signals for simultaneously changing the magnitudes of outputs from the output units 1 to 4. The common switch 6 is, for example, a volume type, and an output increase request is made by rotating in a predetermined direction, and an output decrease request is made by rotating in the other direction. When receiving a request to change the output of each of the output units 1 to 4 by the common switch 6, the control unit U outputs in a state where the output ratio stored at the time when the determination switch 5 is operated is maintained. Control is performed to change the size of. The common switch 6 can be automatically returned to the output zero state by the motor 7 controlled by the control unit U.
[0019]
  In FIG. 2, reference numeral 8 is a manually operated switch for setting a treatment time, and commands a desired treatment time (for example, 15 minutes). The control unit U outputs a control signal corresponding to the therapeutic low-frequency electrical signal to the D / A circuits (digital-analog conversion circuits) 21 to 24. That is, the output units 1 to 4 output electrical signals (therapeutic low frequency electrical signals) from the amplifiers 31 to 34 to the outside, and control signals from the control unit U to the amplifiers 31 to 34 are output. The D / A conversion circuits 21 to 31 are used. Further, the control unit U outputs a signal indicating the output state from each of the output units 1 to 4 to the display 9 provided in a place where the main body H is easily visible. The display 9 displays the output states of the output units 1 to 4 independently. In the embodiment, the voltage and current output from the output units 1 to 4 are displayed. ing. Further, the control unit U outputs to a speaker (buzzer) 36 via an amplifier 35.
[0020]
  Next, output waves from the output units 1 to 4 will be described with reference to FIGS. In addition, although the output from the output units 1 to 4 is a voltage value in the embodiment, it can be a current value. First, as shown in FIG. 3, the electrical signals output from the output units 1 to 4 are basically a low-frequency electrical signal that is output with a low-frequency square pulse having a predetermined width (time width). (The period corresponding to the pulse interval in FIG. 3 corresponds to a low frequency, for example, 1HZ to 999HZ in frequency). In the embodiment, a medium frequency as a carrier wave is superposed on the low frequency electric signal (for example, 2 KHZ to 10 KHZ in frequency). That is, an electric signal of medium frequency is superposed within a square pulse width that becomes a low frequency signal, and a burst duty ratio that becomes a superposition ratio is always a constant value (for example, 30%) in the embodiment. Thereby, it becomes effective for giving a stimulus to the part which goes deep from the body surface of the patient K while having a low frequency component.
[0021]
  As shown in FIG. 4, the outputs from the output units 1 to 4 are in a continuous output state where a constant value is maintained for a predetermined time, but the output gradually increases until the continuous output state is reached. In addition, the output is gradually decreased from the continuous output state to the gradually decreasing output state. In this case, the output increase rate (output increase rate per unit time) in the gradually increasing output state is smaller than the output decrease rate (output decrease rate per unit time) in the gradually decreasing output state. In other words, the increase in output is slow and the decrease in output is rapid. The output increase ratios in the gradually increasing output state between the output units 1 to 4 are set to be substantially equal to each other, and similarly, the output decrease ratios in the gradually decreasing output state are also set to be substantially equal to each other.
[0022]
  The outputs from the output units 1 to 4 are sequentially performed with a time shift. For example, the first output unit 2 (electrodes 1a and 1b), the second output unit 2 (electrodes 2a and 2b), the third output unit 3 (electrodes 3a and 3b), and the fourth output unit 4 (electrodes 4a and 4b). Output in order. The order of the outputs corresponds to the direction of the brushing. For example, in the case of FIG. 1, a sense of touching clockwise (clockwise) in the output order is given. Contrary to the above output order, when output is performed in the order from the fourth output unit 4 to the third output unit 3, the second output unit 2, and the first output unit 1, it is counterclockwise (counterclockwise) in FIG. A sensation is given.
[0023]
  FIG. 5 shows a preferable output example. FIG. 5 shows a case where the first output unit 1, the second output unit 2, the third output unit 3, and the fourth output unit are sequentially output and output in this order is repeatedly performed. In the example of FIG. 5, the magnitude of the output (continuous output state) is the largest in the second output unit 2, the smallest in the third output unit 3, and the first output unit 1 and the fourth output unit 4. It is the middle size. The size of each of the output units 1 to 4 is different in consideration of the fact that the stimulation intensity felt by the patient K varies depending on the electrode mounting site even if the output is the same size. Is. In other words, the output magnitude is adjusted between the output units 1 to 4 so as to feel the same stimulation intensity for each part where the electrode is mounted.
