CN216319497U - Wearable electrical stimulation treatment device - Google Patents

Abstract

The utility model provides a wearable electrical stimulation treatment device, comprising: electric pulse module, electro photoluminescence module and central control module, electric pulse module electric connection central control module converts the mechanical energy that external environment acted on it to the electric pulse, and the electric photoluminescence module contacts with user's skin surface, includes: the electric stimulation module comprises an elastic insulating substrate which is arranged into a preset shape according to the skin surface of a user and a plurality of electric stimulation components which are arranged on one side of the insulating substrate, close to the skin surface of the user, and are respectively and electrically connected with the central control module, wherein each electric stimulation component of the electric stimulation module is controlled by the central control module and is respectively and electrically communicated with the electric pulse module, and the electric pulses output by the electric pulse module are applied to the skin surface of the user for electric stimulation. The wearable electrical stimulation treatment device provided by the utility model has the advantages of simple structure and process, low cost, no need of external power supply, convenience in use, wide application scene and wide applicable population.

Description

Wearable electrical stimulation treatment device

Technical Field

The utility model relates to the field of biomedical treatment, in particular to a wearable electrical stimulation treatment device.

Background

Electrical stimulation can alter the histological properties of the muscle and enhance muscle strength, preventing and treating a variety of pathologies. The low-frequency pulse current therapy is a method for treating diseases by using pulse current with a frequency of 1000Hz or less, and includes induction electrotherapy, electrokinetic therapy, electric sleep therapy, super-stimulation electrotherapy, transcutaneous electrical nerve stimulation therapy, electrical stimulation therapy, and the like. The low-frequency pulse current therapy has the advantages of low voltage, adjustable low frequency, no obvious electrolysis, strong stimulation to sensory nerves and motor nerves, pain relieving and no heat, and is widely applied to the medical field.

However, the existing electrical stimulation therapeutic apparatus is usually applied to large medical institutions such as hospitals, the size of the apparatus is large, and the apparatus is designed by adopting an external power supply, so that the use convenience is limited. And the existing electric stimulation therapeutic apparatus has complex manufacturing process and high cost, so that the application scene and the applicable population are limited.

Therefore, the prior art lacks a wearable electric stimulation treatment device which does not need an external power supply for power supply, and has simple structure and manufacturing process and low cost.

SUMMERY OF THE UTILITY MODEL

The utility model provides a wearable electrical stimulation treatment device. The device is used for solving the problems that the device for electrical stimulation treatment in the prior art is complex in structure and process, high in cost, inconvenient to use and limited in application scenes and applicable crowds, and utilizes an external power supply to supply power.

The present invention provides a wearable electrical stimulation skin treatment device, comprising: the device comprises an electric pulse module, an electric stimulation module and a central control module; wherein the content of the first and second substances,

the electric pulse module is electrically connected with the central control module and is used for converting mechanical energy acted on the electric pulse module by an external environment into electric pulses; the electric pulse module includes: at least one of a friction generator, a piezoelectric generator, a pressure induction cable based on the friction generator, a pressure induction cable based on the piezoelectric generator, and a piezoelectric and triboelectric hybrid generator;

the electrical stimulation module is in contact with a skin surface of a user, comprising: an elastic insulating substrate, and a plurality of electrostimulation members; the elastic insulating substrate is adjusted to be in a preset shape according to the skin surface of a user, and the plurality of electrical stimulation components are arranged on one side, close to the skin surface of the user, of the insulating substrate and are respectively and electrically connected with the central control module;

the central control module is used for controlling the electric pulse module to be electrically connected with or disconnected from each electric stimulation component of the electric stimulation module;

and when each electrical stimulation component of the electrical stimulation module is electrically communicated with the electrical pulse module through the control of the central control module, the electrical pulses output by the electrical pulse module are acted on the skin surface of a user for electrical stimulation.

Optionally, the electrical stimulation treatment device further comprises: the device comprises a rechargeable power supply conversion module and a vibration module; wherein the content of the first and second substances,

the vibration module is arranged in contact with the electric pulse module;

the central control module is respectively electrically connected with the rechargeable power supply conversion module and the vibration module and is used for controlling the vibration module to be electrically connected with or disconnected from the rechargeable power supply conversion module;

the vibration module receives power supply of the rechargeable power supply conversion module when being electrically communicated with the rechargeable power supply conversion module under the control of the central control module, generates vibration with preset frequency and preset amplitude and transmits the vibration to the electric pulse module.

Optionally, the electrical stimulation treatment device further comprises: an energy storage module; wherein the content of the first and second substances,

the energy storage module is electrically connected with the rechargeable power supply conversion module and the central control module respectively;

the central control module controls the electric pulse module to be electrically disconnected with all the electric stimulation components of the electric stimulation module, and when the vibration module is electrically disconnected with the rechargeable power supply conversion module, the electric pulse module is electrically connected with the energy storage module, and electric pulses output by the electric pulse module are preprocessed and then stored in the energy storage module;

when the central control module controls the vibration module to be electrically communicated with the rechargeable power supply conversion module, the rechargeable power supply conversion module receives electric energy transmitted by the energy storage module so as to supply power to the vibration module through the central control module.

Optionally, the central control module includes: a wireless transmitting/receiving unit and a terminal device; wherein the content of the first and second substances,

the wireless transceiver component is electrically connected with the rechargeable power supply control module, is wirelessly connected with the terminal equipment, and is used for receiving a control signal of the terminal equipment through the power supply of the rechargeable power supply conversion module;

and the central control module controls according to the control signal.

Optionally, the friction generator is a friction power generation film, and/or the piezoelectric generator is a piezoelectric power generation film.

Optionally, the friction generator comprises: a friction member based woven friction generator; wherein the content of the first and second substances,

a friction member based woven friction generator comprising: at least one first friction member and at least one second friction member;

at least one first friction component and at least one second friction component are woven with each other to form a friction component-based woven friction generator, and at least one of the at least one first friction component and the at least one second friction component comprises a friction interface capable of contacting and rubbing;

the at least one first friction element and/or the at least one second friction element have an electrical signal output of the friction element-based woven friction generator, which is electrically connected to the central control module.

Optionally, the pressure induction cable based on the friction generator and/or the pressure induction cable based on the piezoelectric generator are woven to form an electric pulse module with a preset appearance;

and/or the at least one first friction component and the at least one second friction component are woven to form the electric pulse module with a preset appearance.

Optionally, the preset appearance is a headgear, a corsage, a bandage, an insole.

Optionally, the electrical stimulation skin treatment device further comprises: a wearable body; the wearable body is provided with an electric pulse module, an electric stimulation module and a central control module.

Optionally, the wearable body is a headgear, a corsage, a bandage, or a shoe.

The wearable electrical stimulation treatment device provided by the utility model has the following beneficial effects:

(1) according to the wearable electrical stimulation treatment device provided by the utility model, the electrical pulse module adopts at least one of the friction generator, the piezoelectric generator, the pressure induction cable based on the friction generator, the pressure induction cable based on the piezoelectric generator and the piezoelectric and triboelectric hybrid generator, so that mechanical energy in an external environment can be directly converted into electrical pulses under the condition that no external power supply is available or insufficient, so that the electrical stimulation module performs electrical stimulation, the energy is saved, the environment is protected, and the problem that the electrical stimulation module cannot be used due to the fact that no external power supply is available is avoided.

(2) According to the wearable electrical stimulation treatment device provided by the utility model, the vibration module generates the vibration with the preset frequency and the preset amplitude, the electrical pulse output to the electrical stimulation module by the electrical pulse module is accurately controlled, and different electrical pulses are accurately applied according to different treatment scenes.

