JP2010172562A - Electrical muscle stimulation belt - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrical muscle stimulation belt for obtaining a sufficient training effect by giving an electrical stimulation to a muscle in the deep part of a body. <P>SOLUTION: The electrical muscle stimulation belt for electrically stimulating the muscle inside the body of a user includes: a belt body to be mounted by winding onto the body of the user; at least one first paired electrodes to be arranged on an abutment surface of the belt body onto the body of the user; a first common electrode electrically connected to the belt body and fixed to a position opposing to the first paired electrodes by abutment onto the body of the user; a first supply part for supplying a low-frequency pulse voltage to a part between the first common electrode and the respective first paired electrodes; a plurality of electrodes to be arranged on the abutment surface of the belt body; and a second supply part for supplying the low-frequency pulse voltage to a part between a second common electrode and respective second paired electrodes by defining one of the respective electrodes as the second common electrode and defining the respective electrodes other than the second common electrode as the second paired electrodes. The belt is obtained by combining two or more respective electrodes and parts. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electric muscle stimulation belt which is wound around a user's body and performs treatment by electrically stimulating muscles inside the user's body.

  Traditionally, treatments for muscle training and slimming are performed by bringing electrodes into contact with predetermined parts of the body such as the abdomen, arms, and legs, applying a pulsed low-frequency voltage, and electrically stimulating the muscles. An electromuscular stimulation device to perform is known (for example, see Patent Document 1 below).

JP 2005-13593 A

  However, the above-described conventional electric muscle stimulating device cannot provide stimulation to the muscles in the deep part of the body and cannot obtain a sufficient effect.

  The present invention adopts the following configuration in order to solve the above points.

<Constitution>
An electric muscle stimulation belt according to the present invention is provided between a belt main body wound around a user's body and electrically attached to the user's body to electrically stimulate muscles inside the user's body. At least one first counter electrode disposed on the contact surface, and a first common electrode that is electrically connected to the belt body and is in contact with and fixed to the user's body at a position facing each first counter electrode One of an electrode, a first supply unit that supplies a low-frequency pulse voltage between the first common electrode and each first counter electrode, a plurality of electrodes disposed on the contact surface of the belt body, and each electrode A second supply electrode for supplying a low-frequency pulse voltage between the second common electrode and each second counter electrode, with one electrode being a second common electrode and each electrode excluding the second common electrode being a second counter electrode; A first counter electrode, a first common electrode and a first supply unit, and a plurality of electrodes and a second supply unit. Characterized in that it comprises in combination or One.

  According to the electromuscular stimulation belt of the present invention, for example, energization is performed between each electrode brought into contact with the front and back of the body and between each electrode brought into contact with both side surfaces. It is possible to apply electrical stimulation to the muscles of the human body. Therefore, more effective muscle training is possible, and the viscera can be stimulated and activated, so that the slimming effect can be obtained by reducing visceral fat.

1 is a schematic configuration diagram of an electric muscle stimulation belt according to an embodiment of the present invention. It is a block diagram which shows the function structure of the controller of the electromuscular stimulation belt which concerns on the Example of this invention. It is a figure which shows the external shape of an 11 pole belt. It is a partial block diagram which shows the example of a connection of an 11 pole belt. It is a figure which shows the external shape of a controller. It is explanatory drawing which shows the signal pattern of a stationary pulse signal. It is explanatory drawing which shows the signal pattern of an EMS signal. It is explanatory drawing which shows the output pattern of 5 pole rotation mode. It is explanatory drawing which shows the output pattern of surge mode. It is a figure explaining the treatment operation | movement of an electromuscular stimulation belt. It is a figure (the 1) which shows the example of mounting | wearing of an electromuscular stimulation belt. It is a figure (the 2) which shows the example of mounting | wearing of an electromuscular stimulation belt. It is FIG. (3) which shows the example of mounting | wearing of an electromuscular stimulation belt. It is a figure explaining the electricity supply between each electroconductive part and 1 pole pad.

  Hereinafter, as an embodiment of the present invention, an example in which each electrode and two supply units that conduct electricity between these electrodes are combined will be described in detail with reference to the drawings.

