JP4326824B2 - Interference low frequency treatment device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention provides interference low frequency therapyIn a vesselIt is related.
[0002]
[Prior art]
  Among the low-frequency treatment devices for treating patients such as massage, there is an interference low-frequency treatment device using a low-frequency electric signal obtained by interference between high-frequency electric signals. In this interference low-frequency treatment device, two or more pairs (electrodes) to be electrically connected to the patient body surface are provided, and the frequency is slightly different from each other for each set of conductors. A high frequency electrical signal is applied. Each set of conductors is arranged on the patient's body surface so that the straight lines connecting the pair of conductors intersect each other, and treatment is performed by low-frequency components obtained by interference between high-frequency electrical signals generated near this intersection. Will be done. That is, the vicinity of the intersection is a stimulation site for the patient. Patent Document 1 discloses that the number of pairs of conductors to be paired is 3 or more. This Patent Document 1 also discloses changing the output of a high-frequency electrical signal or modulating the high-frequency electrical signal in order to change the stimulus at the intersection.
[0003]
[Patent Document 1]
JP-A-11-212290
[0004]
[Problems to be solved by the invention]
  By the way, in the conventional interference low frequency treatment device, the stimulation site to the patient in which the interference between the high frequency electrical signals is not changed. That is, once the conductor is disposed at a desired position on the surface of the patient body, unless the position of the conductor is changed, the interference site is the same and the stimulation is always applied to the same site. And even if the output change of a high frequency electric signal or a modulation process is performed, the stimulation part itself does not change at all.
[0005]
  On the other hand, in the case of an interference low frequency treatment device, there are many cases where it is difficult to accurately set an interference site at a desired position. That is, the interference low-frequency treatment device has an advantage that it is possible to apply a stimulus to a deep position in the body because the interference site can be set at a deep position inside the patient's body. On the other hand, in order to cause interference at a desired deep position inside the patient's body, it is necessary to appropriately set a conductor arranged in a three-dimensional positional relationship on the patient body surface. Position setting becomes difficult. In an actual treatment site, the final placement of the preferred conductor is determined by applying a high-frequency electrical signal (observing the degree of stimulation that the patient receives and actually causing interference). The placement of the child on the patient's body surface is shifted little by little, and the position of the conductor having the highest stimulating effect is searched with thought and error.
[0006]
  The present invention has been made in view of the above circumstances.EyesThe objective of the present invention is to provide an interference low-frequency treatment device that can easily change the interference site, that is, the stimulation site, without changing the position of the conductor relative to the surface of the patient.The
[0007]
[Means for Solving the Problems]
  in frontNoteIn order to achieve the objective, the present invention is as follows as the first solution. That is, as described in claim 1 in the claims,
  Three or more sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
  External connection terminals that are provided in a number that is a multiple of the number of sets of the high-frequency generating means, and in which the conductors are detachably connected,
  Each of the output units of the high-frequency generating unit is individually connected to each of the external output terminals, and switching unit for changing the connection relationship between the output unit and the external connection terminals;
  Control means for controlling switching of the switching means;
With
  The frequency of the high-frequency electrical signal generated by the three or more sets of high-frequency generating means is set to be three or more as a whole.The stimulation part due to interference between high-frequency electrical signals is changed according to switching by the switching means.
It is like that.
[0008]
  According to the above solution, even if the placement position of the conductor on the surface of the patient body is the same, the relationship between the pair of conductors is changed and the interference site is changed by switching by the switching means. Therefore, the stimulation site can be changed. Also, the interference location can be changed to one location or two or more locations. In addition to the above, since the control means for controlling the switching means is provided, the flexibility (degree of freedom) of how to change the stimulation site or the number of stimulation sites is increased. For example, the change of the stimulation site and the number of stimulation sites can be appropriately set so as to be performed by any automatic, counter-automatic or manual method, or selection between two or more combinations of these change methods (Switching) can be performed as appropriate. In this manner, changing the stimulation site is preferable not only for providing a stimulus over a wider range but also for preventing the same site from being continuously applied. Further, after the stimulation site is changed and the position having the highest stimulation effect is confirmed, the switching mode of the switching means can be maintained in this state.
[0009]
  Preferred embodiments based on the above solution are as set forth in claims 2 and 3 in the claims. That is,
  The number of the high-frequency generating means is three,
  The number of the external connection terminals is set to a multiple of the number of sets of the high-frequency generating means;
  The frequency of the high-frequency electrical signal generated by each of the high-frequency generating means is set to be different from each other, and is set to be three types in total.
(Claim 2). In this case, the effect corresponding to claim 1 can be obtained by using a conventional interference low-frequency treatment device for hexapole interference (three pairs of conductors).
[0010]
  The number of the high-frequency generating means is three,
  The number of the external connection terminals is set to a number larger than a multiple of the number of sets of the high-frequency generating means,
  The frequencies of the high-frequency electrical signals generated by the three sets of high-frequency generating means are set to be different from each other, and are set to be three types as a whole.