[0024]
  As is clear from FIG. 5, in the embodiment, the output delay time (delay time) between the output units 1 to 4 is set to be substantially equal to each other (for example, from the first output unit 1). (The output from the second output unit 2 is started after a certain delay time t from the start of the output, and the output from the third output unit 3 is started with the delay of the above t from the start of the output from the second output unit 2) .
[0025]
  While the current output unit (for example, the first output unit 1) that is being output this time is being output, the output from the output unit (for example, the second output unit 2) that is to be output next is started. . More specifically, the output from the next output unit is started while the output state of the output unit at this time is in the continuous output state described above. At the time when the output from the current output unit is stopped (output zero) (the end of the gradually decreasing output state), the output state at the next output unit is set to the continuous output state. By such setting, in particular, a strong sense that the stimulus continuously moves from a pair of electrodes that are output to another electrode that is output next is obtained. In addition to the above, the next output is performed in the transitional period in which the output state of the current output unit among the plurality of output units 1 to 4 is shifted from the continuous output state to the gradually decreasing output state. The output from the next output unit is the start time of the continuous output state.
[0026]
  In addition, after the output from the output unit that has been output this time is completely stopped (output zero), if the output from the next output unit is started, the feeling of smashing will be interrupted This is undesirable. In addition, although it is conceivable that only the continuous output state is set as the output state from each of the output units 1 to 4 (when both the gradually increasing output state and the gradually decreasing output state are not provided), in this case, the stimulus is gradually and gradually increased. It becomes difficult to get the feeling of moving to.
[0027]
  For example, from the start of output from the first output unit, through the output of the second output unit, the output of the third output unit, the output of the fourth output unit, until the output from the first output unit is started again The time (the time per cycle, the time corresponding to the repetition time in FIG. 5) may be set to a time that takes into account the massage performed by ordinary hands, for example, about 0.5 second to 2 seconds, preferably What is necessary is just to set in the range of about 0.8 second-1.5 second. Further, this one cycle time can be manually changed (a manual switch for this purpose may be provided separately).
[0028]
  Next, the control content of the control unit U that performs the above-described control will be described with reference to the flowcharts of FIGS. The mounting state of the plurality of sets of electrodes 1a, 1b to 4a, 4b to the patient K is, for example, as shown in FIG. 1, and in order to give a sense of turning counterclockwise in FIG. The first output unit 1, the second output unit 2, the third output unit 3, and the fourth output unit 4 are arranged in this order. In the following description, Q indicates a step.
[0029]
  First, in Q1, by operating the switch 8, the treatment time is set to 15 minutes, for example. In Q2, the outputs from the output units 1 to 4 are individually adjusted using the adjustment switches 11 to 14. More specifically, after the treatment time is set in Q1, first, output is performed only from the first output unit 1, and the switch 11 (the lowering operation unit 11a and the increasing operation unit 11b) is operated. By doing so, the patient K is adjusted so as to have a minimum output that feels a stimulus, and this adjusted value is temporarily stored. Next, output is performed only from the second output unit 2, and by operating the switch 12 (the operation units 12a and 12b), the output is adjusted to the minimum output felt by the patient K. Temporarily stored. Thereafter, the output is performed only from the third output unit 3, and the switch 13 (the operation units 13 a and 13 b) is operated to adjust the output so that the patient K feels the minimum output. Is temporarily stored. Finally, the output is performed only from the fourth output unit 4, and the switch 14 (the operation units 14a and 14b) is operated so that the minimum output felt by the patient K is adjusted. Is temporarily stored. In this way, the minimum output size that allows the user to feel a stimulus at the attachment site of the electrodes 1a, 1b to 4a, 4b corresponding to the output units 1 to 4 is set independently for each of the output units 1 to 4. , Will be remembered. Note that it is also possible to display on the display 9 which one output unit is currently output.
[0030]
  In Q3, it is determined whether or not the decision switch 5 has been turned ON. If the determination in Q3 is NO, the process returns to Q2. When YES is determined in Q3, the magnitude of the output ratio between the output units 1 to 4 stored as described above is stored in Q4. As this storage, for example, when the output value of the third output unit 3 having the smallest output value is 100%, the output value of the first output unit 1 is 110%, and the output value of the second output unit 2 is 140. %, And the output value of the fourth output unit 4 is stored as 120%.