FIG. 1 is a schematic configuration diagram of an electromuscular stimulation belt according to an embodiment of the present invention.
As shown in FIG. 1, the electric muscle stimulation belt 10 of the present embodiment includes an 11-pole belt 11, a 1-pole pad 12 that is used by being connected to the 11-pole belt, and a controller 13. The

FIG. 5 is a diagram showing the outer shape of the controller.
FIG. 5A is a diagram illustrating the side surface portion 13 a of the controller 13, and FIG. 5B is a diagram illustrating the front surface portion 13 b of the controller 13. FIG. 5C is a diagram showing the side surface portion 13 c of the controller 13.

  The controller 13 has two output systems consisting of CH1 (channel 1) and CH2 (channel 2), outputs a low-frequency pulse signal, and outputs a low-frequency pulse voltage to the 11-pole belt 11 and the 1-pole pad 12. Supply.

  As shown in FIG. 5A, four insertion ports 20-1 to 20-4 are provided on the side surface portion 13 a of the controller 13.

  The insertion ports 20-1a and 20-1b are CH1 output ports. The insertion port 20-1a is an output port for grounding, and is used by inserting a plug 18-1b provided at one end of the connection cord 18-1, as shown in FIG. Moreover, the plug 18-2b provided in the one side edge part of the connection cord 18-2 is inserted in the insertion port 20-1b. The controller 13 supplies a low-frequency pulse voltage to apply electrical stimulation to the muscle at the treatment site via the insertion ports 20-1a and 20-1b corresponding to CH1.

  The insertion ports 20-2a and 20-2b are CH2 output ports. The insertion port 20-2a is an output port for grounding, and is used by inserting the plug 19-1b of the connection cord 19-1 as shown in FIG. Further, as shown in FIG. 1, the plug 19-2b of the connection cord 19-2 is inserted into the insertion port 20-2b. The controller 13 supplies a low-frequency pulse voltage to apply electrical stimulation to the muscle at the treatment site via the insertion ports 20-2a and 20-2b corresponding to CH2.

  As shown in FIG. 5B, the front surface portion 13b of the controller 13 is provided with a liquid crystal panel 21 and six operation buttons.

  The power button 22 is an operation button for turning on / off the power of the controller 13.

The mode button 23 is an operation button for selecting an operation mode.
The electric muscle stimulation belt 10 of the present embodiment has three operation modes that can be selected according to the treatment site. The user presses the power button 22 to turn on the power, and then presses the mode button 23 to select a desired operation mode. When the operation mode is selected, the mode number which is the identification number is displayed on the mode display portion 21a of the liquid crystal panel 21.

  In this embodiment, the mode number “1” corresponds to the “abdomen / flank mode” in which the abdomen and the flank are treated. The mode number “2” corresponds to the “waist / flank mode” in which the waist and flank are treatment sites. The mode number “3” corresponds to the “hip mode” with the buttocks as a treatment site.

  The volume setting buttons 24a and 24b are operation buttons for setting the output level of CH1, and the volume setting buttons 25a and 25b are operation buttons for setting the output level of CH2. In the electric muscle stimulation belt 10 of this embodiment, 0 to 40 output levels can be set. The output levels set for CH1 and CH2 are displayed on the level display portions 21c and 21d of the liquid crystal panel 21, respectively.

  The liquid crystal panel 21 includes a timer display unit 21b in addition to the mode display unit 21a and the level display units 21c and 21d described above. The remaining time of the operation time is displayed on the timer display unit 21b. In the electric muscle stimulation belt 10 of this embodiment, the operation time required for one treatment process is set to 30 minutes.

  As shown in FIG. 5C, a connection port 26 is provided in the side surface portion 13 c of the controller 13. As shown in FIG. 1, a power cord 27 is connected to the connection port 26.

Next, the configuration of the 11-pole belt 11 will be described with reference to FIGS. 1 and 3.
FIG. 3 is a view showing the outer shape of an 11-pole belt.

  The eleven-pole belt 11 is a belt for wrapping around the abdomen and the buttocks. As shown in FIG. 3, the eleven conductive portions 14-1 to 11 and the first connecting portion 15- The connection part 15 which consists of 1 and the 2nd connection part 15-2, and the electricity supply cord 16 are provided.