(Claim 3). In this case, by using a conventional interference low frequency treatment device for hexapole interference (three pairs of conductors), the stimulation site can be changed in a wider range than in the case corresponding to claim 2. It becomes possible.
[0011]
  In order to achieve the first object, the present invention provides the second solution as follows. That is, as described in claim 4 in the claims,
  Two sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
  6 or moreAn external connection terminal provided and connected to each of the conductors in a detachable manner;
  Each of the output units of the high-frequency generating unit is individually connected to each of the external output terminals, and switching unit for changing the connection relationship between the output unit and the external connection terminals;
  Control means for controlling switching of the switching means;
With
  The frequencies of the high-frequency electrical signals generated by the two sets of high-frequency generating means are set so as to be different from each other, and are set to be two types as a whole.The stimulation part due to interference between high-frequency electrical signals is changed according to switching by the switching means.
It is like that.
[0012]
  According to the above solution, the number of high-frequency generating means is two sets that are the minimum necessary for an interference low-frequency treatment device, and even if the placement positions of the conductors on the patient body surface are the same, the switching means By performing the switching, the relationship between the pair of conductors is changed to change the interference site, and the stimulation site can be changed.
[0013]
  A preferred mode based on the first solution technique and the second solution technique is as described in claims 5 to 14 in the claims. That is,
  in frontThe control means can control to automatically and sequentially switch the connection relationship between the output section and the external connection terminal (corresponding to claim 5). In this case, it is possible to perform a treatment that automatically and sequentially changes the stimulation site.
[0014]
  A switching command switch for manually commanding switching by the switching means;
  The control means is set to switch the connection relationship between the output unit and the external connection terminal when the switch command switch is operated.
(Corresponding to claim 6). In this case, the stimulation site can be easily and sequentially changed according to the patient's request.
[0015]
  A selection command switch for manually selecting a connection relationship between the output unit and the external connection terminal;
  Storage means for storing a connection relationship between the output unit and the external connection terminal when the selection command switch is operated;
Further comprising
  The control means includes a first control means for automatically and sequentially switching connection relationships that the switching means can take in order to give the storage means an opportunity to perform storage, and after the control of the first control means, the storage means Second control means for controlling the switching means so as to have a connection relationship stored in the means,
(Corresponding to claim 7). In this case, it is possible to preliminarily select a stimulation site preferable for the patient (use of the first control unit and the storage unit) and perform intensive treatment on the selected preferable stimulation site.
[0016]
  The storage means is set to store one connection relationship;
  The second control means controls the switching means so as to have one connection relation stored in the storage means;
(Claim 8). In this case, it is possible to concentrate and treat only the most preferable one preselected stimulation site.
[0017]
  The storage means is set to store two or more connection relationships;
  The second control means controls the switching means so that a plurality of connection relationships stored in the storage means are automatically and sequentially switched;
(Corresponding to claim 9). In this case, the stimulation sites can be automatically and sequentially changed within a range of a plurality of preferable stimulation sites selected in advance.
[0018]
  A non-interference state that does not cause interference between high-frequency electrical signals for a predetermined time can be obtained (corresponding to claim 10). In this case, by providing a time zone during which no stimulus is given, it is preferable to prevent a situation in which the patient becomes chronic with respect to the stimulus and enhance the therapeutic effect.
[0019]
  The switching means is provided inside an interference low frequency treatment device body incorporating the high frequency generation means,
  The external connection terminal is provided on the outer surface of the interference low frequency treatment device body,
(Corresponding to claim 11). In this case, the casing for covering the switching means can be shared by the interference low-frequency treatment device body itself.
[0020]
  It has an input terminal connected to the high-frequency generating means on the outer surface and the external connection terminal, and includes a casing provided with the switching means for changing the connection relationship between the input terminal and the external connection terminal inside,
  The casing is provided outside the interference low-frequency treatment device body incorporating the high-frequency generation means,
(Corresponding to claim 12). In this case, the present invention can be implemented while effectively using the existing interference low-frequency treatment device.
[0021]
  The switching means may be constituted by a plurality of changeover switches (corresponding to claim 13). In this case, the switching means can be configured simply and inexpensively using an electromagnetic switch.
[0022]
  The above-mentioned conductors are equipped in two suction cups,
  Switching of the connection relationship by the switching means is performed between two conductors in the suction cup.
(Corresponding to claim 14). In this case, it is preferable for easily grasping which conductor the connection relationship is changed between.
[0023]
  in frontNoteIn order to achieve the objective, the present invention is as follows as the third solution. That is, as described in claim 15 in the claims,
  Three or more sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
  External connection terminals that are provided in a number that is a multiple of the number of sets of the high-frequency generating means, and in which the conductors are detachably connected,
  Switching means for individually connecting each output part of the high-frequency generating means to each external output terminal, and changing the connection relationship between the output part and the external connection terminal according to a manual operation;
With
  The frequency of the high-frequency electrical signal generated by the three or more sets of high-frequency generating means is set to be three or more as a whole.The stimulation part due to interference between high-frequency electrical signals is changed according to switching by the switching means.