(3) The wearable electrical stimulation treatment device provided by the utility model controls the electrical communication forms of the electrical pulse module, the plurality of electrical stimulation components of the electrical stimulation module, the rechargeable power supply conversion module, the vibration module and the energy storage module through the central control module; the electric stimulation components of the electric stimulation module can be respectively and electrically communicated, so that the flexibility of an electric stimulation mode is improved, the charging and discharging of the rechargeable power supply conversion module can be reasonably coordinated, and the energy utilization efficiency is improved; and wireless remote control is realized by receiving the control signal of the terminal equipment.

(4) According to the wearable electrical stimulation treatment device provided by the utility model, the elastic insulating substrate is adaptive to the skin surface of a user, the wearable body or the preset appearance form is various, the fitting degree of a plurality of electrical stimulation components and the skin surface of the user is improved, and the application scenes and the applicable population of the wearable electrical stimulation treatment device are increased.

(5) The wearable electrical stimulation treatment device provided by the utility model is simple in structure and process, low in cost, convenient to use and suitable for large-scale industrial production.

Drawings

Fig. 1 is a schematic block diagram of an embodiment of a wearable electrical stimulation treatment device provided in the present invention;

fig. 2 is a schematic block diagram of another embodiment of the wearable electrical stimulation treatment device provided in the present invention;

fig. 3 is a schematic block diagram of a wearable electrical stimulation treatment device according to another embodiment of the present invention;

fig. 4 is a schematic block diagram of a wearable electrical stimulation treatment device according to still another embodiment of the present invention;

fig. 5a is a schematic structural diagram of at least one first friction member of the friction member-based woven friction generator of the wearable electrical stimulation treatment device provided by the utility model;

fig. 5b is another schematic structural diagram of at least one first friction member of the friction member-based woven friction generator of the wearable electrical stimulation treatment device provided by the utility model.

Detailed Description

In order to fully understand the objects, features and effects of the present invention, exemplary embodiments of the present invention will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the utility model are shown in the drawings, it should be understood that the utility model can be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the utility model to those skilled in the art.

Fig. 1 shows a block schematic diagram of a wearable electrical stimulation therapy device according to an embodiment of the present invention. As shown in fig. 1, the wearable electrical stimulation therapy device of the present embodiment includes: an electrical pulse module 10, an electrical stimulation module 20, and a central control module 30.

The electrical pulse module 10 is electrically connected to the central control module 30, and is configured to convert mechanical energy applied thereto from an external environment into electrical pulses, where the electrical pulse module 10 includes: at least one of a friction generator, a piezoelectric generator, a pressure induction cable based on a friction generator, a pressure induction cable based on a piezoelectric generator, and a piezoelectric and triboelectric hybrid generator.

The user may include, but is not limited to, a human body, an animal body, or the like, of an organism requiring electrical stimulation therapy. Taking a human body as an example, a user can wear the wearable electrical stimulation therapy device of the present invention on various parts of the body, when the user generates body motion, the mechanical energy of the motion acting on the electrical pulse module 10 can enable at least one of the friction generator, the piezoelectric generator, the pressure induction cable based on the friction generator, the pressure induction cable based on the piezoelectric generator, and the piezoelectric and triboelectric hybrid generator included in the electrical pulse module 10 to generate electrical pulse signals.

The electrical stimulation module 20 is in contact with the skin surface of the user and includes: an elastic insulating substrate 21, and a plurality of electrostimulation members 22; the elastic insulating substrate 21 is set to be in a preset shape according to the skin surface of the user, and the plurality of electrical stimulation components 22 are arranged on one side of the elastic insulating substrate 21 close to the skin surface of the user and are respectively electrically connected with the central control module 30.

The elastic insulating base 21 is adjusted to a preset shape according to the skin surface of the user, and the preset shape may include, but is not limited to: a shape adapted to the top of the skull of the user, a three-dimensional curved shape adapted to the chest of the user, a sheet shape adapted to the bandage of the user, a convex shape adapted to the arch of the foot of the user, etc. Since the elastic insulating substrate 21 has elasticity, the elastic insulating substrate 21 can be well fitted to the skin surface of the user by a predetermined shape when the user wears the wearable electrical stimulation therapy device on various parts of the body.

The plurality of electrostimulation members 22 are arranged on the side of the elastic insulating substrate 21 close to the skin surface of the user, and after the wearable electrostimulation treatment device is worn by the user, the plurality of electrostimulation members 22 are attached between the skin surface of the user and the elastic insulating substrate 21. The plurality of electrical stimulation components 22 may be distributed in an array manner, such as an annular array or a rectangular array, but may be configured according to actual needs by those skilled in the art.

The plurality of electrostimulation components 22 may include, but are not limited to, the following forms: an electrode pad form, or a bump form. Electrode sheet forms may include, but are not limited to, strip electrodes or interdigitated electrodes; the raised form can add a massaging effect to the skin surface of the user.

The central control module 30 is used for controlling the electrical pulse module 10 to be electrically connected with or disconnected from each electrical stimulation component 22 of the electrical stimulation module 20.

When each electrical stimulation component 22 of the electrical stimulation module 20 is electrically connected to the electrical pulse module 10 through the control of the central control module 30, the electrical pulses output by the electrical pulse module 10 are applied to the skin surface of the user for electrical stimulation.

In order to make the connection of the central control module 30 with the electrical pulse module 10 and the electrical stimulation module 20 more clearly understood by those skilled in the art, the following detailed description is provided:

the electrical pulse module 10 may include at least one of a friction generator, a piezoelectric generator, a friction generator based pressure sensing cable, a piezoelectric and triboelectric hybrid generator. The number of the friction generator, and/or the piezoelectric generator, and/or the pressure induction cable based on the friction generator, and/or the pressure induction cable based on the piezoelectric generator, and/or the piezoelectric and triboelectric hybrid generator included in the electric pulse module 10 may be one or more. Thus, the electrical pulse module 10 may comprise one output, or a plurality of outputs.

When the electric pulse module 10 includes a plurality of types and/or includes a plurality of types, a plurality of friction generators, and/or piezoelectric generators, and/or pressure induction cables based on friction generators, and/or pressure induction cables based on piezoelectric generators, and/or piezoelectric and triboelectric hybrid generators may be arranged in a tiled and/or stacked manner.

Electrostimulation module 20 has a plurality of electrostimulation components 22, and therefore each of the plurality of electrostimulation components 22 has one input.

When the electrical pulse module 10 includes one output end, the central control module 30 can control the one electrical pulse output end to be electrically connected with each input end of each electrical stimulation component 22, so that all the electrical stimulation components 22 apply electrical stimulation to the skin surface of the user; or the central control module 30 may control the one electrical pulse output end to be respectively electrically communicated with the input end of the specific electrical stimulation component 22, so that the specific electrical stimulation component 22 applies electrical stimulation to the skin surface of the user.

When the electrical pulse module 10 includes a plurality of output terminals, the plurality of output terminals may be connected in series or in parallel, and at this time, the plurality of electrical pulse output terminals are equivalent to one electrical pulse output terminal and electrically connected to the electrical stimulation module 20 through the central control module 30.

Alternatively, when the electrical pulse module 10 includes a plurality of output terminals, the central control module 30 can control the plurality of electrical pulse output terminals to be respectively electrically connected to the input terminals of the specific electrical stimulation component 22. That is, the input of one or more of the electrical stimulation components 22 is in electrical communication with one of the plurality of electrical pulse outputs; in addition, the input end of one or more of the electrical stimulation components 22 is electrically connected to another output end of the plurality of electrical pulse output ends, and so on, which are not described herein again.

