CN108815703B - Foot sole electric stimulation massager - Google Patents

Abstract

The invention discloses a plantar electrical stimulation massager, which comprises a base plate and a host. The upper surface interval of backing plate is provided with first electrically conductive district of trampling and the electrically conductive district of trampling of second, two all set up an electric connection point on the electrically conductive district of trampling. The host is used for outputting pulse current, the host is installed on the base plate and provided with two current output contacts, and the host is respectively and correspondingly electrically connected with the two electric connection points on the conductive area through the connection of the two current output contacts. The technical scheme of the invention improves the use convenience of the plantar electrical stimulation massager.

Description

Foot sole electric stimulation massager

Technical Field

The invention relates to the technical field of physical therapy instruments, in particular to a plantar electrical stimulation massager.

Background

With the increasing living standard of people, individuals pay more and more attention to the health condition of the body. Further, the foot electro-stimulation massager is widely used in daily life of people, wherein the foot electro-stimulation massager has functions of massaging and electro-stimulation physiotherapy on the foot, so that the user can obtain effects of relaxation and physiotherapy.

However, the conventional foot electro-stimulation massagers are large-sized devices, so that users are very inconvenient to use, carry or carry.

Disclosure of Invention

The invention mainly aims to provide a plantar electrical stimulation massager, and aims to solve the problem of inconvenience in use.

In order to achieve the above object, the present invention provides a plantar electrical stimulation massager, comprising:

the upper surface of the base plate is provided with a first conductive treading area and a second conductive treading area at intervals, and the two conductive treading areas are provided with an electric connection point;

the host is used for outputting pulse current and is arranged on the base plate, the host is provided with two current output contacts, and the host is respectively and correspondingly electrically connected with the two electric connection points on the conductive area through the connection of the two current output contacts.

Preferably, the backing plate comprises an EVA bottom plate and a PU plate arranged on the upper surface of the EVA bottom plate;

the upper surface coating of PU board is equipped with silver thick liquid layer, first silver thick liquid layer and second silver thick liquid layer that silver thick liquid layer set up including the interval, first silver thick liquid layer is formed first electrically conductive trample the district, second silver thick liquid layer is formed the electrically conductive trample the district of second.

Preferably, the backing plate comprises an insulating silica gel base plate and a conductive silica gel layer arranged on the upper surface of the insulating silica gel base plate;

the conductive silica gel layer comprises a first conductive silica gel layer and a second conductive silica gel layer which are arranged at intervals, the first conductive silica gel layer forms the first conductive trampling area, and the second conductive silica gel layer forms the second conductive trampling area.

Preferably, a storage battery is arranged in the main machine;

the base plate is provided with a power generation device, and the power generation device is used for generating power to charge a storage battery in the host machine when the base plate is trampled.

Preferably, the power generation device comprises a magnet, a magnetic induction linear cutting element and two wires respectively connected with two ends of the magnetic induction linear cutting element; the two lead wires are electrically connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit;

the magnetic induction line cutting element is used for cutting the magnetic induction lines of the magnet to carry out magnetic induction electricity when the base plate is trampled, and further charges a storage battery in the host machine.

Preferably, a first accommodating cavity is arranged in the base plate, and the first accommodating cavity is arranged corresponding to the first conductive pedal area;

first magnet is installed to the bottom in first holding chamber, the upper surface of first magnet is provided with first compression spring, first compression spring's lower extreme with first magnet insulation is fixed, first compression spring's upper end with the insulating butt in top of backing plate, and first compression spring's both ends all are connected with the wire, and a rectifier is connected to two wires, and this rectifier through a charging circuit and with the battery electricity in the host computer is connected.

Preferably, a second accommodating cavity is further arranged in the base plate, and the second accommodating cavity is arranged corresponding to the second conductive pedal area;

the bottom of the second accommodating cavity is provided with a second magnet, a second compression spring is arranged on the upper surface of the second magnet, the lower end of the second compression spring is fixed to the second magnet in an insulating mode, the upper end of the second compression spring is in insulating abutting joint with the top of the base plate, two ends of the second compression spring are connected with conducting wires, the two conducting wires are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through another charging circuit.

Preferably, a first cavity is arranged in the backing plate and corresponds to the first conductive pedal area;

the bottom of the first cavity is provided with a third magnet, the upper surface of the third magnet is provided with a first elastic sheet, the lower end of the first elastic sheet is fixed with the third magnet in an insulating mode, the upper end of the first elastic sheet is abutted to the top of the base plate in an insulating mode, two ends of the first elastic sheet are connected with wires, the two wires are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit.