It is like that. According to the above solution, an effect similar to the effect corresponding to claim 1 can be obtained except when the control means is not provided.
[0024]
  In order to achieve the above object, the present invention provides the fourth solution as follows. That is, as described in claim 16 in the claims,
  Two sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
  6 or moreAn external connection terminal provided and connected to each of the conductors in a detachable manner;
  Switching means for individually connecting each output part of the high-frequency generating means to each external output terminal, and changing the connection relationship between the output part and the external connection terminal according to a manual operation;
With
  The frequencies of the high-frequency electrical signals generated by the two sets of high-frequency generating means are set so as to be different from each other, and are set to be two types as a whole.The stimulation part due to interference between high-frequency electrical signals is changed according to switching by the switching means.
It is like that. According to the above solution, an effect similar to the effect corresponding to claim 4 can be obtained except that the control means is not provided.
[0025]
[0026]
[0027]
【The invention's effect】
  According to the present invention, the stimulation site can be easily changed without changing the arrangement position of the conductor with respect to the patient body surface.The
[0028]
DETAILED DESCRIPTION OF THE INVENTION
  In FIG. 1, K1 is a main body casing of the interference low frequency treatment device. The main body casing K1 is schematically shown by wavy lines in FIG. In the main body casing K1, output circuits 1, 2, and 3 are disposed as high frequency generating means. The output circuits 1 to 3 each output two types of paired high-frequency electrical signals. That is, the output circuit 1 is for the first channel, and outputs the first type high frequency electric signals A1 and A2 that form a pair and the second type high frequency electric signals B1 and B2 that form a pair. ing. The output circuit 2 is for the second channel, and outputs the first type high frequency electrical signals C1 and C2 that form a pair and the second type high frequency electrical signals D1 and D2 that form a pair. . The output circuit 3 is for the third channel, and outputs a first type of high-frequency electric signals E1 and E2 that form a pair and a second type of high-frequency electric signals F1 and F2 that form a pair. .
[0029]
  A total of twelve output terminals 11a, 11b, 12a, 12b... 16a, 16b are disposed on the outer surface of the main casing 1 so that a part of the outer casing 11 is exposed to the outside. In relation to the output circuit 1, the output terminal 11a is fixedly set so that the high-frequency electric signal A1 from the output circuit 1 is applied, and the high-frequency electric signal from the output circuit 1 is applied to the output terminal 11b. The setting is fixed so that the signal A2 is applied. The output terminal 12a is fixedly set so that the high frequency electric signal B1 from the output circuit 2 is applied, and the high frequency electric signal B2 from the output circuit 1 is applied to the output terminal 12b. Is fixed so that.
[0030]
  In relation to the output circuit 2, the output terminal 13a is fixedly set so that the high-frequency electric signal C1 from the output circuit 2 is applied, and the high-frequency electric signal from the output circuit 2 is applied to the output terminal 13b. The signal C2 is fixedly set to be applied. Further, the output terminal 14a is fixedly set so that the high frequency electric signal D1 from the output circuit 2 is applied, and the high frequency electric signal D2 from the output circuit 2 is applied to the output terminal 14b. Is fixed so that.
[0031]
  In relation to the output circuit 3, the output terminal 15a is fixedly set so that the high-frequency electric signal E1 from the output circuit 3 is applied, and the high-frequency electric signal from the output circuit 3 is applied to the output terminal 15b. The setting is fixed so that the signal E2 is applied. Further, the output terminal 16a is fixedly set so that the high frequency electric signal F1 from the output circuit 3 is applied, and the high frequency electric signal F2 from the output circuit 3 is applied to the output terminal 16b. Is fixed so that.
[0032]
  As described above, in the embodiment, the output terminals 11a, 11b to 16a, and 16b are substantially set so as to also serve as the output units 1a, 2a, or 3a of the output circuits 1 to 3 as high-frequency generating means. (In FIG. 1, each of the output units 1a to 3a is depicted as one, but actually there are four locations). Further, each of the output circuits 1 to 3 is set to output two sets of high-frequency electric signals to be paired so that two-pole interference can be performed independently.
[0033]
  The frequency of the high frequency electrical signal is set as follows, for example. First, the paired high-frequency electrical signals A1 and A2 are set to a high-frequency frequency “H”. The frequency of the paired high-frequency electric signals B1 and B2 is a high-frequency frequency “H + α” (α is a low frequency). The frequency of the paired high-frequency electrical signals C1 and C2 is a high-frequency frequency “H + 2α” (α is a low frequency). The frequency of the paired high-frequency electrical signals D1 and D2 is a high-frequency frequency “H-α” (α is a low frequency). The frequencies of the paired high-frequency electrical signals E1 and E2 are the same frequency “H” as A1 and A2. The frequency of the paired high-frequency electrical signals F1 and F2 is the same frequency “H + α” (α is a low frequency) as B1 and B2.