That is, the manner in which the central control module 30 controls the electrical pulse module 10 to be electrically connected to or disconnected from each electrical stimulation component 22 of the electrical stimulation module 20 is very flexible, and one skilled in the art can select any one of the connection manners according to actual needs. For example, the wearable electrical stimulation treatment device of the utility model comprises a plurality of electrical stimulation parts 22 distributed in a rectangular array mode, the wearable electrical stimulation treatment device is worn on the arch part of a user, the central control module 30 only controls the input ends of certain specific electrical stimulation parts 22 corresponding to the arch acupuncture points of the user to be electrically connected with the output end of the electrical pulse module 10, and the input ends of other electrical stimulation parts 22 are electrically disconnected with the output end of the electrical pulse module 10, so that the electrical stimulation is performed on the arch acupuncture points of the user in a targeted manner.

In order to avoid energy consumption, the central control module 30 of the present invention may be in the form of a mechanical switch, but is not limited thereto, and a person skilled in the art may select the type of the central control module 30 according to practical situations.

According to the wearable electrical stimulation treatment device of the embodiment of the utility model, the electrical pulse module 10 adopts at least one of a friction generator, a piezoelectric generator, a pressure induction cable based on the friction generator, a pressure induction cable based on the piezoelectric generator, and a piezoelectric and triboelectric hybrid generator, so that mechanical energy in an external environment can be directly converted into electrical pulses under the condition that no external power supply supplies power or the power supply of the external power supply is insufficient, so that the electrical stimulation module 20 performs electrical stimulation, the energy is saved, the environment is protected, and the problem that the electrical stimulation module cannot be used due to the fact that no external power supply supplies power is avoided; the central control module 30 controls the electrical connection form of the electrical pulse module 10 and the plurality of electrical stimulation components 22 of the electrical stimulation module 20, so that the flexibility of the electrical stimulation mode is improved; the elastic insulating substrate 21 is adapted to the skin surface of a user, so that the fitting degree of the plurality of electrical stimulation parts 22 and the skin surface of the user is improved, and the application scenes and the applicable population of the wearable electrical stimulation treatment device are increased; the structure and the process are simple, the cost is low, the use is convenient, and the method is suitable for large-scale industrial production.

Fig. 2 shows a schematic diagram of a circuit module of the wearable electrical stimulation therapy device according to another embodiment of the utility model. As shown in fig. 2, the wearable electrical stimulation treatment device of the present embodiment further includes, in addition to the wearable electrical stimulation treatment device of the above embodiment: a rechargeable power conversion module 40, and a vibration module 50.

The vibration module 50 is arranged in contact with the electric pulse module 10; the central control module 30 is electrically connected to the rechargeable power conversion module 40 and the vibration module 50, respectively, and is configured to control the vibration module 50 to be electrically connected to or disconnected from the rechargeable power conversion module 40; the vibration module 50 receives power supplied by the rechargeable power conversion module 40 under the control of the central control module 30, and generates vibration with a preset frequency and a preset amplitude, and transmits the vibration to the electric pulse module 10.

In order to make the connection and operation of the above modules more clear for those skilled in the art, the following detailed description is provided:

consider the following scenario where the electrical pulse module 10 cannot acquire mechanical energy to convert into electrical pulses by autonomous movement after the user wears the wearable electrical stimulation therapy device, including but not limited to the following scenarios: the user is a crowd who is inconvenient to exercise; or the part where the electric pulse module 10 is worn is relatively static or has little mechanical energy when the user is moving.

When the situation does not occur, that is, the mechanical energy of the autonomous movement of the user is enough to enable the electric pulse module 10 to generate the electric pulse action with the skin surface of the user, the user controls the vibration module 50 to be electrically disconnected from the rechargeable power conversion module 40 through the central control module 30, so that additional power supply and mechanical energy are not needed, and energy is saved.

When the above situation occurs, the vibration module 50 is electrically connected to the rechargeable power conversion module 40 through the control of the central control module 30, receives the power supplied by the rechargeable power conversion module 40, and generates vibration with a preset frequency and a preset amplitude, and transmits the vibration to the electric pulse module 10.

The vibration module 50 may further include: a drive member 51, and at least one vibration member 52. The driving part 51 is connected with the at least one vibration part 52 and is used for driving the at least one vibration part 52 to vibrate at a preset frequency and a preset amplitude; at least one vibration member 52 is disposed in contact with the electrical pulse module 10 for generating vibrations of a predetermined frequency and a predetermined amplitude to act on the electrical pulse module 10.

The driving part 51 may be a driving chip in the prior art. The at least one vibration member 52 is a prior art vibration motor and may include, but is not limited to, a rotor motor, a longitudinal linear motor, or a transverse linear motor. If the number of the vibration members 52 is multiple, the multiple vibration members 52 may include the same number of longitudinal linear motors or transverse linear motors, and the multiple vibration members 52 are uniformly arrayed and contacted on the electric pulse module 10, in such a way that the multiple vibration members 52 can apply regular longitudinal or transverse vibration to the electric pulse module 10, so as to precisely control the preset frequency and the preset amplitude of the electric pulse output by the electric pulse module 10.

That is, the central control module 30 controls the vibration module 50 to generate vibrations of a preset frequency and a preset amplitude; the vibration module 50 is configured to achieve the vibration to reach a preset frequency and a preset amplitude by adjusting the driving component 51 and/or adjusting the at least one vibration component 52. I.e., increasing or decreasing the driving strength of the driving member 51, and/or increasing or decreasing the vibration strength of the at least one vibration member 52, while adjusting the frequency at which the driving member 51 drives the at least one vibration member 52, the vibration module 50 reaches the preset frequency and the preset amplitude.

The specific arrangement position of the vibration module 50 is not limited in the present invention, and only the vibration module 50 is required to be in contact with the electric pulse module 10. In order to avoid the conduction problem between the vibration module 50 and the electric pulse module 10, an insulating interlayer (not shown) is disposed between the vibration module 50 and the electric pulse module 10. The insulating interlayer can transmit the vibration of the vibration module 50 to the electric pulse module 10 and prevent the vibration module 50 from being conducted with the electric pulse module 10. The insulating interlayer can be selected from, but not limited to, insulating films such as polyvinyl chloride films, polyethylene films, polypropylene films, polystyrene films, etc.

According to the wearable electrical stimulation treatment device of the embodiment of the utility model, the vibration module 50 generates the vibration with the preset frequency and the preset amplitude, the electrical pulse module 10 is accurately controlled to output the electrical pulse to the electrical stimulation module 20, and different electrical pulses are accurately applied according to different treatment scenes; meanwhile, the wearable electric stimulation treatment device can still be suitable for the situation that the user can not move autonomously, and applicable people of the wearable electric stimulation treatment device are increased.

Fig. 3 shows a schematic diagram of a circuit module of the wearable electrical stimulation therapy device according to yet another embodiment of the utility model. As shown in fig. 3, the wearable electrical stimulation treatment device of the present embodiment further includes, in addition to the wearable electrical stimulation treatment devices of the two embodiments: an energy storage module 60.

The energy storage module 60 is electrically connected with the rechargeable power conversion module 40 and the central control module 30 respectively; the central control module 30 controls the electrical pulse module 10 to be electrically disconnected from all the electrical stimulation components 22 of the electrical stimulation module 20, and when the vibration module 50 is electrically disconnected from the rechargeable power conversion module 40, the electrical pulse module 10 is electrically connected with the energy storage module 60, and the electrical pulses output by the electrical pulse module 10 are stored in the energy storage module 60 after being preprocessed; when the central control module 30 controls the vibration module 50 to be electrically connected to the rechargeable power conversion module 40, the rechargeable power conversion module 40 receives the electric energy transmitted by the energy storage module 60 to supply power to the vibration module 50 through the central control module 30.