Preferably, a second cavity is further arranged in the base plate, and the second cavity is arranged corresponding to the second conductive pedal area;

the bottom of the second cavity is provided with a fourth magnet, the upper surface of the fourth insulating plate is provided with a second elastic sheet, the lower end of the second elastic sheet is fixed with the fourth magnet in an insulating mode, the upper end of the second elastic sheet is abutted to the top of the base plate in an insulating mode, the two ends of the second elastic sheet are connected with wires, the two wires are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit.

Preferably, a first air cavity and a second air cavity are arranged in the backing plate, the first air cavity is arranged corresponding to the first conductive pedal area, the second air cavity is arranged corresponding to the second conductive pedal area, and the first air cavity and the second air cavity are both provided with air outlets which are arranged oppositely;

an installation cavity is arranged between the first air cavity and the second air cavity, two magnets are oppositely arranged on the bottom surface and the top surface of the installation cavity, and the N poles and the S poles of the two magnets are oppositely arranged;

the accommodating cavity is also internally provided with a conductive rotating blade, one end of the conductive rotating blade is fixed in a rotating way, the other end of the conductive rotating blade penetrates through the two magnets and extends to the space between the air outlets of the first air cavity and the second air cavity, meanwhile, both ends of the conductive rotating blade are connected with leads, the two leads are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit.

According to the technical scheme, the sole electrical stimulation massager is matched with the main machine through the base plate, so that the effects of massage, motor physiotherapy, meridian dredging and muscle electrical stimulation can be achieved. Moreover, the height of the base plate can be set at will, and the base plate is extremely light in weight, so that the electric stimulation massager for the soles is convenient to use, carry, transport and the like.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of an electrical foot stimulation massager of the present invention;

FIG. 2 is an exploded view of the sole electric stimulation massager of FIG. 1;

FIG. 3 is a schematic structural view of another embodiment of the foot electro-stimulation massager of the present invention;

FIG. 4 is a rear view of the sole electrical stimulation massager of FIG. 3;

FIG. 5 is an exploded view of another embodiment of the foot electro-stimulation massager of the present invention;

FIG. 6 is a schematic view of a portion of the structure of FIG. 5;

FIG. 7 is an exploded view of a sole electric stimulation massager in accordance with another embodiment of the present invention;

FIG. 8 is a schematic view of a portion of the structure of FIG. 7;

FIG. 9 is an exploded view of a sole electric stimulation massager in accordance with another embodiment of the present invention;

FIG. 10 is a schematic view of a portion of the structure of FIG. 9;

FIG. 11 is a schematic structural view of a further embodiment of the electrical foot stimulation massager of the present invention;

fig. 12 is a circuit connection diagram of a part of the structure of the electric foot stimulation massager.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Foot sole electric stimulation massager	100	Backing plate
110	A first conductive tread area	120	Second conductive tread area
				130	Electrical connection point	140	Insulating silica gel bottom plate
111	First silver paste layer	121	Second silver paste layer
				112	First conductive silica gel layer	122	Second conductive silica gel layer
200	Main unit	210	Current output contact
				300	First magnet	310	Second magnet
320	Third magnet	330	Fourth magnet
				340	U-shaped magnet	400	A first compression spring
410	Second compression spring	500	First elastic sheet
				510	Second elastic sheet	600	The first air cavity
610	Second air cavity	620	Air outlet
				700	Conductive rotating vane	800	Insulating board
900	Convex hull	L	Conducting wire

The objects, features, and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides a plantar electrical stimulation massager which is used for foot massage, muscle electrical stimulation, channel dredging, rehabilitation treatment and the like.

Referring to fig. 2, the present invention provides a foot electro-stimulation massager 10, which includes a pad 100 and a main machine 200. The structure of the foot sole electric stimulation massager 10, the connection relationship and the position relationship thereof will be described first, and then the work flow of the foot sole electric stimulation massager 10 will be described in detail.

The structure of the foot electro-stimulation massager 10, and the connection relationship and the positional relationship thereof will be described below. For convenience of description, the "up-down" direction is introduced to assist in description, and please refer to fig. 11 for specific direction indication.

Specifically, referring to fig. 1, 2 and 11, the first conductive stepping area 110 and the second conductive stepping area 120 are spaced apart from each other on the upper surface of the pad 100, so that the two conductive stepping areas are not in contact with each other. Furthermore, an electrical connection point 130 is disposed on both of the conductive stepping regions, and it should be noted that the electrical connection point 130 may be a bump disposed on the pad 100, or may be directly formed by a certain region of the conductive stepping region. That is, the electrical connection point 130 is electrically connected to the conductive stepping area, and the electrical connection point 130 is used for connecting a host 200.