[0034]
  Thus, the frequency of the two sets of high-frequency electrical signals for each channel is set so as to differ by the low frequency. Further, as will be described later, the connection terminals 11a, 11b and 12a, and 12b and 13a, 13 used simultaneously for hexapole interference have different frequencies so as to be different from each other by a low frequency. . Furthermore, since the third channel is only used independently, the same frequency as that of the other channels is set so that the types of generated frequencies are reduced as much as possible.
[0035]
  On the outer surface of the main body casing K1, output adjustment switches (volumes) VR1, VR2, and VR3 that are manually operated are provided corresponding to the three output circuits 1, 2, and 3, respectively. Further, a mode switching (selection) switch SW1 that is manually operated is provided on the outer surface of the main body casing K1. This mode changeover switch SW1 utilizes a part of the output circuit 2 in addition to the single mode for low-frequency treatment of quadrupole interference that uses each of the output circuits 1 to 3 independently. The mode is switched to a joint mode for performing low-frequency treatment of hexapole interference. The output circuit 3 is always used exclusively for low-frequency treatment with quadrupole interference.
[0036]
  The main body casing K1 is equipped with a controller U1 configured using a microcomputer. The controller U1 receives inputs from the output adjustment switches VR1 to VR and gives target outputs to the output circuits 1, 2, and 3. That is, when the above-described single mode is selected by the mode switch SW1, the output adjustment of the output circuit 1 is performed by the output adjustment switch VR1, and the output adjustment of the output circuit 2 is performed by the output adjustment switch VR2. The output adjustment of the output circuit 3 is performed by the output adjustment switch VR3. When the above-mentioned common mode is selected by the mode changeover switch SW1, the output adjustment of the output circuits 1 and 2 is performed by the output adjustment switch VR1 (the output sizes of the output circuits 1 and 2 are the same). )
[0037]
  In FIG. 2, J1 to J6 are conductors equipped on the patient body surface. The conductors J1 to J6 are installed in the suction cap as is known, and are arranged so as not to easily move or drop from the patient body surface using the suction force of the suction cap. In FIG. 2, K2 is a switching device that constitutes switching means. In the switching device K2, a plurality of electromagnetic or electronic switching switches such as relay switches are provided.
[0038]
  The external surface of the casing of the switching device K2 is equipped with six external connection terminals M1 to M6 corresponding to the number of the conductors J1 to J6, and the connection terminals 11a, 11b to 13a, 13b described above. Six input terminals N1 to N6 having a number corresponding to the number of are provided. The connection relationship between each of the terminals M1 to M6 and N1 to N6 can be changed, and a specific circuit configuration for that purpose is shown in FIG. In FIG. 3, a total of three electromagnetic relay switches R1 to R3 are provided in the switching device K2.
[0039]
  The relay switch R1 is for changing the connection relationship between the external connection terminals M1 and M2 and the input terminals N1 and N2 (the state where M1 and N1 are connected and M2 and N2 are connected) And switching between a state in which M1 and N2 are connected and M2 and N1 are connected). The relay switch R2 is used for changing the connection relationship between the external connection terminals M3 and M4 and the input terminals N3 and N4. The relay switch R3 is for changing the connection relationship between the external connection terminals M5 and M6 and the input terminals N5 and N6.
[0040]
  The conductors J1 to J6 are individually detachably connected to the external connection terminals M1 to M6 through wiring, and an example of the connection is shown in FIG. Further, the connection terminals 11a, 11b to 13a to 13b are individually connected to the input terminals N1 to N6. An example of the connection is shown in FIG. In the connection example of FIG. 3, a state is shown in which the conductors J1 to J6 are arranged at substantially equal intervals on a substantially circumference. The relay switch R1 is for changing the applied high-frequency electrical signal between the conductors J1 and J6, and the relay switch R2 is for changing the applied high-frequency electrical signal between the conductors J2 and J3. Thus, the relay switch R3 is for changing the high-frequency electrical signal applied between the conductors J4 and J5.
[0041]
  FIG. 3 shows a case where all of the relay switches R1 to R3 are OFF. In this state, the high frequency electrical signal A1 is applied to the conductor J1, the high frequency electrical signal C1 is applied to the conductor J2, the high frequency electrical signal B2 is applied to the conductor J3, and the high frequency electrical signal A2 is applied to the conductor J4. Then, the high frequency electrical signal C2 is applied to the conductor J5, and the high frequency electrical signal B1 is applied to the conductor J6. That is, the paired high-frequency electrical signals A1 and A2 are given on a 180-degree diagonal line, the paired high-frequency electrical signals B1 and B2 are given on a 180-degree diagonal line, and the paired high-frequency electrical signals C1 and C2 Is given on a 180 degree diagonal.