  Each of the conductive portions 14-1 to 11-11 is made of conductive rubber, and is disposed at a predetermined position on one surface of the 11-pole belt 11. In the present embodiment, the surface of the eleven-pole belt 11 on which the conductive portions 14-1 to 14-11 are provided is referred to as a conductive portion surface 11a. FIG. 1 shows a back surface 11b of the conductive portion surface 11a.

  Among the eleven conductive portions 14-1 to 11-5, five conductive portions 14-1 to 14-5 are arranged at predetermined intervals along the arc as shown in FIG. 3. An energization cord (not shown) is connected to each of the conductive portions 14-1 to 14-5.

  As shown in FIG. 3, the conductive portions 14-6 to 8 and the conductive portions 14-9 to 11 are respectively arranged in the longitudinal direction of the 11-pole belt 11 with the five conductive portions 14-1 to 5 therebetween. Arranged substantially linearly. An energization cord (not shown) is also connected to each of the conductive portions 14-6 to 11-11.

  Further, as shown in FIG. 3, a velcro fastener 17 is provided at the longitudinal end of the 11-pole belt 11.

Next, the connection part with the controller 13 of the 11 pole belt 11 is demonstrated using FIG.1 and FIG.4.
FIG. 4 is a partial configuration diagram illustrating a connection example of an 11-pole belt.

  The first connection portion 15-1 includes two input connection ports 15-1 a and 15-1 b in the side surface direction of the 11-pole belt 11. As shown in FIGS. 1 and 4, a connection cord 18 including two connection cords 18-1 and 18-2 is connected to these connection ports 15-1 a and 15-1 b.

  The connection cord 18-1 has plugs 18-1a and 18-1b at both ends, respectively, and the plug 18-1b is connected to the grounding outlet 20-1a corresponding to CH1 in the controller 13. (FIG. 5 (a)). The plug 18-1a of the connection cord 18-1 is inserted into the connection port 15-1a of the first connection portion 15-1, and is electrically connected to the controller 13.

  An energization cord 16 is also connected to the first connection portion 15-1. The energization cord 16 is connected to the output side of the connection port 15-1a, and its end is inserted into the one-pole pad 12, as shown in FIGS. The 1-pole pad 12 is made of a disc-shaped conductive rubber, and is electrically connected to the 11-pole belt 11 and the controller 13 via the energization cord 16 and used as a first common electrode.

  The connection cord 18-2 has plugs 18-2a and 18-2b at both ends, respectively, and the plug 18-2b is connected to the insertion port 20-1a corresponding to CH1 in the controller 13 (FIG. 5). (A)). The plug 18-2a of the connection cord 18-2 is inserted into another connection port 15-1b provided in the first connection portion 15-1, and is electrically connected to the controller 13.

  Five energization cords (not shown) are connected to the output side of the connection port 15-1b. These energization cords are connected to the conductive portions 14-1 to 14-5, respectively. Each of the conductive portions 14-1 to 14-5 forms a 5-channel output system corresponding to CH1 as a pair of the first electrode 12 as a first common electrode as a first counter electrode.

  Similarly to the first connection portion 15-1, the second connection portion 15-2 includes two input connection ports 15-2a and 15-2b in the side surface direction of the 11-pole belt 11. As shown in FIGS. 1 and 4, a connection cord 19 including two connection cords 19-1 and 19-2 is connected to the connection ports 15-2 a and 15-2 b.

  The connection cord 19-1 has plugs 19-1a and 19-1b at both ends, respectively, and the plug 19-1b is connected to the grounding outlet 20-2a corresponding to CH2 in the controller 13. (FIG. 5 (a)). The plug 19-1a of the connection cord 19-1 is inserted into the connection port 15-2a of the second connection portion 15-2 and is electrically connected to the controller 13.

  An energization cord (not shown) is connected to the output side of the connection port 15-2a. This energization cord is connected to the conductive portion 14-11 as the second common electrode.

  The connection cord 19-2 has plugs 19-2a and 19-2b at both ends, respectively, and the plug 19-2b is connected to the insertion port 20-2b corresponding to CH2 in the controller 13 (FIG. 5). (A)). The plug 19-2a of the connection cord 19-2 is inserted into the connection port 15-2b of the second connection portion 15-2 and is electrically connected to the controller 13.