[0031]
  In Q5, the outputs are simultaneously output from the output units 1 to 4 in the ratio of the output stored as described above (in the embodiment, the output value set and stored in Q2 is output as it is). In the state in which the outputs are simultaneously performed from the output units 1 to 4, the patient K is in all the wearing sites between the electrodes 1a and 1b corresponding to the output units 1 to 4 and between 4a and 4b. , Feels almost the same strength of stimulation. In this state, in Q6, by operating the common switch 6, the magnitude of the output from each output unit 1 to 4 is adjusted so that the patient K feels comfortable (in the embodiment, initially, Since the output gives the weakest stimulus, the common switch 6 adjusts the direction of increasing the stimulus, that is, the direction of increasing the output). At the time of output adjustment by the common switch 6, the magnitude of the output from each of the output sections 1 to 4 is performed so that the magnitude ratio of the output stored in Q4 is maintained. As a result, the patient K feels stimulation of almost the same size for all the electrode mounting sites.
[0032]
  In Q7, it is determined whether or not a predetermined time (for example, 15 seconds) has elapsed since the decision switch 5 in Q3 was turned on. If the determination in Q7 is NO, the process returns to Q5. If YES in Q7, simultaneous output from the output units 1 to 4 is stopped in Q8, and sequential output in a predetermined order is started. That is, for example, the output is started in the output mode in the brushing mode (specific mode) for obtaining the brushing sensation as shown in FIG.
[0033]
  In Q9, it is determined whether or not the treatment time set in Q1 has elapsed since the output start time in the feed mode in Q8. When the determination of Q9 is NO, the process of Q8 is repeated and the output mode in the brushing mode is continued. If YES in Q9, the buzzer 36 is activated in Q10 to indicate the end of treatment. Thereafter, in Q11, the operation state of the common switch 6 is forcibly driven and returned to the state of zero output by the motor 7, and the output from all the output units 1 to 4 is stopped.
[0034]
  When performing output in the Q8 tilt mode, the output size from each output unit 1 to 4 can be adjusted independently or the output size from all output units 1 to 4 can be changed simultaneously. You can also In this case, for example, the flowchart shown in FIG. 7 is interrupted every predetermined time with respect to the flowchart shown in FIG. Note that the flowchart of FIG. 7 may be interrupted from the flowchart of FIG. 6 when any one of the switches 11 to 14 or the common switch 6 is operated.
[0035]
  In the flowchart of FIG. 7, first, at Q21, it is determined whether or not any of the switches 11 to 14 has been operated. If YES in Q21, the output from the output unit (eg, first output unit 1) corresponding to the operated switch (eg, switch 11) is changed in Q22. Moreover, in this Q22, the output ratio between each output part 1-4 is changed and memorize | stored with the change from the output from one part output part.
[0036]
  After Q22 or when NO is determined in Q21, it is determined in Q23 whether or not the common switch 6 has been operated. When the determination in Q23 is YES, in Q24, the magnitudes of the outputs from the output units 1 to 4 are simultaneously changed while maintaining the stored output ratio. Note that the simultaneous change in output is a simultaneous change in software, and what is actually embodied as a change in output is every output timing of each of the output units 1 to 4 (sequential change in output). If NO in Q23, the process returns as it is.
[0037]
  Next, a plurality of pairs of electrodes 1a, 1b to 4a, 4b and a holding sheet main body for holding these will be described with reference to FIG. First, a holding sheet main body is denoted by reference numeral 41. The holding sheet main body 41 is formed into a thin sheet as a whole by, for example, a soft synthetic resin, and has a thin internal space 42 inside (see FIG. 12). A plurality of sets of electrode pairs 1a, 1b to 4a, 4b are detachably attached to one surface side of the holding sheet main body 41.
[0038]
  The holding sheet body 41 is substantially divided into two regions 51 and 52, and a virtual boundary line γ between the two regions 51 and 52 is indicated by a one-dot chain line in FIG. That is, the first region 51 is substantially rectangular, and is positioned at the center and at the upper portion of the holding sheet main body 41 in the left-right direction (FIG. 9, FIG. 10 left-right direction). The second region 52 is formed so as to partially surround the peripheral portion of the first region 51. That is, in FIG. 9, the second region 52 is generally U-shaped as a whole, and is continuous with the first peripheral portion 51 a below the first region 51 and one end side of the first peripheral portion 51 a. The second peripheral edge portion 52b on the left side and the third peripheral edge portion 51c on the right side connected to the other end side of the first peripheral edge portion 51a are extended to be substantially U-shaped as a whole. That is, the above-described virtual boundary line γ is set to be substantially U-shaped.
[0039]
  In the first region 51, the electrodes 1a, 2a, 3a, 4a on one side of the plurality of sets of electrodes 1a, 1b-4a, 4b are arranged. Specifically, the four one-side electrodes 1a to 4a are distributed and arranged at substantially four corners of the substantially rectangular first region 51, and the electrode 1a is disposed above the second peripheral edge portion 51a. 1b is on the upper part of the third peripheral part, the electrode 3a is on the lower part of the second peripheral part 51a (the right end part of the first peripheral part 51a), and the electrode 4a is on the lower part of the third peripheral part 51a (of the first peripheral part 51a). (Left end) As described above, the electrodes 1a, 2a, 3a, and 4a are sequentially arranged clockwise in FIG. 10 from the electrode 1a.