In order to make the connection and operation of the above modules more clear for those skilled in the art, the following detailed description is provided:

consider the following scenario in which the user carries only the wearable electrical stimulation therapy device and does not perform electrical stimulation therapy, including but not limited to the following scenarios: the wearable electrical stimulation treatment device is worn by a user and is not taken down after electrical stimulation treatment; or the user transfers the wearable electrical stimulation therapy device with him.

In the above situation, the wearable electrical stimulation therapy device is not used for electrical stimulation therapy, but at least one of the friction generator, the piezoelectric generator, the pressure induction cable based on the friction generator, the pressure induction cable based on the piezoelectric generator, and the piezoelectric and triboelectric hybrid generator included in the electrical pulse module 10 may still convert the mechanical energy acted thereon by the external environment into electrical pulses. The wearable electrical stimulation treatment device of the present embodiment further includes an energy storage module 60, and the electrical pulses output by the electrical pulse module 10 are stored in the energy storage module 60 after being preprocessed.

The energy storage module 60 is activated on the premise that the wearable electrical stimulation treatment device is not used for electrical stimulation treatment, and the vibration module 50 does not need to supply power to work. Therefore, only when the central control module 30 controls the electrical pulse module 10 to be electrically disconnected from all the electrical stimulation components 22 of the electrical stimulation module 20 and the vibration module 50 is electrically disconnected from the rechargeable power supply replacement module 40, the electrical pulse module 10 is electrically connected to the energy storage module 60, and the electrical pulses output by the electrical pulse module 10 are pre-processed and stored in the energy storage module 60.

The energy storage module 60 may include, but is not limited to, a rectifying component (not shown), an amplifying component (not shown), a filtering component (not shown), and a battery component (not shown) to pre-process the electrical pulses. The rectification component is electrically connected with the central control module 30, and when the central control module 30 controls the electrical connection of the electrical pulse module 10 and the rectification component, the rectification component rectifies the electrical pulse converted by the electrical pulse module 10; the amplifying part is electrically connected with the rectifying part and is used for amplifying the electric signal output by the rectifying part; the filtering part is respectively electrically connected with the amplifying part and the battery part and is used for filtering interference noise waves in the electric signals output by the amplifying part so as to store the preprocessed electric pulses to the battery part. The energy storage module 60 comprises a rectifying component, an amplifying component and a filtering component which are optional components, and a person skilled in the art can perform screening according to actual needs. For example, if the amplification process is not required, the amplification unit may be omitted.

The above working process is actually an energy collection charging process of the wearable electrical stimulation treatment device. After the electric pulse converted by the electric pulse module 10 is pre-processed and stored in the energy storage module 60, the electric energy can be supplied to the vibration module 50 through the rechargeable power conversion module 40 when the vibration module 50 operates.

When the central control module 30 controls the vibration module 50 to be electrically connected to the rechargeable power conversion module 40, the electric energy stored in the energy storage module 60 is converted into the voltage and/or current parameters adapted to the vibration module 50 by the rechargeable power conversion module 40, so as to supply power to the vibration module 50. The working process is actually the discharging process of the wearable electrical stimulation treatment device.

Those skilled in the art will appreciate that the power that the vibration module 50 can obtain through the control of the central control module 30 is derived from the rechargeable power conversion module 40; the power of the rechargeable power conversion module 40 can be derived from the energy storage module 60 or from a prior art power charging form. The rechargeable power conversion module 40 has a double meaning, namely, the energy storage module 60 stores electric energy converted from mechanical energy applied thereto by the external environment through the electric pulse module 10, and the double meaning is a power charging form in the prior art.

According to the wearable electrical stimulation treatment device of the embodiment of the utility model, after the electrical pulse module 10 converts the mechanical energy acted on the electrical pulse module by the external environment into the electrical pulse, the electrical pulse is released without electrical stimulation treatment, so that the part of the electrical energy is collected in the energy storage module 60, and the rechargeable power supply conversion module 40 supplies power to the vibration module 50, thereby improving the energy utilization efficiency.

Fig. 4 shows a schematic diagram of a circuit module of the wearable electrical stimulation therapy device according to still another embodiment of the utility model. As shown in fig. 4, the central control module 30 of the wearable electrical stimulation treatment device of the present embodiment includes: a radio transmitting and receiving section 31, and a terminal device 32.

The wireless transceiver 31 is electrically connected to the rechargeable power supply control module 40, wirelessly connected to the terminal device 32, and configured to receive a control signal of the terminal device 32 through power supply of the rechargeable power supply conversion module 40; the central control module 30 performs control according to the control signal.

In order to make the connection and operation of the above modules more clear for those skilled in the art, the following detailed description is provided:

considering the following situations, it is inconvenient for the user to directly operate the central control module 30 after wearing the wearable electrical stimulation therapy device, including but not limited to the following situations: the wearable electrical stimulation treatment device worn by the user is located on the back and other places where the user is not easy to touch, or the central control module 30 is integrated inside the wearable electrical stimulation treatment device.

In the above situation, the central control module 30 of the wearable electrical stimulation treatment apparatus of the present embodiment includes the wireless transceiving part 31 and the terminal device 32. The user sends a control signal by operating the terminal device 32, and the wireless transceiver 31 receives the control signal, so that the central control module 30 performs control according to the control signal.

Terminal devices 32 may include, but are not limited to: an infrared remote control terminal, a mobile phone terminal, a computer terminal, a third-party system and the like. The skilled person can select the desired one according to the actual needs, without limitation.

The electric pulse module 10 of the present invention will be described in detail below. The electrical pulse module 10 may be at least one of a triboelectric generator, a piezoelectric generator, a triboelectric generator-based pressure sensing cable, a piezoelectric generator-based pressure sensing cable, a hybrid piezoelectric and triboelectric generator.

The friction generator can be a three-layer structure, a four-layer structure, a five-layer intermediate film structure or a five-layer intermediate electrode structure friction generator. Said friction generator comprising at least two surfaces forming a friction interface, said friction generator having an output end; the piezoelectric generator can be a piezoelectric generator made of piezoelectric materials such as zinc oxide, PZT, PVDF and the like in the prior art.

The friction generator may also be a woven friction generator based on friction members. A friction member based woven friction generator comprising: at least one first friction member and at least one second friction member; wherein the at least one first friction member is interwoven with the at least one second friction member to form a friction member based woven friction generator; the at least one first friction component and/or the at least one second friction component comprise friction interfaces capable of contacting and rubbing; the at least one first friction element and/or the at least one second friction element have an electrical signal output of the friction element based woven friction generator.

In a first embodiment, a friction member based woven friction generator comprises: at least one first friction member and at least one second friction member. Wherein the at least one first friction member comprises a first high molecular polymer insulator; at least one second friction member comprises a second electrical conductor; the first high polymer insulator and the second conductor are mutually woven to form a woven friction generator based on a friction component; a friction interface is formed by contact friction between the first high molecular polymer insulator and the second conductor, and/or between the first high molecular polymer insulator and the body to be generated, and/or between the second conductor and the body to be generated; the second electrical conductor serves as an electrical signal output of the friction member based woven friction generator.

In a second embodiment, a friction member based woven friction generator comprises: at least one first friction member and at least one second friction member. Wherein the at least one first friction member comprises a first electrical conductor and a first high molecular polymer insulator; at least one second friction member comprises a second electrical conductor; the first high polymer insulator is arranged on the outer side surface of the first conductor; the first conductor, the first high polymer insulator and the second conductor are mutually woven to form a woven friction generator based on a friction part; the friction interface is formed by contact friction between the first conductor and the first high polymer insulator, and/or between the first conductor and the second conductor, and/or between the first conductor and the body to be generated, and/or between the first high polymer insulator and the second conductor, and/or between the first high polymer insulator and the body to be generated, and/or between the second conductor and the body to be generated; the first electrical conductor and/or the second electrical conductor serve as an electrical signal output of the friction member-based woven friction generator.