  Five energization cords (not shown) are connected to the output side of the connection port 15-2b. These energization cords are connected to the conductive portions 14-6 to 10, respectively. Each of the conductive portions 14-6 to 10 is paired with a conductive portion 14-11 as a second common electrode as a second counter electrode, and constitutes a 5-channel output system corresponding to CH2.

Next, the control system of the controller 13 will be described with reference to FIG.
FIG. 2 is a block diagram illustrating a functional configuration of the controller of the electric muscle stimulation belt according to the embodiment of the present invention.

  As shown in FIG. 2, the electric muscle stimulation belt 10 includes a power supply circuit 28, a switch circuit 29, a buzzer circuit 30, a display panel unit 31, a channel control unit 32-1, a channel control unit 32-2, and a control unit 33. Consists of including.

  The power supply circuit 28 is a circuit that is connected to a commercial AC power supply via the power supply cord 27 (FIG. 1) and supplies power to each unit.

  The switch circuit 29 includes a power button 22, a mode button 23, and volume control buttons 24a, 24b, 25a, and 25b. The switch circuit 29 generates a corresponding signal based on the operation of each operation button and inputs it to the control unit 33.

  The buzzer circuit 30 outputs a buzzer sound based on the control of the control unit 33 and notifies the end of the operation time, the occurrence of an error, and the like.

  The display panel unit 31 includes the liquid crystal panel 21 and a panel drive circuit (not shown), and displays the mode number, output level, remaining time, etc. of the selected operation mode based on the control of the control unit 33.

  The channel control unit 32-1 and the channel control unit 32-2 include circuits that control the output of the low-frequency pulse signal based on the control of the control unit 33.

  As the first supply unit, the channel control unit 32-1 controls the output via each of the insertion ports 20-1a and 20-1b which are the output ports of CH1, and the steady pulse signal generation unit 34-1 and the EMS A signal generator 35-1 and an output controller 36-1 are provided.

  Similarly, as the second supply unit, the channel control unit 32-2 controls the output via each of the insertion ports 20-2a and 20-2b which are the output ports of CH2, in order to control the steady pulse signal generation unit 34- 2, an EMS signal generator 35-2 and an output controller 36-2 are provided.

The stationary pulse signal generators 34-1 and 3 are composed of a circuit that generates a stationary pulse signal.
FIG. 6 is an explanatory diagram showing a signal pattern of a stationary pulse signal.

  As shown in FIG. 6, the stationary pulse signal is composed of positive and negative pulse signals having a predetermined amplitude voltage Vp and a pulse width Wp, and is output at a pulse frequency fp. Here, the amplitude voltage Vp, the pulse width Wp, and the pulse frequency fp are parameters, and are set according to each operation mode. The steady pulse signal is used to give a rotational stimulus described later to the muscle at the treatment site.

The EMS signal generators 35-1 and 35-2 are configured by a circuit that generates an EMS signal.
FIG. 7 is an explanatory diagram showing a signal pattern of the EMS signal.

  As shown in FIG. 7, the EMS signal is composed of a plurality of pulse signals having a constant pulse width Wp and modulating the output voltage V. The EMS signal generators 35-1 and 35-2 increase the output voltage V of the pulse signal from 0 to a predetermined amplitude voltage Vp, maintain it for a certain time Th, and then decrease it from Vp to 0. Thereafter, the next EMS signal is output across the pause time Tr. If the time required to increase the output voltage V from 0 to Vp is the ramp-up time Tu, and the time required to decrease the output voltage V from 0 is the ramp-down time Td, the energization time To of each EMS signal is To = Tu + Th + Td. The energization time To and the rest time Tr are parameters, and are set according to each operation mode. Further, in the EMS signal, the amplitude voltage Vp, the pulse width Wp of each pulse signal, and the pulse frequency fp are similarly parameters, and are set according to each operation mode. The EMS signal is used to give a surge stimulus to be described later to the muscle at the treatment site.

  The output control units 36-1 and 36-2 have a function of controlling a 5-channel output system in two output modes including a 5-pole rotation mode and a surge mode, which will be described later. That is, the output control unit 36-1 controls output via the CH1 insertion ports 20-1a and 20-1b. Moreover, the output control part 36-2 controls the output via the insertion ports 20-2a and 20-2b of CH2.

