CN212756848U - Moulding trousers of intelligence based on bioelectric current muscle rehabilitation training - Google Patents

Abstract

The utility model discloses an intelligence moulding trousers based on bioelectricity muscle rehabilitation training, the inboard of this intelligence moulding trousers is fixed with a plurality of electrode slices, the electrode slice corresponds with the different muscle crowd position of human body, each electrode slice is connected with the voltage generation module, the drive module that correspond in the controller through the corresponding wire, a plurality of voltage generation modules, a plurality of drive modules all are connected with the control module, the control module is connected with the drive module through the voltage generation module, the drive module produces bioelectricity on the electrode slice through the wire, and act on the human body; after the machine is started, different voltage generation modules and different driving modules are selected through the control module, different pulse wave signals are adjusted, and therefore electrode plates at different muscle groups generate different bioelectric current signals.

Description

Moulding trousers of intelligence based on bioelectric current muscle rehabilitation training

Technical Field

The utility model relates to a bioelectricity physiotherapy technical field, specific theory relates to a moulding trousers of intelligence based on bioelectricity muscle rehabilitation training.

Background

The bioelectric current is the current generated in the process of the nerve activity or muscle movement of the organism, and more products for assisting the movement are stimulated by the derived external bioelectric current. Among them, EMS (Electro mechanical Stimulation) is widely used, and is applied to an intelligent wearable device to assist a user in body building and shaping.

One or more wires are led out from the existing EMS bioelectric current movement products through a control box, the tail ends of the wires are connected with electrode plates, and different electrode plates are controlled through the same control port of the control box, so that all the electrode plates can be operated and controlled in a polarity unified mode.

But the product adjustability of this structure and system function is poor, and different users may have different experiences in different body parts. If the same gear is adopted for output, one part of a certain user feels comfortable, but the other part may not feel current stimulation, or the current stimulation is too large, and experience feelings of different parts of the body are different, so that EMS stimulation effects are different. The products on the market can not be separately controlled, if the products need to be separately controlled, different control ends need to be designed, so that the resource waste of the products is caused, and the volume of the control box is overlarge.

The above-mentioned drawbacks are worth solving.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model provides an intelligent shaping trousers based on bioelectric current muscle rehabilitation training.

The utility model discloses technical scheme as follows:

an intelligent shaping pants based on bioelectric current muscle rehabilitation training comprises shaping pants and is characterized in that a plurality of electrode plates are fixed on the inner side of the shaping pants, the electrode plates correspond to different muscle groups of a human body in position, and each electrode plate is connected with a controller through a corresponding lead;

the controller is internally provided with a control module, a plurality of voltage generation modules and a plurality of driving modules, the voltage generation modules, the driving modules, the wires and the electrode plates are all in one-to-one correspondence, the control module is connected with the driving modules through the voltage generation modules, and the driving modules generate biological current on the electrode plates through the wires and act on a human body.

According to the above scheme the utility model discloses, a serial communication port, the electrode slice includes one or more in abdomen flesh electricity pole piece, the outer flesh electricity pole piece of hip, shank flesh electricity pole piece, adductor electrode slice, waist flesh electricity pole piece, gluteus medius electrode slice and the gluteus maximus electrode slice, abdomen flesh electricity pole piece corresponds with human abdomen muscle crowd position, the outer flesh electricity pole piece of hip corresponds with human hip flesh crowd position, shank flesh electricity pole piece corresponds with human shank muscle crowd position, the adductor electrode slice corresponds with human adductor muscle crowd position, waist flesh electricity pole piece corresponds with human waist muscle crowd position, the gluteus medius electrode slice corresponds with human gluteus medius muscle crowd position, the gluteus maximus electrode slice corresponds with human gluteus maximus muscle crowd position.

Furthermore, the abdomen myoelectric pole piece, the hip outer myoelectric pole piece, the leg myoelectric pole piece, the adductor electrode piece, the waist myoelectric pole piece, the gluteus medius electrode piece and the gluteus maximus electrode piece are symmetrically arranged on the left side and the right side of the shaping trousers.