[0040]
  Four other electrodes 1 b to 4 b are disposed in the second region 52. That is, the electrode 1b is disposed in the vicinity of the paired electrode 1a at a position along the second peripheral edge portion 51b. The electrode 2b is disposed in the vicinity of the paired electrodes 2a at a position along the third peripheral edge 51c. The electrode 3b is disposed at a position along the first peripheral edge 51a, in the vicinity of the paired electrode 3a and next to the electrode 2b. The electrode 4b is disposed in the vicinity of the electrode 4a at a position along the first peripheral edge 51a and between the electrodes 1b and 3b.
[0041]
  The first region 51 is covered with a first conductive sheet 53 in order to improve conductivity. Similarly, the second region 52 is also covered with the second conductive sheet 54. The first conductive sheet 53 is formed in a shape corresponding to the first region 51, that is, in a substantially square shape. Similarly, the second conductive sheet 54 is formed in a shape corresponding to the second region 42, that is, substantially U-shaped. Each of the conductive sheets 53 and 54 is formed in a thin sheet shape such as a sponge having communication bubbles mixed with a conductive material such as carbon. In order to improve conductivity, the electrodes 1a to 4a or the electrodes 1b to 4b are covered with the conductive sheets 53 and 54 immersed in water, for example.
[0042]
  In order to detachably attach the first conductive sheet 53 to the holding sheet main body 41, a first attachment portion 55 is formed on the holding sheet main body 41 (one surface side). Similarly, in order to detachably attach the second conductive sheet 54 to the holding sheet main body 41, a second attachment portion 56 is formed on the holding sheet main body 41 (one surface side). Each of the attachment portions 55 and 56 is integrally formed with the holding sheet main body 41. That is, the holding sheet main body 41 can be formed by, for example, blow molding, but the attachment portions 55 and 56 can also be formed at the same time as this blow molding.
[0043]
  The first attachment portion 55 is formed so as to surround substantially the entire periphery of the first region 51. As shown in FIG. 14, the first attachment portion 55 has a substantially L-shaped cross section, and protrudes from the holding sheet main body 41 (one surface side), and a front end (upper end) of the vertical wall portion 55a. ) To the first region 51 (the direction covering the first region 51). The first conductive sheet 53 is held by the holding sheet main body 41 by engaging the outer peripheral edge of the first conductive sheet 53 with the first mounting portion 55, but the lateral wall portion 55 b is separated from the holding sheet main body 41 of the conductive sheet 53. This is done with a locking action to prevent detachment. The first mounting portion 51 is cut into a part of the entire peripheral edge portion of the first region 51 so that a part of the outer peripheral edge portion of the first conductive sheet 55 can be gripped and easily attached and detached. It has a notch.
[0044]
  The second attachment portion 56 is formed so as to surround substantially the entire periphery of the second region 52. The second attachment portion 56 is formed in the same manner as the first attachment portion 55. That is, as shown in FIG. 14, the second attachment portion 56 has a substantially L-shaped cross section, and protrudes from the holding sheet main body 41 (one surface side), and the tip of the vertical wall portion 56 a ( And a lateral wall portion 56b extending in the direction from the upper end) to the second region 52 (the direction covering the second region 52). The second conductive sheet 54 is held by the holding sheet main body 41 by engaging the outer peripheral edge portion thereof with the second mounting portion 56, but the horizontal wall portion 56 b is held by the holding sheet main body 41 of the second conductive sheet 54. It will be performed with a locking action to prevent detachment. The second mounting portion 56 is cut into a part of the entire peripheral edge portion of the second region 52 so that a part of the outer peripheral edge portion of the second conductive sheet 54 can be gripped and easily attached and detached. It has a notch.
[0045]
  Each electrode 1a, 1b-4a, 4b is made detachable with respect to the holding sheet main body 41 in the embodiment. In the embodiment, the electrodes 1a, 1b to 4a, 4b are attached to the holding sheet main body 41 by using, for example, a concave-convex engagement locking mechanism such as a hook. An example of this locking mechanism will be described with reference to FIG. 13 while focusing on the electrode 1a, but the same locking mechanism is adopted for the other electrodes. That is, a female side member 61 that constitutes an engaging concave portion as a locking portion is fixed to one surface side of the holding sheet main body 41, and a male side member 62 that constitutes an engaging convex portion is fixed to the electrode 1a. Yes. The electrode 1 a is fixed to the holding sheet main body 41 by aligning the male side member 62 with the female side member 61 and strongly pressing the electrode 1 a against the holding sheet main body 41. By peeling off the fixed electrode 1 a, the engagement between the female side member 61 and the male side member 62 is released, and the electrode 1 a is removed from the holding sheet main body 41.