FIG. 8 is an explanatory diagram showing an output pattern in the 5-pole rotation mode.
In the 5-pole rotation mode, as shown in FIG. 8, in order to give a rotational stimulus to the muscle of the treatment site, an output of one block consisting of a predetermined energization time To and a rest time Tr is sequentially shifted for each channel. Mode. Each block includes a plurality of stationary pulse signals shown in FIG. In each block, the amplitude voltage Vp and the pulse frequency fp of the stationary pulse signal are kept constant, but the pulse width Wp is modulated in a predetermined time range. The rest time Tr and the energization time To in each block are parameters, and are set according to each operation mode.

FIG. 9 is an explanatory diagram showing a surge mode output pattern.
The surge mode is an output mode for outputting the EMS signal shown in FIG. 7 by shifting the channel for each pulse as shown in FIG. 9 in order to give a surge stimulus to the muscle at the treatment site. The output voltage V of each pulse signal is modulated between 0 and the amplitude voltage Vp. In the present embodiment, the pulse frequency fp of the EMS signal, the energization time To, and the pause time Tr are parameters, and are set according to each operation mode.

  As shown in FIG. 2, the control unit 33 includes a memory 37 and a CPU 38.

The memory 37 stores various programs and data for controlling each part of the controller 13.
The CPU 38 executes a program in the memory 37 to control each unit.

  For example, the memory 37 stores stationary pulse signal data and EMS signal data as signal data of the low-frequency pulse signal. The steady pulse signal generators 34-1 and 3-4 generate a steady pulse signal having the signal pattern shown in FIG. 6 based on the steady pulse signal data. Similarly, the EMS signal generators 35-1 and 35-2 generate EMS signals having the signal pattern shown in FIG. 7 based on the EMS signal data.

  The memory 37 stores pattern data indicating an output pattern according to each output mode. For example, the memory 37 stores rotation pattern data indicating the output pattern shown in FIG. 8 corresponding to the 5-pole rotation mode. The memory 37 stores surge pattern data indicating the output pattern shown in FIG. 9 corresponding to the surge mode.

  Further, the memory 37 stores an operation program corresponding to each operation mode. With these operation programs, the combination data of the 5-pole rotation mode and the surge mode, and the parameter values of the steady pulse signal and the EMS signal are set for each operation mode. In the controller 13 of the electric muscle stimulation belt 10 of the present embodiment, the memory 37 stores three operation programs corresponding to the three operation modes of mode numbers “1” to “3”. The control unit 33 controls the output pattern of the low frequency pulse signal in each CH, that is, the output level and the output timing, based on the operation program corresponding to the selected operation mode.

Next, the operation of the electric muscle stimulation belt 10 of this embodiment will be described.
Here, the operation mode “abdomen / flank mode” is selected and a case where a treatment for the user's abdomen and flank is performed will be described as an example.
FIG. 10 is a diagram for explaining the treatment operation of the electromuscular stimulation belt, and FIG. 11 is a diagram (part 1) showing an example of wearing the electromuscular stimulation belt.

  The controller 13 of the electromuscular stimulation belt 10 is connected to plugs 18-1b and 18-2b of the connection cord 18 at the CH1 insertion ports 20-1a and 20-1b, respectively. The plugs 19-1b and 19-2b of the connection cord 19 are connected to the CH2 insertion ports 20-2a and 20-2b, respectively.

  The other plugs 18-1a and 18-1b of the connection cord 18 are inserted into the CH1 connection ports 15-1a and 15-1b provided in the first connection portion 15-1 of the 11-pole belt 11, respectively. The Similarly, the other plugs 19-1a and 19-1b of the connection cord 19 are inserted into the CH2 connection ports 15-2a and 15-2b provided in the second connection unit 15-2, respectively.

  Further, the end of the energization cord 16 of the 11-pole belt 11 is inserted into the 1-pole pad 12.

  And the 11 pole belt 11 and the 1 pole pad 12 are mounted | worn with a user's abdomen and the back, as FIG. 11 (a) and FIG.11 (b) show.