In a third embodiment, a friction member based woven friction generator comprises: at least one first friction member and at least one second friction member. Wherein the at least one first friction member comprises a first electrical conductor and a first high molecular polymer insulator; the at least one second friction part comprises a second electric conductor and a second high polymer insulator, the first high polymer insulator is arranged on the outer side surface of the first electric conductor, and the second high polymer insulator is arranged on the outer side surface of the second electric conductor; the first conductor and the first high polymer insulator, and the second conductor and the second high polymer insulator are mutually woven to form a woven friction generator based on a friction component; the first conductor and the first high polymer insulator, and/or the first conductor and the second high polymer insulator, and/or the first conductor and the body to be generated, and/or the first conductor and the second conductor, and/or the first high polymer insulator and the second high polymer insulator, and/or the first high polymer insulator and the body to be generated, and/or the first high polymer insulator and the second conductor, and/or the second high polymer insulator and the body to be generated, and/or the second conductor and the second high polymer insulator, and/or the second conductor and the body to be generated contact and rub to form a friction interface; the first electrical conductor and/or the second electrical conductor serve as an electrical signal output of the friction member-based woven friction generator.

In a fourth embodiment, a friction member based woven friction generator comprises: at least one first friction member and at least one second friction member. Wherein the at least one first friction member comprises a first electrical conductor and a first high molecular polymer insulator; at least one second friction member comprises a second high molecular polymer insulator; the first high polymer insulator is arranged on the outer side surface of the first conductor; the first conductor, the first high polymer insulator and the second high polymer insulator are mutually woven to form a woven friction generator based on a friction part; a friction interface is formed by contact friction between the first conductor and the first high polymer insulator, and/or between the first conductor and the second high polymer insulator, and/or between the first conductor and the body to be generated, and/or between the first high polymer insulator and the second high polymer insulator, and/or between the first high polymer insulator and the body to be generated, and/or between the second high polymer insulator and the body to be generated; the first electrical conductor serves as an electrical signal output of the friction member based woven friction generator.

In a fifth embodiment, a friction member based woven friction generator comprises: at least one first friction member and at least one second friction member. Wherein at least one first friction member comprises a first electrical conductor; at least one second friction member comprises a second electrical conductor; the first conductor and the second conductor are mutually woven to form a woven friction generator based on the friction component; the friction interface is formed by the contact friction between the first conductor and the second conductor, and/or between the first conductor and the body to be generated, and/or between the second conductor and the body to be generated; the first electrical conductor and/or the second electrical conductor serve as an electrical signal output of the friction member-based woven friction generator.

In the second, third, and fourth embodiments, the first polymer insulator may be disposed on the outer surface of the first conductor in a covering or winding-braiding manner to form at least one first friction member; specifically, fig. 5a shows that the first polymer insulator 12 is disposed on the outer surface of the first conductor 11 in a covering manner to form at least one first friction member, and fig. 5b shows that the first polymer insulator 12 is disposed on the outer surface of the first conductor 11 in a winding and weaving manner to form at least one first friction member. In the third embodiment, the second polymer insulator may be provided on the outer surface of the second conductor in a covering or winding-braiding manner to form at least one second friction member. That is, the first polymer insulator is disposed on the outer surface of the first conductor in a covering or winding and weaving manner to form at least one first friction member; and/or the second high polymer insulator is arranged on the outer side surface of the second conductor in a covering or winding weaving mode to form at least one second friction part. The selection can be made by those skilled in the art according to the actual needs, and is not limited herein.

It should be noted that when at least one first friction member is formed in a winding weave, at least one first friction member may be formed by winding and weaving one first electric conductor 11 and one first polymer insulator 12 as shown in fig. 5 b; at least one first friction component can also be formed by winding and weaving one first conductor and a plurality of first high polymer insulators; at least one first friction part can be formed by winding and weaving a plurality of first electric conductors and a first high polymer insulator; the first friction member may be formed by winding and braiding a plurality of first conductors and a plurality of first polymer insulators, and those skilled in the art may select the first friction member according to actual needs, which is not limited herein. For the description of forming at least one second friction member in a winding weave manner, reference may be made to the above description of forming at least one first friction member in a winding weave manner, which will not be described herein again.

In a first embodiment, the first polymer insulator may comprise a plurality of polymer insulated wires forming the first polymer insulator in a intertwined weave, and/or the second electrical conductor may comprise a plurality of electrically conductive wires forming the second electrical conductor in a intertwined weave; in a second embodiment, the first electrical conductor may comprise a plurality of electrically conductive wires forming the first electrical conductor in a intertwined braid, and/or the first polymer insulator may comprise a plurality of polymer insulated wires forming the first polymer insulator in a intertwined braid, and/or the second electrical conductor may comprise a plurality of electrically conductive wires forming the second electrical conductor in a intertwined braid; in a third embodiment, the first electrical conductor may comprise a plurality of electrically conductive wires, the plurality of electrically conductive wires forming the first electrical conductor in a intertwined weave, and/or the first polymeric insulator may comprise a plurality of polymeric insulated wires, the plurality of polymeric insulated wires forming the first polymeric insulator in a intertwined weave, and/or the second electrical conductor may comprise a plurality of electrically conductive wires, the plurality of electrically conductive wires forming the second electrical conductor in a intertwined weave, and/or the second polymeric insulator may comprise a plurality of polymeric insulated wires, the plurality of polymeric insulated wires forming the second polymeric insulator in a intertwined weave; in a fourth embodiment, the first electrical conductor may comprise a plurality of electrically conductive wires forming the first electrical conductor in a intertwined braid, and/or the first high polymer insulator may comprise a plurality of high polymer insulated wires forming the first high polymer insulator in a intertwined braid, and/or the second high polymer insulator may comprise a plurality of high polymer insulated wires forming the second high polymer insulator in a intertwined braid; in a fifth embodiment, the first electrical conductor may comprise a plurality of electrically conductive wires, the plurality of electrically conductive wires forming the first electrical conductor in a wound braid, and/or the second electrical conductor may comprise a plurality of electrically conductive wires, the plurality of electrically conductive wires forming the second electrical conductor in a wound braid; the selection can be made by those skilled in the art according to the actual needs, and is not limited herein.

The above-mentioned various ways of forming the first friction member, the second friction member, the first conductor, the first polymer insulator, the second conductor and the second polymer insulator may be used in any combination, and those skilled in the art may select them according to actual needs, and the utility model is not limited thereto. For example: in a fourth embodiment, a plurality of polymer insulated wires are mutually wound and woven to form a first polymer insulator, and the first polymer insulator is coated on the outer side surface of a first conductor to form at least one first friction part; a plurality of high polymer insulated wires are mutually wound and woven to form a second high polymer insulator, namely at least one second friction part is formed; the at least one first friction member is interwoven with the at least one second friction member to form a friction member based woven friction generator.

In order to enable the surfaces forming the friction interface in the friction member based woven friction generator to better contact friction, a member structure may be provided on at least one surface forming the friction interface in the friction member based woven friction generator. The present invention does not limit the kind and number of the recesses and the members included in the member structure, and those skilled in the art can flexibly set the kind and number of the recesses and the members included in the member structure.