According to the above scheme the utility model discloses, a serial communication port, the inside of moulding trousers is equipped with the trough, the wire is in the tiling the trough is interior.

Furthermore, the wiring groove comprises an original fabric and a covering fabric of the shaping pants, and the original fabric and the covering fabric are sealed to form the wiring groove.

According to the above scheme the utility model discloses, its characterized in that, the electrode slice is electrically conductive silica gel, electrically conductive silica gel fixes the inboard surface of moulding trousers.

According to the above scheme the utility model discloses, a serial communication port, still be equipped with voltage acquisition module, every in the controller the output of voltage generation module with voltage acquisition module connects, voltage acquisition module with control module connects, voltage generation module voltage acquisition module and control module connects and forms voltage closed loop control circuit.

According to the above scheme the utility model discloses, a serial communication port, still be equipped with current acquisition module, every in the controller drive module's output with the level is practised to current acquisition module, current acquisition module with control module connects, drive module current acquisition module control module forms electric current closed-loop control circuit.

According to the above scheme the utility model discloses, a serial communication port, still be equipped with power management module in the controller, power management module respectively with control module, lithium cell are connected.

Furthermore, the power management module is also connected with a charging port.

According to the utility model discloses of above-mentioned scheme, in the voltage generation module, power supply passes through first inductance L1 and is connected with first diode D1's positive pole, field effect transistor Q1's drain electrode, field effect transistor Q1's source with control module's control signal connects, just field effect transistor Q1's source passes through second resistance R2 ground connection, field effect transistor Q1's gate ground connection, first electric capacity C1, first resistance R1 and drive module are connected respectively to first diode D1's negative pole, first electric capacity C1's other end ground connection, the other end of first resistance R1 passes through the voltage acquisition module and is connected with control module, the other end of first resistance R1 still passes through third resistance R3 ground connection.

According to above-mentioned scheme the utility model discloses, its characterized in that in the drive module, fourth resistance R4, fifth resistance R5, the first power end, the second power end of H4 bridge are connected respectively to the output of voltage generation module:

the other end of the fourth resistor R4 is connected to the first signal end of the H4 bridge through a sixth resistor R6, and the other end of the fourth resistor R4 is also connected to the fourth signal end of the H4 bridge through a ninth resistor R9; the other end of the fifth resistor R5 is connected with the second signal end of the H4 bridge through a seventh resistor R7, and the other end of the fifth resistor R5 is also connected with the third signal end of the H4 bridge through an eighth resistor R8; two output ends of the H4 bridge are connected with the corresponding electrode plates;

the other end of the fourth resistor R4 is further connected with a collector of a sixth triode Q6, the other end of the fifth resistor R5 is further connected with a collector of a seventh triode Q7, and a base of the sixth triode Q6 and a base of the seventh triode Q7 are both connected with a control signal of the control module.

Furthermore, a first ground end and a second ground end of the H4 bridge are both connected with a first pin of an integrated chip U1, a third pin of the integrated chip U1 is connected with a hard overcurrent protection interface of the control module, and a sixth pin and a seventh pin of the integrated chip U1 are connected with the control module through a current collection module.

According to above-mentioned scheme the utility model discloses, a serial communication port, controller and intelligent terminal wireless connection.

Further, the controller is connected with the intelligent terminal through a Bluetooth signal.

According to above-mentioned scheme the utility model discloses, a serial communication port, control module still is connected with the human-computer interaction module.

Furthermore, the human-computer interaction module comprises a key and an LED lamp.

The utility model discloses a according to above-mentioned scheme the utility model discloses, its beneficial effect lies in, the utility model discloses an electrode slice produces the bioelectric current and acts on human muscle, and the supplementary human body carries out muscle training and rehabilitation activity, cooperates the design of moulding trousers and the stimulation of bioelectric current, realizes good supplementary effect, reaches the effect of doing the best effort doubly; the boost circuit is used for boosting the voltage to be less than 100V, so that the generation requirement of the bioelectric current is met, the number of components is reduced, the product cost can be reduced, and the product volume can be fully reduced; the system realizes the separate control of a plurality of control circuits, so that the product is more intelligent to use, and a user can adjust the system according to the self requirement; the system can form stable voltage and current output through feedback design, and guarantees user experience.