[0042]
  In the above-described application of the three sets of high-frequency electric signals A1, A2 to C1, and C2 as shown in FIG. 3, the intersection or the vicinity of the pair of conductors (high-frequency electric signals) is on the circumference. One of the centers of the conductors J1 to J6 disposed in the center is an interference site (treatment site) T1 in which high-frequency electrical signal interference occurs.
[0043]
  When only the relay switch R1 is switched ON from the state of FIG. 3, the type of the applied high-frequency electrical signal is changed between the two conductors J1 and J6. At this time, there are two interference sites, T2 and T3 as a whole, and the interference sites T2 and T3 are located at positions different from the interference site T1 in FIG.
[0044]
  Similarly, FIG. 5 shows a case where only the relay switch R2 is switched ON. In this case, as in the case of FIG. 4, there are two interference sites, T4 and T5. FIG. 6 shows a case where only the relay switch R3 is switched ON (interference sites are T6 and T7). FIG. 7 shows a case where the relay switches R1 and R2 are switched ON. In this case, the interference site is one location of T8. FIG. 8 shows a case where the relay switches R2 and R3 are switched to ON. In this case, the interference site is one location T9. FIG. 9 shows a case where the relay switches R1 and R3 are switched ON. In this case, the interference site is one location of T10. FIG. 10 shows a case where all of the relay switches R1 to R3 are switched ON. In this case, there is no interference site. The interference sites T1 to T10 described above are positions that are different from each other.
[0045]
  In order to automatically switch and control a plurality of switching modes (connection relationships) shown in FIGS. 3 to 10, a controller U2 configured using a microcomputer is provided. This controller U2, together with the switching device K2, is installed outside the main body casing K1 of the interference low frequency treatment device, and receives a control signal from the controller U1. That is, when the common mode for performing the six-pole interference is selected by the mode changeover switch SW1, a signal indicating that this common mode has been selected is output to the controller U2.
[0046]
  An example of control of the switching device K2 by the controller U2 will be described with reference to the flowchart of FIG. 11, where Q indicates a step in the following description. First, in Q1, a signal is received from the controller U1 that the joint mode for 6-pole interference has been selected (the output adjustment switch VR1 is used as the two output circuits 1 and 2). Is confirmed, in Q2, all the relay switches R1 to R3 are turned OFF (state of FIG. 3). Thereafter, in Q3, the relay switches R1 to R3 are sequentially switched at predetermined time intervals (for example, every 10 seconds), for example, in the order shown in FIGS. 3, 4, 5,... . Thereby, the interference part used as a treatment part is changed automatically. The output adjustment is performed by only one output adjustment switch VR1.
[0047]
  After Q3, at Q4, it is determined whether or not a treatment time set by a manually operated treatment time setting timer (not shown) has elapsed. If the determination in Q4 is NO, it is determined in Q5 whether or not the manually operated selection switch SW2 (see FIG. 2) has been turned ON. When the determination in Q5 is NO, the above-described sequential automatic switching control is continued. When the determination in Q5 is YES, in Q6, it is fixed to one specific switching mode that is executed when the selection switch SW2 is turned on (no sequential automatic switching).
[0048]
  After Q6, at Q7, it is determined whether or not the set treatment time has elapsed. If the determination in Q7 is NO, it is determined in Q8 whether or not the release switch SW3 (see FIG. 2) for instructing the release of the manually operated fixed control is turned on. When the determination in Q8 is NO, the control of Q6 is continued as it is, and the specific one switching mode is maintained. When the determination in Q8 is YES, the control for the one specific switching mode is canceled and the control returns to the sequential automatic switching control in Q3. When YES is determined in Q4 or Q7, the control is ended because the treatment is ended.
[0049]
  FIG. 12 shows another control example of the controller U2. In this control example, one or more switching modes are manually selected from a plurality of switching modes in advance, and automatic sequential switching is performed in one or more manually selected switching modes. It is. First, if YES is determined in Q21 corresponding to Q1 in FIG. 11, for example, all relay switches R1 to R3 are turned OFF in Q22. Thereafter, in Q23, it is determined whether or not the manually operated selection switch SW4 (see FIG. 2) is turned on. If the determination in Q23 is YES, in Q24, the switching mode when the selection switch SW4 is turned on is stored in the storage means (memory), and then the process proceeds to Q26.
[0050]
  If the determination in Q23 is NO, it is determined whether or not a predetermined time (for example, 3 to 5 seconds) has elapsed since the switching mode was selected in Q22. If NO in Q25, the process returns to Q23 (setting of a margin time to be selected). If YES in Q25, the process proceeds to Q26.
[0051]
  In Q26, the relay switch R1 to R3 is changed to the next combination of ON and OFF. Thereafter, in Q27, it is determined whether or not all combinations of ON and OFF of the relay switches R1 to R3 are provided. If NO in Q27, the process returns to Q23. In this way, one or more specific switching modes preferred by the patient among all switching modes are stored in the storage means.