The materials used by the first conductor and the second conductor are indium tin oxide, graphene, silver nanowire films, metals or alloys; wherein the metal is gold, silver, platinum, palladium, aluminum, nickel, copper, titanium, chromium, selenium, iron, manganese, molybdenum, tungsten or vanadium; the alloy is an aluminum alloy, a titanium alloy, a magnesium alloy, a beryllium alloy, a copper alloy, a zinc alloy, a manganese alloy, a nickel alloy, a lead alloy, a tin alloy, a cadmium alloy, a bismuth alloy, an indium alloy, a gallium alloy, a tungsten alloy, a molybdenum alloy, a niobium alloy, or a tantalum alloy.

The first polymer insulator and the second polymer insulator are made of a material selected from the group consisting of polytetrafluoroethylene, polydimethylsiloxane, polyimide, aniline formaldehyde resin, polyoxymethylene, ethylcellulose, polyamide, melamine formaldehyde, polyethylene glycol succinate, cellulose acetate, polyethylene glycol adipate, polydiallyl phthalate, fibrous (regenerated) sponge, polyurethane elastomer, styrene-propylene copolymer, styrene-butadiene copolymer, rayon, and polymethyl, any one of methacrylate, polyvinyl alcohol, polyester, polyisobutylene, polyurethane flexible sponge, polyethylene terephthalate, polyvinyl butyral, formaldehyde phenol, neoprene, butadiene-propylene copolymer, natural rubber, polyacrylonitrile, acrylonitrile vinyl chloride, and polyethylene propylene carbonate.

In order to improve the friction power generation effect, different high polymer materials are preferably used between the surface of the high polymer material capable of contacting friction and the surface of the high polymer material included in the at least one first friction member and/or the at least one second friction member. For example: in the third and fourth embodiments, since the first polymer insulator and the second polymer insulator can contact friction, the first polymer insulator and the second polymer insulator are preferably different polymer materials in order to improve the effect of friction power generation.

To increase the comfort of use for the user, the electric pulse module 10 preferably employs a flexible triboelectric generator, and/or a piezoelectric generator, and/or a pressure-sensitive cable based on a triboelectric generator and/or a piezoelectric generator, and/or a piezoelectric and triboelectric hybrid generator. In order to avoid electromagnetic interference in the external environment from affecting the normal operation of the electric pulse module 10, the electric pulse module 10 preferably employs a friction generator and/or a piezoelectric generator, and/or a pressure-sensitive cable based on the friction generator and/or the piezoelectric generator, and/or a piezoelectric and triboelectric hybrid generator, which are externally provided with a shielding layer. In order to avoid that external environmental factors (such as temperature, humidity and/or dust and the like) influence the normal operation of the electric pulse module 10, the electric pulse module 10 preferably adopts a friction generator and/or a piezoelectric generator, and/or a pressure induction cable based on the friction generator and/or the piezoelectric generator, and/or a piezoelectric and triboelectric hybrid generator, which are externally provided with a protective layer. In order to avoid electromagnetic interference in the external environment and at the same time avoid the influence of external environmental factors (such as temperature, humidity and/or dust, etc.), the electric pulse module 10 preferably employs a friction generator, and/or a piezoelectric generator, and/or a pressure-sensitive cable based on the friction generator and/or the piezoelectric generator, and/or a piezoelectric and triboelectric hybrid generator, which are sequentially provided with a shielding layer and a protective layer on the outside, so as to ensure the normal operation of the electric pulse module 10.

When the electrical pulse module 10 includes a friction generator based pressure sensing cable, and/or a piezoelectric generator based pressure sensing cable, the friction generator based pressure sensing cable, and/or the piezoelectric generator based pressure sensing cable may be braided to form the electrical pulse module 10 with a predetermined appearance.

Alternatively, when the electric pulse module 10 comprises a friction member based woven friction generator, the at least one first friction member and the at least one second friction member may be woven using a weaving method to form the electric pulse module 10 with a predetermined appearance.

The preset shapes contemplated by the present invention may include, but are not limited to, corsets, headgear, bandages, insoles. The at least one first friction member and the at least one second friction member may be woven, or the friction generator based pressure sensing cable and/or the piezoelectric generator based pressure sensing cable may be woven to a predetermined appearance, and may be used in combination with any one or more of the other generators of the present invention.

The wearable electrical stimulation treatment device of the present invention may further include: the body can be worn. The wearable body is provided with an electric pulse module 10, an electric stimulation module 20 and a central control module 30. Wearable bodies may include, but are not limited to, corsets, headgear, bandages, shoes.

Hereinafter, the technical solution of the present invention will be described in detail by specific embodiments.

In the first embodiment, the wearable electrical stimulation treatment device is applied to the field of corsets.

In one aspect, the wearable electrical stimulation treatment device includes an electrical pulse module 10, an electrical stimulation module 20, and a central control module 30.

The electric pulse module 10 can be a friction generator-based pressure induction cable and/or a piezoelectric generator-based pressure induction cable woven to form the electric pulse module 10 with a preset appearance; and/or at least one first friction member and at least one second friction member are woven to form the electrical pulse module 10 with a predetermined appearance. The preset appearance formed by the electric pulse module 10 is a corselet shape, and the user wears the corselet to wear the wearable electric stimulation treatment device.

The electrostimulation module 20 is arranged inside two cups of the corselet, and the elastic insulating substrate 21 is adjusted according to the shape of the chest of the user, so that the plurality of electrostimulation components 22 on the elastic insulating substrate are wrapped on the skin surface of the chest of the user. The user can drive the corset-shaped electric pulse module 10 to generate electric pulses by only doing arm swinging actions.

The central control module 30 is disposed outside the centers of the two cups of the corset-shaped electric pulse module 10 for user operation and control.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 by controlling the central control module 30, so that electrical stimulation can be performed on mammary glands, lymph and the like. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the central control module 30, and the electrical stimulation treatment can be stopped.

In another case, the wearable electrical stimulation treatment device comprises an electrical pulse module 10, an electrical stimulation module 20, a central control module 30 and a wearable body.

The wearable body is a corselet; the electric pulse module 10 is arranged at the relative position of two armpits of the corset; the electrostimulation module 20 is arranged inside two cups of the corselet, and the elastic insulating substrate 21 is adjusted according to the shape of the chest of the user, so that the plurality of electrostimulation components 22 on the elastic insulating substrate are wrapped on the skin surface of the chest of the user. The user only needs to do the motion similar to arm swinging, and the electric pulse module 10 at the armpit part can be driven to generate electric pulses.

The central control module 30 is disposed outside the centers of the two cups of the corset, and it is not easy to directly operate and control the central control module 30 in consideration that a user still wears other clothes after wearing the corset, so that the central control module 30 includes a wireless transceiving component 31 and a terminal device 32, so that the user can remotely control the corset by operating the terminal device 32.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 through the control of the terminal device 32, so that electrical stimulation can be performed on mammary glands, lymph and the like. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the terminal device 32, and the electrical stimulation treatment can be stopped.

In the second embodiment, the wearable electrical stimulation treatment device is applied to the field of headgear.

In one aspect, the wearable electrical stimulation treatment device includes an electrical pulse module 10, an electrical stimulation module 20, and a central control module 30.

The electric pulse module 10 can be a friction generator-based pressure induction cable and/or a piezoelectric generator-based pressure induction cable woven to form the electric pulse module 10 with a preset appearance; and/or at least one first friction member and at least one second friction member are woven to form the electrical pulse module 10 with a predetermined appearance. The preset appearance formed by the electric pulse module 10 is in the shape of a head cover, such as a hat, and the wearable electric stimulation treatment device is worn by a user.

The electrical stimulation module 20 is arranged in the head cover, and the elastic insulating substrate 21 is adjusted according to the shape of the top of the skull of the user, so that the plurality of electrical stimulation components 22 on the elastic insulating substrate wrap the surface of the top of the skull skin of the user. The user can drive the electric pulse module 10 in the shape of the head cover to generate electric pulse as long as the head rotates.