Drawings

Fig. 1 is a schematic front structural view of a first embodiment of the present invention.

Fig. 2 is a schematic back structure diagram of a first embodiment of the present invention.

Fig. 3 is a schematic front structural view of a second embodiment of the present invention.

Fig. 4 is a schematic back structure diagram of a second embodiment of the present invention.

Fig. 5 is a circuit system structure diagram of the present invention.

FIG. 6 is a schematic diagram of a portion of a control module.

Fig. 7 is a circuit diagram of a voltage generation module.

Fig. 8 is a circuit diagram of the driving module.

In the figure, 1-abdominal myoelectric pole piece; 2-external myoelectric pole piece of hip; 3-a leg myoelectric pole piece; 4-adductor electrode pad; 5-lumbar myoelectric pole piece; 6-gluteus medius electrode slice; 7-gluteus maximus electrode slice.

Detailed Description

The invention is further described with reference to the following figures and embodiments:

as shown in fig. 1 to 8, an intelligent shaping pants based on bioelectric current muscle rehabilitation training comprises shaping pants, wherein a plurality of electrode plates are fixed on the inner side of the shaping pants, the electrode plates correspond to different muscle groups of a human body in position, and each electrode plate is connected with a controller through a corresponding lead. The shaping trousers in the utility model can also be sport trousers and the like. The utility model discloses a bioelectric current that the design cooperation electrode slice of moulding trousers produced is amazing, can assist the user to carry out muscle training and recovered activity.

The electrode plate comprises one or more of an abdomen myoelectric electrode plate, a hip outer myoelectric electrode plate, a leg myoelectric electrode plate, an adductor electrode plate, a waist myoelectric electrode plate, a gluteus medius electrode plate and a gluteus maximus electrode plate. According to different product requirements, 3-7 paths (6-14 connecting points) can be selected for output. The utility model discloses a distribution of a plurality of electrode slices cooperates different muscle training and rehabilitation activity, realizes different supplementary effects, has increased the application scope of product to through the rational layout of electrode slice, increase the amazing effect of electric current of product.

The abdominal myoelectric pole piece is laid on the inner surface of the abdominal position of the shaping trousers and corresponds to the abdominal muscle group position of the human body; the external hip muscle electric pole pieces are laid on the inner surfaces of two sides of the crotch of the shaping trousers, extend from the front to the back and correspond to the external hip muscle group of the human body; the leg myoelectric pole piece is laid on the inner surface of the position of the leg of the shaping trousers, winds the inner side of the leg from the front panel and extends to the rear panel, and the position of the leg myoelectric pole piece corresponds to the position of the muscle group of the leg of the human body; the adductor electrode plates are laid on the inner surfaces of the left side and the right side of the crotch part of the shaping trousers, extend from the front width to the rear width and correspond to the adductor group positions of the human body; the waist myoelectric pole piece is laid on the inner surface of the back waist position of the shaping trousers and corresponds to the position of the human waist muscle group, and the gluteus medius pole piece is laid on the back gluteus position of the shaping trousers and corresponds to the position of the human gluteus medius group; the gluteus maximus electrode plate is laid at the position of the back gluteus of the shaping trousers, is positioned at the lower side of the gluteus medius electrode plate and corresponds to the position of the gluteus maximus group of the human body.

Preferably, the abdomen myoelectric pole piece, the hip outer myoelectric pole piece, the leg myoelectric pole piece, the adductor electrode piece, the waist myoelectric pole piece, the gluteus medius electrode piece and the gluteus maximus electrode piece are symmetrically arranged at the left side and the right side of the shaping trousers.

In the embodiment shown in fig. 1 and 2, the inner surface of the sports pants is provided with an abdominal myoelectric pole piece 1, a hip external myoelectric pole piece 2, a leg myoelectric pole piece 3, an adductor muscle pole piece 4, a waist myoelectric pole piece 5, a gluteus medius pole piece 6 and a gluteus maximus pole piece 7, and each pole piece is arranged in bilateral symmetry and is used for performing stimulation exercise on muscles at each position of the waist, abdomen and legs of a human body. The sports pants in the embodiment are more convenient to wear, and are convenient for people to wear in daily life.