[0046]
  The cross-sectional shape (the cross-sectional shape in the direction orthogonal to the axis that is the engaging direction) of the fitting portion between the female-side member 61 and the male-side member is circular (or substantially circular) in the embodiment, For this reason, the electrodes 1 a, 1 b to 4 a, 4 b are rotated relative to the holding sheet main body 41 simply by engaging the female side member 61 and the male side member 62. The anti-rotation mechanism for preventing the relative rotation will be described later.
[0047]
  The female-side member 61 and the male-side member 62 are each formed of a conductive member, and are formed of, for example, an iron-based metal or a copper alloy in order to ensure sufficient strength (rigidity) (for example, The surface of both members 61 and 62 can also be subjected to a treatment such as silver plating or gold plating for improving conductivity). The male side member 62 is fixed to the electrode 1a, and the electrical conductivity is always secured between the male side member 62 and the electrode 1a. In the state where the female side member 61 and the male side member 62 are engaged, by energizing the female side member 61, the electrode 1 a is energized via the male side member 62. The holding sheet main body 41 itself is formed of a soft non-conductive member (insulating member), and even if the female side member 61 is energized, the holding sheet main body 41 itself is not energized. In the embodiment, each of the electrodes 1a, 1b to 4a, 4b is configured so as to be entirely conductive by a soft material mixed with a conductive material such as carbon, and is in contact with the male member 62. By simply doing, energization with the male side member 62 is ensured.
[0048]
  The engagement relationship between the electrode 1a and the holding sheet body 41 as described above is the same for the other electrodes 1b, 2a, 2b, 3a, 3b, 4a, and 4b. In the thin internal space 42 in the holding sheet main body 41, the above-described energization wires 1A, 1B to 4A, 4B are disposed. Each of the wires 1A, 1B to 4A, 4B is grouped into one cable from a portion led out of the holding sheet main body 41, and its external connection ends are collectively wired to a connection coupler (not shown). ing. That is, the connection coupler has at least eight connection terminals corresponding to a total of eight wirings 1A, 1B to 4A, 4B, and can be detachably connected to the connection terminals provided in the low frequency treatment device body H. It is said. In other words, in FIG. 1, each of the wirings 1A, 1B to 4A, 4B is shown independently for the sake of clarity, but actually, as described above, the wirings 1A, 1B to 4A, 4B have a single cable. It is connected to the low frequency treatment device main body H.
[0049]
  In use, as shown in FIG. 8, the electrodes 1a, 1b to 4a, 4b are attached to the holding sheet main body 41, and then the two conductive sheets 53, 54 are attached to obtain the state shown in FIG. Then, the conductive sheets 53 and 54 are brought into contact with the patient so as to be positioned on the body surface side of the patient. In addition, in order to make each electrode 1a, 1b-4a, 4b contact the patient body surface reliably via the conductive sheet 53 or 54, the holding sheet main body 41, that is, each electrode 1a, 1b. 4a and 4b can be pressed against the patient body surface. In this case, the belt or the like can be used to prevent displacement of the holding sheet main body 41 with respect to the patient body surface. Further, in order to improve the conductive sheet between the electrode and the patient, as shown in FIG. 14, a plurality of rib portions are projected from the surface on the patient side of the electrodes 1a, 1b to 4a, 4b.
[0050]
  Here, if the female side member 61 and the male side member 62 are made of metal, the members 61 and 62 are rusted by moisture adhering to the conductive sheets 53 and 54, sweat generated from the patient, and the like. It is thought that it will occur. In order to prevent the occurrence of rust, it is preferable that both the members 61 and 62 are blocked or sealed from the outside. An example of a seal mechanism for this seal will be described. First, as shown in FIGS. 8, 9, and 13, an annular convex seal portion 71 is provided on the holding sheet main body 41 so as to surround the female side member 61 on the figure holding sheet main body 41 (one surface side). Are integrally molded.