Since the elastic insulating substrate 21 serves to fix the plurality of electrical stimulation components 22 around the skin surface of the user, the electrical pulse module 10 in the shape of a headset can be designed in any aesthetic form according to the preference of the user. This makes the user can carry out effectual electro photoluminescence when wearing wearable electro photoluminescence treatment device, can guarantee again pleasing to the eye effect.

The central control module 30 may be disposed on the outer surface of the headset-shaped electric pulse module 10 to facilitate direct operation and control by the user.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 by controlling the central control module 30, so that electrical stimulation can be performed on the vertex. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the central control module 30, and the electrical stimulation treatment can be stopped.

In another case, the wearable electrical stimulation treatment device comprises an electrical pulse module 10, an electrical stimulation module 20, a central control module 30 and a wearable body.

The wearable body is a head sleeve; the electric pulse module 10 is arranged on the inner side surface of the head cover or the surface of the elastic insulating substrate 21 far away from the plurality of electric stimulation components 22; the electrical stimulation module 20 is arranged in the head cover, and the elastic insulating substrate 21 is adjusted according to the shape of the top of the skull of the user, so that the plurality of electrical stimulation components 22 on the elastic insulating substrate wrap the surface of the top of the skull skin of the user. The user can drive the electric pulse module 10 in the shape of the head cover to generate electric pulse as long as the head rotates.

Since the elastic insulating substrate 21 plays a role of fixing the plurality of electrostimulation parts 22 to wrap the skin surface of the user, the shape of the head cover can be any beautiful cap or the like according to the preference of the user. This makes the user can carry out effectual electro photoluminescence when wearing wearable electro photoluminescence treatment device, can guarantee again pleasing to the eye effect.

The central control module 30 can hide the space between the head cover and the elastic insulating base 21, and for the convenience of user operation control, the central control module 30 includes a wireless transceiver 31 and a terminal device 32, so that the user can realize remote control by operating the terminal device 32.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 through the control of the terminal device 32, so that electrical stimulation can be performed on the vertex. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the terminal device 32, and the electrical stimulation treatment can be stopped.

In the third embodiment, the wearable electrical stimulation treatment device is applied to the field of bandages.

In one aspect, the wearable electrical stimulation treatment device includes an electrical pulse module 10, an electrical stimulation module 20, a central control module 30, a rechargeable power conversion module 40, and a vibration module 50.

The electric pulse module 10 can be a friction generator-based pressure induction cable and/or a piezoelectric generator-based pressure induction cable woven to form the electric pulse module 10 with a preset appearance; and/or at least one first friction member and at least one second friction member are woven to form the electrical pulse module 10 with a predetermined appearance. The preset appearance formed by the electric pulse module 10 is in the shape of a bandage, and the user wears the bandage, namely the wearable electric stimulation treatment device.

The electrostimulation module 20 is disposed inside the bandage, and the elastic insulating substrate 21 is adjusted according to the shape of the skin surface of the user so that the plurality of electrostimulation elements 22 thereon are wrapped around the skin surface of the user.

In the scene of using the bandage, the user often is for the condition that has injuries such as traumatic injury, should not carry out autonomous movement, and wearable electrical stimulation treatment device still includes rechargeable power conversion module 40 and vibration module 50, through the vibration of the preset frequency and the preset amplitude that vibration module 50 produced, makes electrical pulse module 10 convert the electric pulse to electrical stimulation module 20 and carry out the electrical stimulation treatment.

The central control module 30, the rechargeable power conversion module 40, and the vibration module 50 may be disposed on the outer surface of the bandage-shaped electrical pulse module 10 to facilitate direct manipulation and control by a user.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 by controlling the central control module 30, so that electrical stimulation can be performed on the skin. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the central control module 30, and the electrical stimulation treatment can be stopped.

In another case, the wearable electrical stimulation treatment device comprises an electrical pulse module 10, an electrical stimulation module 20, a central control module 30, a rechargeable power conversion module 40, a vibration module 50 and a wearable body.

The wearable body is a bandage; the electric pulse module 10 is arranged on the outer side surface of the bandage; the electrostimulation module 20 is arranged inside the bandage, and the elastic insulating substrate 21 is adjusted according to the skin shape of the user, so that the plurality of electrostimulation elements 22 on the elastic insulating substrate wrap the skin surface of the user.

In the scene of using the bandage, the user often is for the condition that has injuries such as traumatic injury, should not carry out autonomous movement, and wearable electrical stimulation treatment device still includes rechargeable power conversion module 40 and vibration module 50, through the vibration of the preset frequency and the preset amplitude that vibration module 50 produced, makes electrical pulse module 10 convert the electric pulse to electrical stimulation module 20 and carry out the electrical stimulation treatment.

The central control module 30 and the rechargeable power conversion module 40 can be disposed on the outer surface of the bandage, and the vibration module 50 is disposed in contact with the electrical pulse module 10.

When a user needs to perform electrical stimulation treatment, each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20 is electrically communicated with the electrical pulse module 10 by controlling the central control module 30, so that electrical stimulation can be performed on the skin. When the user does not need to perform the electrical stimulation treatment, all the electrical stimulation components 22 of the electrical stimulation module 20 are electrically disconnected from the electrical pulse module 10 by controlling the central control module 30, and the electrical stimulation treatment can be stopped.

In the fourth embodiment, the wearable electrical stimulation treatment device is applied to the field of shoes.

In one aspect, the wearable electrical stimulation treatment device includes an electrical pulse module 10, an electrical stimulation module 20, a central control module 30, a rechargeable power conversion module 40, a vibration module 50, and an energy storage module 60.

The electric pulse module 10 can be a friction generator-based pressure induction cable and/or a piezoelectric generator-based pressure induction cable woven to form the electric pulse module 10 with a preset appearance; and/or at least one first friction member and at least one second friction member are woven to form the electrical pulse module 10 with a predetermined appearance. The preset appearance formed by the electric pulse module 10 is in the shape of an insole, and a user wears a shoe containing the insole, namely the wearable electric stimulation treatment device.

The electrical stimulation module 20 is arranged on one side of the insole facing the foot of the user, and the elastic insulating base 21 is adjusted according to the shape of the arch of the user, so that the plurality of electrical stimulation components 22 on the elastic insulating base are attached to the arch surface of the user.

In the scenario of using the insole, the user may not need the electrical stimulation treatment for the walking state, and the electrical stimulation treatment for the static state. The wearable electrical stimulation therapy device further comprises a rechargeable power conversion module 40, a vibration module 50 and an energy storage module 60.

The central control module 30, the rechargeable power conversion module 40 and the energy storage module 60 can be disposed on a side of the insole away from the foot of the user, and the vibration module 50 is disposed in contact with the insole-shaped electric pulse module 10. To facilitate user operation control, the central control module 30 includes a wireless transceiving section 31 and a terminal device 32, so that a user can perform remote control by operating the terminal device 32.

When the user does not need electrical stimulation treatment in the walking state, the electrical pulse module 10 is electrically communicated with the energy storage module 60 through the control of the terminal device 32, so that the mechanical energy of the user walking can be converted into electrical energy for storage. When the walking state of the user needs the electrical stimulation treatment, the electrical pulse module 10 is electrically communicated with each electrical stimulation component 22 or specific electrical stimulation component 22 of the electrical stimulation module 20 through the control of the terminal device 32, so that the foot acupuncture points can be electrically stimulated. When the user is in a static state and needs electrical stimulation treatment, the vibration module 50 receives the power supply of the rechargeable power supply conversion module 40 through the control of the terminal device 32, generates vibration with preset frequency and preset amplitude and transmits the vibration to the electrical pulse module 10, so that when the electrical pulse module 10 is electrically communicated with each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20, electrical stimulation is performed on the sole acupuncture points.