In the embodiment shown in fig. 3 and 4, the inner surface of the shaping pants is provided with the hip outer myoelectric pole piece 2, the leg myoelectric pole piece 3 and the waist myoelectric pole piece 5, and each pole piece is arranged in bilateral symmetry, so that the bioelectric current vibration and stimulation are increased on the basis of keeping the conventional plasticity, and the muscle exercise effect is increased. The shaping trousers in the embodiment have better plastic effect.

The utility model provides an electrode slice is conductive silica gel, and conductive silica gel fixes the interior side surface at moulding trousers. The uniform bioelectric current can be generated through the conductive silica gel, and the corresponding vibration sense is generated through the stimulation of the bioelectric current to the muscles of the human body, so that the exercise effect of the muscles at the corresponding positions of the human body is improved.

Preferably, the inside of the shaping trousers is provided with a wiring groove, and the wires are flatly laid in the wiring groove. Specifically, the cabling channel comprises an original fabric and a covering fabric of the shaping trousers, and the original fabric and the covering fabric are sealed to form the cabling channel. The wire is hidden in the wiring groove, so that the wire is not exposed on the surface, the safety of wearing the human body is improved, and the product is more attractive.

As shown in fig. 5 and fig. 6, the utility model discloses a boost circuit controls, for guaranteeing every/every can control respectively to the electrode slice homoenergetic, the utility model discloses set up the control scheme that the electrode slice corresponds in the controller respectively. Specifically, a control module, a plurality of voltage generation modules and a plurality of driving modules are arranged in the controller, the control module is connected with the driving modules through the voltage generation modules, and the driving modules generate biological current on the electrode plates through leads and act on human bodies. The voltage generation module, the driving module, the wires and the electrode plates are in one-to-one correspondence, so that each/every pair of electrode plates can be controlled independently, the adjustability of products is improved, and the requirements of different human body conditions are met.

The controller is wirelessly connected with an intelligent terminal (equipment such as a smart phone). Preferably, the controller is connected with the intelligent terminal through a Bluetooth signal, and the function of the intelligent terminal control system is selected. The control module in this embodiment can select the bluetooth SOC chip. The control module is further connected with the human-computer interaction module, and the human-computer interaction module in the embodiment comprises keys and an LED lamp.

Preferably, a power management module is further arranged in the controller, the power management module is respectively connected with the control module and the lithium battery, and the power management module is further connected with the charging port. And power supply management is carried out on the system through the power supply management module, and voltage required by the system is output.

The utility model discloses a control module's negative feedback is controlled boost circuit's output voltage, electric current, can fully reduce the quantity of circuit components and parts, reduces product cost, reduces the product volume.

The utility model provides a be equipped with voltage acquisition module in the controller for carry out the feedback collection to system's voltage. Specifically, the output end of each voltage generation module is connected with a voltage acquisition module, the voltage acquisition module is connected with a control module, and the voltage generation module, the voltage acquisition module and the control module are connected to form a voltage closed-loop control circuit.

The utility model provides a be equipped with current acquisition module in the controller for carry out the feedback collection to system's electric current, specific, every drive module's output and current acquisition module are trained the level, and current acquisition module is connected with control module, and drive module, current acquisition module, control module form the electric current closed loop control circuit.

As shown in fig. 6 and 7, in the Voltage generating module, the power supply Vin is connected to the anode of the first diode D1 and the drain of the field-effect transistor Q1 through the first inductor L1, the source of the field-effect transistor Q1 is connected to a Control signal (PWM Control pin) of the Control module, the source of the field-effect transistor Q1 is grounded through the second resistor R2, the gate of the field-effect transistor Q1 is grounded, the cathode of the first diode D1 is connected to the first capacitor C1, the first resistor R1 and the driving module (Vout output), the other end of the first capacitor C1 is grounded, the other end of the first resistor R1 is connected to the Control module (Voltage Detect pin) through the Voltage collecting module, and the other end of the first resistor R1 is grounded through the third resistor R3.