[0052]
  If YES in Q27, since the preferred switching mode has been selected by the patient in Q28, automatic switching is performed sequentially in the range of one or more specific switching modes stored in the storage means. . After Q28, at Q29, it is determined whether or not a preset treatment time has elapsed. When Q29 is NO, the control of Q28 is continued. If the determination in Q29 is YES, the control is terminated because the treatment time has elapsed.
[0053]
  13 to 15 show examples of setting interference sites other than those shown in FIGS. 3 to 10 (interference sites are indicated by T11, T12, or T13). However, since the interference site as shown in FIGS. 13 to 15 cannot be obtained with the circuit configuration shown in FIG. 3, it is necessary to add a relay switch or change the connection relationship.
[0054]
  16 to 18 show a case where octupole interference is performed in a case where a total of four pairs of conductors are provided, and when four sets having different frequencies are used as high frequency electric signals to be paired. This shows an example of changing the interference site. That is, a total of eight conductors J1 to J8 are arranged in one suction cap L1, L2, L3 or L4 as a pair of two. And the kind of the high frequency electric signal applied is changed between the two conductors in the one suction cap L1 (L2, L3, L4). FIG. 16 shows a case where one interference site T21 is obtained. FIG. 17 shows the interference site obtained when the type of the applied high-frequency electrical signal is changed only between the conductors J1 and J2 from the example of FIG. T26 will be a total of 5 locations.
[0055]
  FIG. 18 shows an interference site obtained when the type of the applied high-frequency electrical signal is changed only between the conductors J3 and J4 from the state of FIG. T30 will be a total of 4 locations. What is necessary is just to perform switching control suitably between several switching modes as shown in FIGS. 16-18, and to change the interference site | part and the number of interference site | parts. Note that a specific example of the switching device for performing such switching (for example, setting of connection relation using a relay switch) can be appropriately configured, and therefore the specific example as shown in FIG. 3 is omitted.
[0056]
  FIGS. 19 to 22 each show an example of changing the correspondence relationship of a pair of conductors when hexapole interference is used and eight conductors are used. The interference part is shown as T31 in FIG. , T32, in FIG. 20, indicated by T33, in FIG. 21, indicated by T34, T35, and in FIG. 22, indicated by T36, T37.
[0057]
  23 to 25 show a case where eight conductors J1 to J8 are provided in the case of performing quadrupole interference. In this example, in each switching mode, the total number of conductors to which high-frequency electrical signals are applied is four, and the remaining four are in a state in which high-frequency electrical signals are not applied. That is, the number of conductors larger than the number of conductors in a pair is used, and the interference site is changed by changing the conductor to which the high-frequency electric signal is actually applied. .
[0058]
  In the switching mode of FIG. 23, J4 and J7 constitute a pair of conductors to which a high-frequency electric signal is actually applied, and similarly J3 and J8 are another pair of conductors to which a high-frequency electric signal is actually applied. Configure. The interference site is indicated by T41.
[0059]
  In the switching mode of FIG. 24, J3 and J6 constitute a pair of conductors to which a high-frequency electric signal is actually applied, and similarly J2 and J7 constitute another pair of conductors to which a high-frequency electric signal is actually applied. Configure. The interference site is T42, which is an upper position than in the case of FIG.
[0060]
  In the switching mode of FIG. 25, J2 and J5 constitute a pair of conductors to which a high frequency electrical signal is actually applied, and similarly J1 and J6 constitute another pair of conductors to which a high frequency electrical signal is actually applied. Configure. The interference site is T43, which is an upper position than in the case of FIG.
[0061]
[0062]
  Although the embodiment has been described above, the present invention is not limited to this, and includes, for example, the following cases. The switching device K2 shown in FIGS. 1 to 3 shows an embodiment in which a function can be added to an existing interference low-frequency treatment device when it is installed outside the main body casing K1 of the interference low-frequency treatment device. However, it is also possible to equip the main body casing K1 with the switching device K2. In this case, the connection terminals 11a, 11b to 16a, 16b constitute external connection terminals to which the conductors are detachably connected. Further, the controller U2 in the main body casing K1 can have the function of the controller U2 so that the controllers can be integrated into one.
[0063]
  In the control example of FIG. 11, only automatic sequential switching may be controlled (steps Q5 to Q8 are unnecessary). Further, the control of Q5 to Q6 may be performed, while the release control of Q8 may not be performed.
[0064]
  In the control example of FIG. 12, the selection switch SW3 in Q23 may select a switching mode that is not included in the switching control performed in Q28. That is, the selection switch SW3 selects a switching mode that is not used for switching the switching mode (selects the switching mode to be excluded), and the stored content in Q24 is that the selection switch SW3 is turned on in Q23. The content may exclude the switching mode at that time.