In another case, the wearable electrical stimulation therapy device includes an electrical pulse module 10, an electrical stimulation module 20, a central control module 30, a rechargeable power conversion module 40, a vibration module 50, an energy storage module 60, and a wearable body.

The wearable body is a shoe; the electric pulse module 10 can be arranged in the cavity of the sole; the electrical stimulation module 20 is disposed on the insole, and the elastic insulating substrate 21 is adjusted according to the shape of the arch of the user, so that the plurality of electrical stimulation components 22 thereon are attached to the surface of the arch of the user.

In the scenario of using the insole, the user may not need the electrical stimulation treatment for the walking state, and the electrical stimulation treatment for the static state. The wearable electrical stimulation therapy device further comprises a rechargeable power conversion module 40, a vibration module 50 and an energy storage module 60.

The central control module 30, the rechargeable power conversion module 40 and the energy storage module 60 can be disposed in the cavity of the sole, and the vibration module 50 is disposed in contact with the electrical pulse module 10. To facilitate user operation control, the central control module 30 includes a wireless transceiving section 31 and a terminal device 32, so that a user can perform remote control by operating the terminal device 32.

When the user does not need electrical stimulation treatment in the walking state, the electrical pulse module 10 is electrically communicated with the energy storage module 60 through the control of the terminal device 32, so that the mechanical energy of the user walking can be converted into electrical energy for storage. When the walking state of the user needs the electrical stimulation treatment, the electrical pulse module 10 is electrically communicated with each electrical stimulation component 22 or specific electrical stimulation component 22 of the electrical stimulation module 20 through the control of the terminal device 32, so that the foot acupuncture points can be electrically stimulated. When the user is in a static state and needs electrical stimulation treatment, the vibration module 50 receives the power supply of the rechargeable power supply conversion module 40 through the control of the terminal device 32, generates vibration with preset frequency and preset amplitude and transmits the vibration to the electrical pulse module 10, so that when the electrical pulse module 10 is electrically communicated with each electrical stimulation component 22 or a specific electrical stimulation component 22 of the electrical stimulation module 20, electrical stimulation is performed on the sole acupuncture points.

It will also be appreciated that the arrangement of devices shown in the figures or embodiments is merely schematic and represents a logical arrangement. Where modules shown as separate components may or may not be physically separate, components shown as modules may or may not be physical modules.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the utility model. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (12)

1. A wearable electrical stimulation therapy device, comprising: the device comprises an electric pulse module, an electric stimulation module and a central control module; wherein the content of the first and second substances,

the electric pulse module is electrically connected with the central control module and is used for converting mechanical energy acted on the electric pulse module by an external environment into electric pulses; the electric pulse module includes: at least one of a friction generator, a piezoelectric generator, a pressure induction cable based on the friction generator, a pressure induction cable based on the piezoelectric generator, and a piezoelectric and triboelectric hybrid generator;

the electrical stimulation module is in contact with a skin surface of a user, comprising: an elastic insulating substrate, and a plurality of electrostimulation members; the elastic insulating substrate is adjusted to be in a preset shape according to the skin surface of the user, and the plurality of electrical stimulation components are arranged on one side, close to the skin surface of the user, of the insulating substrate and are respectively and electrically connected with the central control module;

the central control module is used for controlling the electric pulse module to be electrically connected with or disconnected from each electric stimulation component of the electric stimulation module;

and when each electrical stimulation component of the electrical stimulation module is electrically communicated with the electrical pulse module through the control of the central control module, the electrical stimulation component applies the electrical pulse output by the electrical pulse module to the skin surface of the user for electrical stimulation.

2. The wearable electrical stimulation therapy device according to claim 1, characterized in that the electrical stimulation therapy device further comprises: the device comprises a rechargeable power supply conversion module and a vibration module; wherein the content of the first and second substances,

the vibration module is arranged in contact with the electric pulse module;

the central control module is respectively electrically connected with the rechargeable power supply conversion module and the vibration module and is used for controlling the vibration module to be electrically connected with or disconnected from the rechargeable power supply conversion module;

the vibration module receives power supply of the rechargeable power supply conversion module when being electrically communicated with the rechargeable power supply conversion module through the control of the central control module, generates vibration with preset frequency and preset amplitude and transmits the vibration to the electric pulse module.

3. The wearable electrical stimulation therapy device according to claim 2, characterized in that the electrical stimulation therapy device further comprises: an energy storage module; wherein the content of the first and second substances,

the energy storage module is electrically connected with the rechargeable power supply conversion module and the central control module respectively;

the central control module controls the electric pulse module to be electrically disconnected with all electric stimulation components of the electric stimulation module, and when the vibration module is electrically disconnected with the rechargeable power supply conversion module, the electric pulse module is electrically connected with the energy storage module, and electric pulses output by the electric pulse module are preprocessed and then stored in the energy storage module;

when the central control module controls the vibration module to be electrically communicated with the rechargeable power supply conversion module, the rechargeable power supply conversion module receives the electric energy transmitted by the energy storage module so as to supply power to the vibration module through the central control module.

4. The wearable electrical stimulation therapy device according to any one of claims 2-3, wherein the central control module comprises: a wireless transmitting/receiving unit and a terminal device; wherein the content of the first and second substances,

the wireless transceiver component is electrically connected with the rechargeable power supply control module, is wirelessly connected with the terminal equipment, and is used for receiving a control signal of the terminal equipment through the power supply of the rechargeable power supply conversion module;

and the central control module controls according to the control signal.

5. The wearable electrical stimulation therapy device according to claim 1, characterized in that the triboelectric generator is a triboelectric generating film and/or the piezoelectric generator is a piezoelectric generating film.

6. The wearable electrical stimulation therapy device according to claim 1, wherein the triboelectric generator comprises: a friction member based woven friction generator; wherein the content of the first and second substances,

the friction member based woven friction generator includes: at least one first friction member and at least one second friction member;

at least one first friction component and at least one second friction component are woven with each other to form the friction component-based woven friction generator, and at least one of the at least one first friction component and the at least one second friction component comprises a friction interface capable of contacting and rubbing;

at least one of the first friction member and/or at least one of the second friction member has an electrical signal output of the friction member based woven friction generator, the electrical signal output being electrically connected to the central control module.

7. The wearable electrical stimulation therapy device according to claim 6, wherein the friction generator based pressure sensing cable, and/or the piezoelectric generator based pressure sensing cable are braided to form the electrical pulse module of a preset appearance;

and/or at least one first friction component and at least one second friction component are woven to form the electric pulse module with a preset appearance.

8. The wearable electrical stimulation therapy device according to claim 7, wherein the predetermined appearance is one of a headgear, a corsage, a bandage, and an insole.

9. The wearable electrical stimulation treatment device of any one of claims 1-3 and 5-6, wherein the electrical stimulation skin treatment device further comprises: a wearable body; the wearable body is provided with the electric pulse module, the electric stimulation module and the central control module.

10. The wearable electrical stimulation therapy device according to claim 4, characterized in that the electrical stimulation skin therapy device further comprises: a wearable body; the wearable body is provided with the electric pulse module, the electric stimulation module and the central control module.

11. The wearable electrical stimulation therapy device according to claim 9, wherein the wearable body is one of a headgear, a corsage, a bandage, and a shoe.

12. The wearable electrical stimulation therapy device according to claim 10, wherein the wearable body is one of a headgear, a corsage, a bandage, and a shoe.

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