[0051]
  Similarly, in each of the electrodes 1a, 1b to 4a and 4b, an annular convex seal portion 72 is integrally formed with the electrodes 1a, 1b to 4a and 4b so as to surround the male member 62 (see FIG. 13, see FIG. When the male side member 62 of each of the electrodes 1a, 1b to 4a, 4b is engaged with the female side member 61 of the holding sheet main body 41, the two convex seal portions 71 and 72 are in a double relationship. So that they are closely fitted. This prevents moisture, sweat, and the like from the outside, that is, the electrodes 1a, 1b to 4a, 4b, from entering the female side member 61 and the male side member 62, and the rusting of both the members 61 and 62 occurs. Is prevented. In particular, since each of the convex seal portions 71 and 72 has elasticity, the sealing performance is extremely good.
[0052]
  Each of the electrodes 1a, 1b to 4a, 4b is integrally formed with a pair of convex sandwiching portions 83 on the radially outer side of the second convex seal portion 72, as shown in FIGS. Yes. This clamping part 83 is formed so as to at least partially surround the second convex seal part 72 in the circumferential direction, and its inner surface facing the second convex seal part 2 has an arc shape. And the clearance gap between the 2nd convex seal part 72 and the clamping part 83 is substantially the same as the radial direction thickness of the 1st convex seal part 71 formed in the holding sheet main body 41, and each convex seal part In a state where 71 and 72 are fitted in a double structure inside and outside, the first convex seal portion 71 is sandwiched from the radial direction by the second convex seal portion 72 and the sandwiching portion 83. Thereby, the contact | adherence state of the radial direction of both convex-shaped seal parts 71 and 72 is ensured more fully. In addition, it is also possible to make the clamping part 83 into an annular shape as a whole. It is also possible to form (integrally mold) a clamping part corresponding to the clamping part 83 on the holding sheet main body 41 side. In this case, the first convex seal part 71 of the holding sheet main body 41 and the clamping part The second convex seal portions 72 of the electrodes 1a, 1b to 4a, 4b are sandwiched from the radial direction.
[0053]
  Here, when the electrodes 1a, 1b to 4a and 4b are formed in a deformed shape, and the fitting portion with respect to the holding sheet main body 41 is only one place, the electrodes 1a, 1b to 4a and 4b are connected to the holding sheet main body 41. Thus, it may be possible to rotate freely and deviate from the desired mounting posture state. In order to prevent such a situation, an anti-rotation mechanism for the electrodes 1a, 1b to 4a, 4b can be separately configured. In the embodiment, the detent mechanism has a total of two positions on the holding sheet main body 41 (one surface side) at a position eccentric with respect to the female side member 61 that is the rotation center of the electrodes 1a, 1b to 4a, 4b. The fitting recess 81 is formed. Corresponding to the fitting recess 81, a fitting projection 82 is integrally formed on each of the electrodes 1a, 1b to 4a, 4b. In the attached state of the electrodes 1a, 1b to 4a, 4b in which the male side member 62 is engaged with the female side member 61, the fitting convex portion 82 is fitted into the fitting concave portion 81. Thereby, the situation where each electrode 1a, 1b-4a, 4b rotates around the female side member 61 (male side member 62) arbitrarily during use is prevented, and each electrode 1a, 1b-4a is prevented. 4b can be fixed to the holding sheet main body 41 in a desired posture state. In order to prevent rotation, the fitting convex portion may be formed on the holding sheet main body 41 side while the fitting concave portion may be formed on the electrode side. In short, in order to prevent rotation, an engagement relationship may be configured between the holding sheet main body 41 and the electrode at a position eccentric with respect to the female side member 61 and the male side member 62. An engaging convex portion may be formed on each of the holding sheet main body 41 and the electrode.
[0054]
  Although the embodiment has been described above, the present invention is not limited to this, and includes, for example, the following cases. The number of pairs of electrodes (the number of output portions) may be two or more, but three or more, particularly four or more as shown in the embodiment, provides a sufficient sense of brushing. Preferred above. The order of output from the plurality of output units is not limited to the case of repeating in the same order. For example, the output is started from the first output unit 1 that is output for the first time, for example, after the fourth output unit 4 that is output last. The output order may be reversed. More specifically, for example, in the example of FIG. 5, the first output unit 1, the second output unit 2, the third output unit 3, the fourth output unit 4, the third output unit 3, the second output unit 2, The output such that the rubbing direction is reversed may be performed by using the output unit 1, the second output unit 2, the third output unit 3, and so on. As described above, a switch for manually selecting a repeat mode in which the same output order is repeated without changing the output order of the plurality of output units and an inversion mode in which the rubbing direction is reversed as described above are provided. You can also
[0055]
  It may be possible to change the time per cycle until the sequential output from all the output units is completed once. In this case, a manually operated switch is provided separately for instructing to change the time per cycle. Just do it. Accordingly, it is possible to arbitrarily obtain a feeling of changing the speed of the brushing, that is, a feeling of performing the brushing early and a time of slowing down the brushing. The low frequency electrical signal may be one that does not superimpose a medium frequency carrier wave.