[0065]
  When a plurality of switching modes are set in advance, it is not necessary to set all the switching modes that can be selected by the switching device K2. For example, switching is performed within the range of some switching modes that can be selected by the switching device K2. You may make it control. In particular, in the case of eight-pole interference or more, the number of conductors is extremely large, while the number of possible switching modes is extremely large. Therefore, it can be taken in order to simplify the switching device K2 and avoid the complexity of control. It is preferable to perform switching control by limiting to some switching modes among all switching modes. Furthermore, it can be set so that treatment is performed with only one switching mode finally selected from a plurality of possible switching modes (for example, the switching mode stored in Q24 of FIG. 12 is selected). Only the latest switching mode when the switch SW3 is operated).
[0066]
  As understood from the examples of FIGS. 23 to 25, it is not necessary to apply a high-frequency electric signal to all the conductors used. That is, the number of conductors needs to be a multiple of the number of pairs of high-frequency electrical signals to be paired, but the number of conductors can be a number equal to or more than this multiple. In addition, the arrangement example of the conductor shown in the embodiment is adopted to clearly show how the interference site is changed, and the arrangement of the conductor itself depends on the treatment site and the like. The conductor can be changed as appropriate (in particular, the conductor is not limited to a plane but can also be arranged in three dimensions).
[0067]
If there are two or more types of high-frequency electrical signals used for interference,Although it is good, it is possible to increase the number of high frequency electrical signal interference sites, i.e. stimulation sites, by using 3 or more sets.It is not necessary to set half of the number of conductors. For example, in the case of octupole interference, at least four pairs of conductors are required (eight conductors as a whole), but the number of high-frequency electrical signals to be used can be set to, for example, three. However, in this case, there may be a case where interference does not occur at a portion where lines connecting the pair of conductors intersect.
[0068]
  It may be a case where the controller U2 as the control means is not provided. That is, the switching mode can be switched by a manually operated switch. In this case, for example, for a switching mode that is not very stimulating, the switching command switch is immediately skipped by manually operating the switching mode and changed to the next switching mode, so that the switching mode that the stimulation effect is good is experienced. About the aspect, it can be set as the switching aspect according to a patient's liking, such as maintaining the state for a comparatively long time, and switching to the next switching aspect, when irritation becomes chronic.
[0069]
  In order to prevent chronic stimulation, a time zone in which no interference occurs can be set. In this case, in a time zone in which no interference occurs, the switching mode itself may not cause interference (there is an output from the output circuit circuit), or the output itself from the output circuit is temporarily interrupted. (In this case, the switching mode itself may be capable of causing interference, or may be a switching mode that is not capable of causing interference). 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 system diagram of an interference low-frequency treatment device main body showing an example of the present invention.
FIG. 2 is a system diagram showing a switching device portion used by being connected to an interference low frequency treatment device.
FIG. 3 is a system diagram showing a connection example between a switching device and a conductor.
FIG. 4 is a diagram showing a change in an interference site accompanying a change in a switching mode of the switching device.
FIG. 5 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 6 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 7 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 8 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 9 is a diagram showing a change in an interference site accompanying a change in a switching mode of the switching device.
FIG. 10 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 11 is a flowchart showing an example of control for changing the switching mode.
FIG. 12 is a flowchart showing another control example for changing the switching mode.
FIG. 13 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 14 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 15 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 16 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 17 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 18 is a diagram showing a change in an interference site accompanying a change in the switching mode of the switching device.
FIG. 19 is a diagram showing a change in an interference site accompanying a change in the switching mode of the switching device.
FIG. 20 is a diagram showing a change in an interference site accompanying a change in a switching mode of the switching device.
FIG. 21 is a diagram showing a change in an interference site accompanying a change in the switching mode of the switching device.
FIG. 22 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 23 is a diagram showing a change in an interference site accompanying a change in a switching mode of the switching device.
FIG. 24 is a diagram showing a change of an interference site accompanying a change of a switching mode of the switching device.
FIG. 25 is a diagram showing a change in an interference site accompanying a change in the switching mode of the switching device.
[Explanation of symbols]
K1: Body casing of interference low frequency treatment device
K2: switching device (switching means)
U1: Controller
U2: Controller
A1, A2: A pair of high-frequency electrical signals
B1, B2: A pair of high-frequency electric signals
C1, C2: A pair of high frequency electrical signals
D1, D2: A pair of high frequency electrical signals
E1, E2: a pair of high frequency electrical signals
F1, F2: a pair of high frequency electrical signals
J1-J6: Doshiko
SW1 to SW4: Manual switch
M1 to M6: External connection terminals
NI to N6: input terminals
R1-R3: Relay switch
T1-43: Interference site
1-3: Output circuit (high frequency generating means)
1a-3a: Output part
11a, 11b to 16a, 16b: connection terminals

Claims (16)

Three or more sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
External connection terminals that are provided in a number that is a multiple of the number of sets of the high-frequency generating means, and in which the conductors are detachably connected,
Each of the output units of the high-frequency generating unit is individually connected to each of the external output terminals, and switching unit for changing the connection relationship between the output unit and the external connection terminals;
Control means for controlling switching of the switching means;
With
The frequency of the high-frequency electrical signals generated by the three or more sets of high-frequency generating means is set to be three or more as a whole, and the stimulation site due to the interference between the high-frequency electrical signals according to the switching by the switching means Be changed,
An interference low frequency treatment device characterized by that. In claim 1,
The number of the high-frequency generating means is three,
The number of the external connection terminals is set to a multiple of the number of sets of the high-frequency generating means;
The frequency of the high-frequency electrical signal generated by each of the high-frequency generating means is set to be different from each other, and is set to be three types in total.