  Prior to wearing the 11-pole belt 11 and the 1-pole pad 12, the skin surface of the user's treatment site, and the conductive parts 14-1 to 11 of the 11-pole belt 11 and the skin of the 1-pole pad 12 are brought into contact with each other. A conductive gel is applied to the surface. The conduction gel enhances the electrical conductivity at the treatment site and the adhesion of the conductive parts 14-1 to 11 and the monopolar pad 12 to the skin surface, and also protects the skin and prevents rough skin.

  The user first wears the eleven-pole belt 11 wrapped around the abdomen so that the conductive part surface 11a contacts the skin. At this time, the user adjusts the mounting position so that the five conductive portions 14-1 to 14-5 corresponding to CH1 surround the navel, and fixes the eleven-pole belt 11 by the velcro fastener 17 (FIG. 3). The 11-pole belt 11 is preliminarily provided with a center mark at the center of the belt, and the user visually observes the center mark and places it on the umbilicus so that each of the conductive portions 14-1 to 14-5 is placed. It can be placed in an appropriate position. When the eleven-pole belt 11 is worn, the three conductive portions 14-6 to 8 are in contact with the skin surface of the right lateral abdomen on the front and back of the user, and the three conductive portions 14-9 to 11 are front surfaces. And it will contact | abut to the skin surface of the left lateral abdominal part of a back, and will each be arrange | positioned.

  Further, as shown in FIG. 11B, the user inserts and fixes the 1-pole pad 12 between the 11-pole belt 11 and the skin surface of the back. Thereby, the 1 pole pad 12 will contact | abut and be fixed to the skin surface of the back which opposes the five electroconductive parts 14-1-5.

  Then, after the power button 22 of the controller 13 is pressed and the power is turned on, the mode button 23 is pressed and the mode number “1” corresponding to the “belly / flank mode” is selected. Further, the user operates the volume setting buttons 24a, 24b, 25a, and 25b to select a desired output level.

  The switch circuit 29 generates and outputs a corresponding signal based on the operation of each operation button by the user. Based on the input signal from the switch circuit 29, the control unit 33 causes the display panel unit 31 to perform display and also executes an operation program corresponding to the “abdominal / lateral belly mode” of the mode number “1” to Control is performed on the channel control unit 32-1 and the channel control unit 32-2 of CH2.

  The channel control unit 32-1 of CH1 inserts the steady pulse signal and the EMS signal into the insertion port with a predetermined output pattern that combines the 5-pole rotation mode and the surge mode based on the operation program stored in the memory 37. 20-1a.

  Along with this output, the five conductive portions 14-1 to 14-5 of the 11-pole belt 11 are given potentials in order clockwise as indicated by arrows in FIG. 10 with the 1-pole pad 12 as GND. That is, as shown in FIG. 8 or FIG. 9, a low frequency pulse signal is output with each of the conductive portions 14-1 to 14 as ch1 to ch5. The channel control unit 32-1 alternately applies positive and negative pulse potentials to the respective conductive units 14-1 to 14-5 while sequentially switching output destinations.

  When a pulse potential is applied to each of the conductive portions 14-1 to 14-5 serving as the first counter electrode, a pulse-shaped potential difference, that is, a pulse voltage is generated between the first electrode 12 serving as the first common electrode. For example, when a positive potential is applied to the conductive portion 14-1, a pulse voltage is supplied between the conductive portion 14-1 and the 1-pole pad 12. Based on this pulse voltage, a pulse current flows from the conductive portion 14-1 to the one-pole pad 12. Similarly, when a negative potential is applied to the conductive portion 14-1, a pulse voltage having a reverse polarity is generated between the conductive portion 14-1 and the one-pole pad 12, and from the one-pole pad 12 to the conductive portion 14-1. A pulse current will flow.

  A pulse is generated between each of the conductive portions 14-1 to 14-5 disposed so as to contact the user's abdomen and the one-pole pad 12 disposed on the back side so as to face the conductive portions 14-1 to 14-5. When the current is generated, a low-frequency pulse current flows from the user's abdomen to the back or from the back to the abdomen. As a result, electrical stimulation is applied to the muscles inside the user's body.