[0056]
  It is also possible to set the second region 52 so as to be annular (for example, an annular shape, a rectangular shape, an elliptical shape) so as to surround the first region 51 as a whole. For example, the first region 51 may be formed in a substantially square shape or a substantially circular shape, while the second region 52 may be formed in an annular shape (substantially annular shape) that entirely surrounds the first region 51. In this case, it is preferable to set the number of electrode pairs to 4 or more, for example, 5 sets, 6 sets, 7 sets, 8 sets, etc. as many as possible (a plurality of sets of electrode pairs are arranged at substantially equal intervals in the circumferential direction). Preferably). The electrodes 1a, 1b to 4a, 4b can be always fixed without being detachable from the holding sheet body 41. Moreover, in order to make each electrode 1a, 1b-4a, 4b detachable with respect to the holding | maintenance sheet main body 41, not only an uneven | corrugated fitting type but an appropriate attachment method can be employ | adopted.
[0057]
  The engagement positions of the electrodes 1a, 1b to 4a, 4b with respect to the holding sheet main body 41 can be set to two or more for one electrode (in this case, it is unnecessary to separately provide an electrode rotation prevention mechanism). In addition, the position where the electrode is engaged with the holding sheet main body 41 and the position where the electrode is energized can be configured separately (the energization of the electrode using the female side member 61 and the male side member 62 is performed). Absent).
[0058]
  While the female side member 61 is provided on the electrode side, the male side member 62 may be provided on the holding sheet main body 41 side. When sealing the energized portion between the female side member 61 and the male side member 62, for example, an annular convex formed on the electrode side with respect to the annular concave (or convex) formed on the holding sheet body 41, for example. It can also be performed by fitting the part (or the concave part). The seal part may be a quadratic ring or an oval ring, for example, without forming an annular shape as a whole. However, in order to eliminate the presence of the corner portion and to ensure good sealing performance and ease of manufacture Taking these into consideration, it is preferable to use an annular shape.
[0059]
  In the embodiment, the description has been given focusing on the case of obtaining a sense of brushing, but the electrode holding sheet device according to the present invention can also be used for ordinary massage. For example, it is possible to apply a therapeutic electrical signal to a plurality of pairs of electrodes at the same time and simultaneously apply stimulation to a plurality of locations. In addition, after applying a treatment signal for a long time (for example, 5 minutes) to only one electrode among a plurality of electrode pairs, a long-time electrical signal for treatment is applied to another electrode pair. This can be performed sequentially while changing the electrode pair to which the electrical signal is applied (in the manner of use in which electrodes are arranged in advance for a plurality of sites to which stimulation is applied for a long time, Since an electric signal is continuously applied to one electrode pair for a long time, it is completely unrelated to the sense of brushing).
[0060]
  The anti-rotation mechanism of the electrodes 1a, 1b to 4a, 4b with respect to the holding sheet main body 41 may be configured, for example, by making the cross-sectional shapes of the fitting portions of the female side member 61 and the male side member 62 different from each other. Is possible. However, in this case, the external force for preventing the rotation is concentrated on the fitting portion between the female side member 61 and the male side member 62 as the locking mechanism, so that the locking mechanism is eccentric as in the embodiment. It is preferable to separately configure a portion that receives an external force for preventing rotation at the position. Various members such as each step (step group) or switch shown in the flow chart can be expressed by attaching the name of the means to the high-order expression of the function. The arrangement of the electrodes can be arbitrarily set. In particular, when a special mode for obtaining a sense of brushing is not required, for example, the one-side electrodes 1a to 4a are arranged in series along a predetermined straight line, and the other The side electrodes can also be arranged in series along the predetermined straight line.
[0061]
  The conductive sheets 53 and 54 can be set to be detachably connected to the holding sheet main body 41 by hooks or the like at positions where no electrodes are present (the holding sheets of the conductive sheets 53 and 54). Ensuring more secure attachment to the main body 41). Of course, the conductive sheets 53 and 54 may be omitted. The function of each step (step group) shown in the flowchart can also be expressed as a function of a function unit set in the control unit (controller) (existence of a function unit). Of course, the object of the present invention is not limited to what is explicitly stated, but also implicitly includes providing what is substantially preferred or expressed as an advantage.
[Brief description of the drawings]
FIG. 1 is a simplified top view illustrating an arrangement example of electrodes with respect to a patient for obtaining a sense of brushing.
FIG. 2 is a block diagram showing an example of a control system for obtaining a sense of brushing.