An interference low frequency treatment device characterized by that. In claim 1,
The number of the high-frequency generating means is three,
The number of the external connection terminals is set to a number larger than a multiple of the number of sets of the high-frequency generating means,
The frequencies of the high-frequency electrical signals generated by the three sets of high-frequency generating means are set to be different from each other, and are set to be three types as a whole.
An interference low frequency treatment device characterized by that. Two sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
6 or more external connection terminals to which the conductors are detachably connected,
Each of the output units of the high-frequency generating unit is individually connected to each of the external output terminals, and switching unit for changing the connection relationship between the output unit and the external connection terminals;
Control means for controlling switching of the switching means;
With
The frequencies of the high-frequency electrical signals generated by the two sets of high-frequency generating means are set so as to be different from each other and are set to be two types as a whole, and the high-frequency electrical signals are set in accordance with switching by the switching means. The stimulation site due to interference is changed,
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 4,
The control means controls to automatically and sequentially switch the connection relationship between the output unit and the external connection terminal,
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 4,
A switching command switch for manually commanding switching by the switching means;
The control means is set to switch the connection relationship between the output unit and the external connection terminal when the switch command switch is operated.
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 4,
A selection command switch for manually selecting a connection relationship between the output unit and the external connection terminal;
Storage means for storing a connection relationship between the output unit and the external connection terminal when the selection command switch is operated;
Further comprising
The control means includes a first control means for automatically and sequentially switching connection relationships that the switching means can take in order to give the storage means an opportunity to perform storage, and after the control of the first control means, the storage means Second control means for controlling the switching means so as to have a connection relationship stored in the means,
An interference low frequency treatment device characterized by that. In claim 7,
The storage means is set to store one connection relationship;
The second control means controls the switching means so as to have one connection relation stored in the storage means;
An interference low frequency treatment device characterized by that. In claim 7,
The storage means is set to store two or more connection relationships;
The second control means controls the switching means so that a plurality of connection relationships stored in the storage means are automatically and sequentially switched;
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 9,
An interference low-frequency treatment device characterized in that it can be in a non-interference state that does not cause interference between high-frequency electrical signals for a predetermined time. In any one of Claims 1 thru | or 10,
The switching means is provided inside an interference low frequency treatment device body incorporating the high frequency generation means,
The external connection terminal is provided on the outer surface of the interference low frequency treatment device body,
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 10,
It has an input terminal connected to the high-frequency generating means on the outer surface and the external connection terminal, and includes a casing provided with the switching means for changing the connection relationship between the input terminal and the external connection terminal inside,
The casing is provided outside the interference low-frequency treatment device body incorporating the high-frequency generation means,
An interference low frequency treatment device characterized by that. In any one of Claims 1 thru | or 12,
The interference low-frequency treatment device, wherein the switching means includes a plurality of change-over switches. 14. In any one of claims 1 to 13,
The above-mentioned conductors are equipped in two suction cups,
Switching of the connection relationship by the switching means is performed between two conductors in the suction cup.
An interference low frequency treatment device characterized by that. Three or more sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
External connection terminals that are provided in a number that is a multiple of the number of sets of the high-frequency generating means, and in which the conductors are detachably connected,
Switching means for individually connecting each output part of the high-frequency generating means to each external output terminal, and changing the connection relationship between the output part and the external connection terminal according to a manual operation;
With
The frequency of the high-frequency electrical signals generated by the three or more sets of high-frequency generating means is set to be three or more as a whole, and the stimulation site due to the interference between the high-frequency electrical signals according to the switching by the switching means Be changed,
An interference low frequency treatment device characterized by that. Two sets of high-frequency generating means each having a pair of output units for outputting high-frequency electrical signals;
6 or more external connection terminals to which the conductors are detachably connected,
Switching means for individually connecting each output part of the high-frequency generating means to each external output terminal, and changing the connection relationship between the output part and the external connection terminal according to a manual operation;
With
The frequencies of the high-frequency electrical signals generated by the two sets of high-frequency generating means are set so as to be different from each other and are set to be two types as a whole, and the high-frequency electrical signals are set in accordance with switching by the switching means. The stimulation site due to interference is changed,
An interference low frequency treatment device characterized by that.

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