FIG. 14 is a diagram for explaining energization between each conductive portion and one pole pad.
As described above, positive and negative potentials are alternately applied to the five conductive portions 14-1 to 14-5 of the eleven-pole belt 11. Thereby, as shown in FIG. 14, a positive or negative potential is applied to the skin layer of the skin with which the conductive portions 14-1 to 14-5 come into contact. A one-pole pad 12 is in contact with the opposite skin surface. This one-pole pad 12 acts as GND, and a low frequency pulse voltage is generated between the skin layer to which a potential is applied. As a result, a low-frequency pulse current is generated between the skin layer of the contact surface of the conductive portions 14-1 to 5 and the contact surface of the 1-pole pad 12 as indicated by a broken line in FIG. 14. That is, a low-frequency pulse current flows inside the user's body, and electrical stimulation is applied to the muscles deep in the body.

  Similarly, the channel control unit 32-2 of CH2 outputs a steady pulse signal and an EMS signal with a predetermined output pattern that combines the five-pole rotation mode and the surge mode, based on the operation program stored in the memory 37. It outputs via the insertion port 20-2a. Along with this output, the electric potential is sequentially applied to the five conductive portions 14-6 to 10 of the 11-pole belt 11 with the conductive portion 14-11 as GND. That is, as shown in FIG. 8 or FIG. 9, a low frequency pulse signal is output with each of the conductive portions 14-6 to 10 as ch1 to ch5. The channel control unit 32-2 alternately applies positive and negative pulse potentials to the conductive units 14-6 to 10 while sequentially switching output destinations.

  Thereby, a pulse voltage is generated between each of the conductive portions 14-6 to 10 as the second counter electrode and the conductive portion 14-11 as the second common electrode. Based on this pulse voltage, a pulse current flows between the conductive portions 14-6 to 10 and the conductive portion 14-11.

  When a pulse current is generated between each of the conductive portions 14-6 to 10 disposed so as to contact the left and right flank portions and the conductive portion 14-11 disposed so as to contact the left flank portion A low-frequency pulse current passing through the inside of the body is generated from the left side of the user's body toward the right side or from the right side to the left side. Thereby, electrical stimulation will be given to the muscle of a user's deep body part from the direction different from CH1.

  When the operation time of 30 minutes is finished, the channel control unit 32-1 and the channel control unit 32-2 stop outputting. Based on the control of the control unit 33, the buzzer circuit 30 outputs a buzzer sound to notify the user of the end of the treatment process. Thereby, the electromuscular stimulation belt 10 ends the treatment process.

  As described above, the electric muscle stimulation belt 10 energizes the abdomen and the middle back and between the left and right lateral abdomen, respectively, and applies electrical stimulation from a plurality of directions to the muscles inside the body. By applying this electrical stimulation, a training effect on the trunk muscles is obtained, and effects such as an increase in muscle mass, a decrease in subcutaneous fat, and an increase in basal metabolism are obtained. In addition, edema around the viscera, water content, and visceral fat are expected to decrease. Furthermore, activation of the internal organs is expected, for example, by inducing peristaltic movement of the intestines and eliminating constipation by applying a clockwise rotation stimulus to the abdomen.

When the operation mode “waist / flank mode” is selected and the treatment for the lower back and the abdomen is performed, the user operates the controller 13 to select the mode number “2”. In addition, the eleven-pole belt 11 is worn so that the five conductive portions 14-1 to 14-5 corresponding to CH1 come into contact with the skin surface of the waist.
FIG. 12 is a diagram (part 2) illustrating an example of wearing the electric muscle stimulation belt.

  As shown in FIG. 12B, the eleven pole belt 11 is attached to the user's waist. At this time, the conductive portions 14-6 to 11 of CH2 are fixed in contact with the skin surfaces of the left and right lateral abdominal portions on the front and back sides of the user.

  Further, as shown in FIG. 12A, the 1-pole pad 12 is inserted between the 11-pole belt 11 and the skin surface of the abdomen and fixed on the navel. Thereby, the 1 pole pad 12 will be contact | abutted and fixed to the skin surface of the abdominal part which opposes the five electroconductive parts 14-1-5.

  And when the output by the electromuscular stimulation belt 10 is started, a potential is applied to the skin surface of the user's lower back and flank, and energization is performed inside the body. As a result, electrical stimulation is applied to the lumbar region and muscles inside the body, and effects such as tightening can be obtained.