The utility model discloses an among each way Control scheme, Control module's PWM Control pin and voltage generation module's PWM Control signal channel are connected for Control this boost circuit's output voltage.

The utility model discloses an among each way control scheme, Voltage Detect pin of Voltage generation module passes through Voltage acquisition module and is connected with control module for control module acquires boost Voltage circuit's output Voltage, and then forms closed-loop control.

As shown in fig. 6 and 8, in the driving module, the output terminal (Vout output-Vsupply) of the voltage generating module is connected to the first power terminal and the second power terminal of the bridge of the fourth resistor R4, the fifth resistor R5 and the H4, respectively. The H4 bridge includes a second transistor Q2, a third transistor Q3, a fourth transistor Q4, and a fifth transistor Q5, wherein an emitter of the second transistor Q2 is coupled to an emitter of the third transistor Q3, and a collector of the fourth transistor Q4 is coupled to a collector of the fifth transistor Q5.

The other end of the fourth resistor R4 is connected to the first signal terminal of the H4 bridge (i.e., the base of the second transistor Q2) via a sixth resistor R6, and the other end of the fourth resistor R4 is further connected to the fourth signal terminal of the H4 bridge (i.e., the base of the fifth transistor Q5) via a ninth resistor R9; the other end of the fifth resistor R5 is connected to the second signal terminal of the H4 bridge (i.e., the base of the third transistor Q3) via a seventh resistor R7, and the other end of the fifth resistor R5 is also connected to the third signal terminal of the H4 bridge (i.e., the base of the fourth transistor Q4) via an eighth resistor R8; two output ends of the H4 bridge are connected with corresponding electrode plates, namely a collector of the second triode Q2 and an emitter of the fourth triode Q4 are connected with a PAD-pos pin of the connector PL, and a collector of the third triode Q3 and an emitter of the fifth triode Q5 are connected with a PAD-neg pin of the connector PL.

The other end of the fourth resistor R4 is further connected to the collector of the sixth transistor Q6, the other end of the fifth resistor R5 is further connected to the collector of the seventh transistor Q7, and the emitter of the sixth transistor Q6 is grounded. The base of the sixth triode Q6 and the base of the seventh triode Q7 are both connected with the control Signal of the control module, namely the control end Signal-pos of the control module is connected with the base of the seventh triode Q7, and the control end Signal-neg of the control module is connected with the base of the sixth triode Q6. The over-control end Signal-pos and the control end Signal-neg of the control module are used for controlling the driving circuit to generate positive or negative waveforms.

The first ground (collector of the fourth transistor Q4) and the second ground (collector of the fifth transistor Q5) of the H4 bridge are both connected to a first pin of the ic U1, which is also grounded via a tenth resistor R10. The third pin of the integrated chip U1 is connected to a hard-overload interface (Current-overload interface) of the control module for hard overcurrent protection, and when the Current flowing through the driving circuit exceeds a limited Current, the signal interrupts the control module. The sixth pin and the seventh pin of the integrated chip U1 are connected to a control module (Current-Detect pin) through a Current collection module, and are used for the control module to obtain an output Current of the driving circuit.

The control module is a singlechip, a microcomputer, an FPGA device or other similar controllers. The control module can be integrated with the ADC for collection, or an external ADC collection chip for collecting voltage and current, and the control module shown in FIG. 5 is in a mode of collecting voltage and current by the external ADC collection chip.

In the utility model, one path of voltage generation module and one path of driving module form a group, the Control module controls the output voltage of the voltage generation module through PWM Control, and then controls the output of the positive pole and the negative pole of the driving module through the Control module to generate one path of EMS output; the control module forms feedback by detecting the current of the output voltage/driving module of the voltage generation module, then adjusts the duty ratio of PWM, and controls the output voltage or the output current in a certain range by closed-loop control.

The process is a principle of one-path output, and the multi-path output is controlled simultaneously.

The utility model discloses the in-process of realization:

after the machine is started, different voltage generation modules and different driving modules are selected through the control module, different pulse wave signals are adjusted, and therefore electrode plates at different muscle groups generate different bioelectric current signals.