FIG. 3 is a diagram showing an example of a low frequency signal for treatment.
FIG. 4 is a diagram showing a preferable output example from each output unit, focusing on the output per one time.
FIG. 5 is a view showing a preferable output example when outputting sequentially from each output unit;
FIG. 6 is a flowchart showing an example of control for obtaining a sense of brushing.
FIG. 7 is a flowchart showing an example of control for obtaining a sense of brushing.
FIG. 8 is an exploded perspective view showing an electrode and a conductive sheet attached to the holding sheet main body.
FIG. 9 is a plan view showing an electrode mounting surface side of the holding sheet main body.
10 is a plan view showing a state in which an electrode and a conductive sheet are attached from the state shown in FIG. 9;
FIG. 11 is a rear view of FIG. 9;
FIG. 12 is a side sectional view of the holding sheet main body.
FIG. 13 is an enlarged cross-sectional view showing an attachment site between the holding sheet main body and the electrode.
FIG. 14 is a cross-sectional view of a principal part showing a state where an electrode attached to a holding sheet main body is covered with a conductive sheet.
FIG. 15 is a diagram showing an attachment surface side of the electrode with respect to the holding sheet main body.
[Explanation of symbols]
H: Main body of multi-channel type low frequency treatment device
K: Patient
U: Control unit
γ: Virtual border
1-4: Output unit
1a, 1b-4a, 4b: Electrode
41: Holding sheet body
42: Internal space
51: First region
52: Second region
53: First conductive sheet
54: Second conductive sheet
55: First mounting portion
56: Second mounting portion
61: Female side member (locking recess)
62: Male side member (engagement convex part)
71: 1st convex seal part
72: Second convex seal part
81: Fitting recess (for rotation prevention)
82: Fitting protrusion (for rotation prevention)
83: Clamping part

Claims (4)

In an electrode holding sheet device for a multi-channel type low frequency treatment device, wherein a plurality of electrodes are provided on one surface side of an insulating holding sheet body, and the plurality of electrodes are positioned on the patient's body surface side and are attached to the patient. ,
Each of the electrodes is detachably attached to the holding sheet body by a concave-convex fitting locking mechanism with respect to the holding sheet body,
The locking mechanism includes a locking portion formed of a concave portion or a convex portion provided on the one surface side of the holding sheet body, and a convex portion or a concave portion provided on each of the electrodes and fitted to the locking portion. And the engagement portion and the engagement portion constituting the engagement mechanism are provided only for one electrode,
Each of the locking portion and the engaging portion has conductivity, and a current-carrying wiring to each electrode is connected to the locking portion in the holding sheet body,
Between the holding sheet main body and each electrode, there is a seal mechanism for liquid-tightly blocking the locking mechanism from the outside when the electrode is locked to the holding sheet main body by the locking mechanism. Configured ,
The seal mechanism includes a first convex seal portion that is integrally formed with the holding sheet body and surrounds the locking portion, and a second convex seal portion that is integrally formed with the electrode and surrounds the engagement portion. When the engaging portion is engaged with the locking portion, the first convex seal portion and the second convex seal portion are set to be fitted in an inner / outer dual structure. And
The first convex seal portion and the second convex seal portion each have elasticity and are formed in an annular shape centering on the locking mechanism,
Between the holding sheet body and the electrode, when the electrode is locked to the holding sheet body by the locking mechanism, the electrode is centered on the locking mechanism with respect to the holding sheet body. A detent mechanism that restricts rotation is configured,
The anti-rotation mechanism is formed on the electrode at a position that is eccentric from the engaging portion, a first fitting portion that is formed in the holding sheet body at a position that is eccentric from the locking portion, and that is formed from a concave portion or a convex portion. And a second fitting part comprising a convex part or a concave part fitted into the first fitting part,
A fitting direction between the engaging portion and the locking portion; a fitting direction between the first convex seal portion and the second convex seal portion; and the first fitting portion and the second fitting portion. Are set to be in the same direction as each other,
An electrode holding sheet device for a multi-channel type low frequency treatment device. In claim 1 ,
The holding sheet body is formed with a clamping portion for cooperating with the first convex seal portion to clamp the second convex seal portion from the radial direction thereof. -Type electrode holding sheet device for low frequency therapy equipment. In claim 1 ,
The electrode is provided with a clamping portion for cooperating with the second convex seal portion to clamp the first convex seal portion from the radial direction thereof. Electrode holding sheet device for frequency therapy device. In any one of Claims 1 thru | or 3 ,
An electrode holding sheet device for a multi-channel type low frequency treatment device, wherein each of the electrodes has an irregular shape.

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