Further, when the operation mode “hip mode” is selected and the treatment of the buttocks is performed, the user operates the controller 13 to select the mode number “3”. In addition, the eleven-pole belt 11 is mounted so that the five conductive portions 14-1 to 14-5 corresponding to CH1 come into contact with the skin surface of the buttocks.
FIG. 13 is a diagram (part 3) illustrating an example of wearing the electric muscle stimulation belt.

  The 11-pole belt 11 is attached to the user's buttocks as shown in FIG. At this time, the user winds and wears the 11-pole belt 11 so as to lift up the entire buttocks. Further, as shown in FIG. 13A, the 1-pole pad 12 is inserted between the 11-pole belt 11 and the skin surface of the lower abdomen and fixed under the navel. Thereby, the 1 pole pad 12 will be contact | abutted and fixed to the skin surface of the lower abdominal part which opposes the five electroconductive parts 14-1-5.

  And when the output by the electromuscular stimulation belt 10 is started, a potential is applied to the skin surface of the user's buttocks and energization is performed inside the body. As a result, electrical stimulation is applied to the buttocks and muscles inside the body, and effects such as tightening and hip-up are obtained.

  As described above, the electric muscle stimulation belt 10 according to the present embodiment causes the conductive portions 14-1 to 11 and the monopolar pad 12 to abut on the front and back sides of the user's body and both the left and right sides. By outputting a low frequency pulse signal to the body, it is possible to energize the inside of the body and apply electrical stimulation to muscles in the deep part of the body from a plurality of directions. Accordingly, muscles can be effectively trained, and body fat including visceral fat can be reduced.

  Moreover, since each electroconductive part 14-1 to 11 is provided on the 11 pole belt 11, while being able to be mounted | worn easily by the user himself / herself, it can be freely carried with the controller 13 comprised small and lightweight. Therefore, the convenience is improved regardless of the place of use.

  Further, by sequentially applying a potential to the five conductive portions 14-1 to 14-5 arranged along the arc, it is possible to activate the internal organs by applying a rotational stimulus. In addition, since the plurality of conductive portions 14-6 to 11 are arranged in the longitudinal direction of the 11-pole belt 11, the same 11-pole belt 11 is attached to various users having different body sizes and various treatment sites. The treatment process can be carried out by using it.

  Further, since the pulse voltage and the pulse frequency are changed while combining the steady pulse signal and the EMS signal, it is possible to obtain a higher treatment effect by applying a stimulating stimulus.

  In this embodiment, the conductive portion 14-11 is selected as the GND corresponding to CH2, and a pulse voltage is applied between the conductive portion 14-11 and each conductive portion 14-6-10. However, the present invention is not limited to this. For example, output can be performed by sequentially switching the conductive portions selected as GND. As a result, electrical stimulation can be applied to the muscles inside the body from more directions, and further treatment effects can be obtained.

DESCRIPTION OF SYMBOLS 10 Electric muscle stimulation belt 11 11 pole belt 12 1 pole pad 13 Controller 14-1-11 electroconductive part

Claims (3)

An electric muscle stimulation belt for electrically stimulating muscles inside a user's body,
A belt body wound around the user's body;
At least one first counter electrode disposed on a contact surface of the belt body with the user's body;
A first common electrode that is electrically connected to the belt main body and is in contact with the user's body at a position facing each of the first counter electrodes;
A first supply unit for supplying a low-frequency pulse voltage between the first common electrode and each of the first counter electrodes;
A plurality of electrodes disposed on the contact surface of the belt body;
One of the electrodes is used as a second common electrode, and the electrodes excluding the second common electrode are used as second counter electrodes, and a low-frequency pulse is generated between the second common electrode and each of the second counter electrodes. A second supply for supplying voltage;
With
An electromuscular stimulation belt comprising a combination of two or more of the first counter electrode, the first common electrode, and the first supply unit, and the plurality of electrodes and the second supply unit. Each of the first counter electrodes is arranged at a predetermined interval,
The electromuscular stimulation belt according to claim 1, wherein the first supply unit sequentially supplies a low-frequency pulse voltage between the first common electrode and each of the first counter electrodes.   The electric muscle stimulation belt according to claim 1, wherein the second supply unit sequentially supplies a low frequency pulse voltage between the second common electrode and each of the second counter electrodes.

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