After the machine is started, a user is connected with the control module through the intelligent terminal, different moving parts are selected through the intelligent terminal/the control module, the moving mode and the gear of the parts are set, and the control module adjusts output pulse waves of the parts. And opening the motion process of the intelligent shaping trousers after the regulation is finished.

And judging whether the controller or the intelligent terminal sends a command for starting movement, if not, resetting different movement modes and gears at different positions, and if so, outputting appointed pulse wave signals aiming at different muscle groups according to the setting. In the process, the user can also perform teaching movement according to the movement video on the intelligent terminal.

And in the process of outputting the pulse wave signals, circularly judging whether the mode and the gear are adjusted, and modifying the pulse wave signals at the position if the mode and the gear are adjusted. And in the process of outputting the pulse wave signal, detecting the connection state of the electrode plates in real time, and if the electrode plates are disconnected, readjusting the electrode plates of the shaping trousers.

The utility model adopts the boost circuit to boost the voltage to less than 100V, the product volume is smaller, and the cost is lower; in addition, through different line drive for different electrode slices can reach different amazing effects, and the product is more intelligent.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are considered to be within the scope of the invention as defined by the following claims.

The above exemplary description of the present invention is made in conjunction with the accompanying drawings, and it is obvious that the present invention is not limited by the above manner, and various improvements made by the method concept and technical solution of the present invention or by directly applying the concept and technical solution of the present invention to other occasions without improvement are all within the protection scope of the present invention.

Claims (10)

1. An intelligent shaping pants based on bioelectric current muscle rehabilitation training comprises shaping pants and is characterized in that a plurality of electrode plates are fixed on the inner side of the shaping pants, the electrode plates correspond to different muscle groups of a human body in position, and each electrode plate is connected with a controller through a corresponding lead;

the controller is internally provided with a control module, a plurality of voltage generation modules and a plurality of driving modules, the voltage generation modules, the driving modules, the wires and the electrode plates are all in one-to-one correspondence, the control module is connected with the driving modules through the voltage generation modules, and the driving modules generate biological current on the electrode plates through the wires and act on a human body.

2. The intelligent shaping pants based on bioelectric current muscle rehabilitation training according to claim 1, wherein the electrode plates comprise one or more of an abdominal myoelectric pole piece corresponding to a human abdominal muscle group position, a hip external myoelectric pole piece corresponding to a human hip external muscle group position, a leg myoelectric pole piece corresponding to a human leg muscle group position, a lumbar myoelectric pole piece corresponding to a human adductor muscle group position, and a gluteus maximus electrode piece corresponding to a human gluteus maximus group position.

3. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 2, wherein the abdominal myoelectric pole piece, the hip external myoelectric pole piece, the leg myoelectric pole piece, the adductor electrode piece, the waist myoelectric pole piece, the gluteus medius electrode piece and the gluteus maximus electrode piece are symmetrically arranged on the left and right sides of the shaping pants.

4. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 1, wherein a wiring groove is arranged inside the shaping pants, and the wires are laid in the wiring groove.

5. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 4, wherein the cabling channel comprises an original fabric and a covering fabric of the shaping pants, and the original fabric and the covering fabric are sealed to form the cabling channel.

6. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 1, wherein the electrode sheet is conductive silicone fixed on the inner side surface of the shaping pants.

7. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 1, wherein voltage collecting modules are further arranged in the controller, an output end of each voltage generating module is connected with the voltage collecting module, the voltage collecting modules are connected with the control module, and the voltage generating modules, the voltage collecting modules and the control module are connected to form a voltage closed-loop control circuit.

8. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 1, wherein a current collection module is further arranged in the controller, an output end of each driving module is connected with the current collection module, the current collection module is connected with the control module, and the driving module, the current collection module and the control module form a current closed-loop control circuit.

9. The intelligent shaping pants based on bioelectric current muscle rehabilitation training as claimed in claim 1, wherein a power management module is further arranged in the controller, and the power management module is respectively connected with the control module and the lithium battery.

10. The intelligent shaping pants based on bioelectric current muscle rehabilitation training of claim 9, wherein the power management module is further connected to a charging port.

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