The first conductive tread area 110 and the second conductive tread area 120 may be formed in various ways, and the following two specific examples are illustrated, but do not represent that the present invention only protects the two described schemes, and if the schemes obtained by logical analysis, reasoning or limited experiments by those skilled in the art all belong to the protection scope of the present invention. The specific implementation mode is as follows:

referring to fig. 3, the upper surface of the pad 100 is coated with a first silver paste layer 111 and a second silver paste layer 121 which are arranged at intervals, the first silver paste layer 111 forms the first conductive stepping area 110, and the second silver paste layer 121 forms the second conductive stepping area 120, so that one of the electrical connection points 130 on the pad 100 is arranged on the first silver paste layer 111, and the other electrical connection point 130 is arranged on the second silver paste layer 121.

The silver paste layer in this embodiment may be in a planar coating, a plain weave arrangement, a basket weave arrangement, or other forms of texture arrangements, etc. Secondly, for considering that materials are simply drawn and processes are simplified, the height of the backing plate 100 is reasonably controlled, the use strength is guaranteed, the weight of the whole machine is reduced so as to facilitate carrying and other factors, the backing plate 100 comprises an EVA bottom plate and a PU plate arranged on the upper surface of the EVA bottom plate is preferred in the embodiment. It is therefore easily understood that the silver paste layer is provided on the upper surface of the PU plate.

Referring to fig. 2, the pad 100 includes an insulating silicone rubber base plate 140 and a conductive silicone rubber layer disposed on an upper surface of the insulating silicone rubber base plate 140; the conductive silica gel layer comprises a first conductive silica gel layer 112 and a second conductive silica gel layer 122 which are arranged at intervals, the first conductive silica gel layer 112 forms the first conductive treading area 110, and the second conductive silica gel layer 122 forms the second conductive treading area 120. Therefore, one of the electrical connection points 130 on the pad 100 is disposed on the first conductive silicone layer 112, and the other electrical connection point 130 is disposed on the second conductive silicone layer 122. The insulating silica gel pad 100 and the conductive silica gel layer are connected or bonded in a hot-pressing manner; in addition, the surface of the conductive silica gel layer can be smooth or provided with specific textures. Secondly, the backing plate 100 of this embodiment adopts the silica gel material, and then makes the flexibility of backing plate 100 stronger, is difficult for breaking, and highly controllable to and resistant dirty and easy scrubbing etc..

Next, for the host 200, the host 200 is installed on the pad 100, and the host 200 has two current output contacts 210, which are electrically connected to electrically connect the electrical connection points 130 on the conductive stepping area, so that the pulse current generated when the host 200 works can flow into the conductive stepping area through the electrical connection points 130. It is easy to understand that one of the current output contacts 210 of the host 200 is connected to the electrical connection point 130 of the first conductive stepping area 110, and the other current output contact 210 of the host 200 is connected to the electrical connection point 130 of the second conductive stepping area 120. The host 200 is internally provided with a circuit board, a storage battery electrically connected with the circuit board, other components and the like; the circuit board is provided with a pulse module, a control chip, a switch module and the like.

It should be noted that, after the host 200 is mounted on the pad 100 and started, the pulse current output by the host 200 cannot form a loop because the first conductive stepping area 110 and the second conductive stepping area 120 are separated.

In addition, the shape of the host 200 can be flexibly set according to the user's requirement, such as a cylinder, a square column, a triangular column, a table shape or more, and will not be described herein. The host 200 may be fixedly connected to the pad 100 or detachably connected to the pad, and the detachable connection is preferred for the convenience of use, detachment and replacement of the host 200. Specifically, the detachable mode can be an insertion mode or a clamping mode, and the like, and in the scheme of the invention, the clamping mode is preferably selected as follows: the electrical connection point 130 and the current output point are provided by snap fasteners, and the main unit 200 is detachably mounted on the pad 100 by the snap fasteners.

The operation of the foot electro-stimulation massager 10 will be described in detail below.

First, since the present application prefers that the main unit 200 and the pad 100 are detachably connected by snap fasteners, the main unit 200 is fastened to the pad 100, and then the main unit 200 is activated by controlling the switch buttons on the main unit 200. At this time, the host 200 is electrically connected to the first conductive stepping area 110 and the second conductive stepping area 120 at the same time.

Next, after the host 200 is turned on, the user treads the two feet on the first conductive treading area 110 and the second conductive treading area 120 respectively, so that the first conductive treading area 110 and the second conductive treading area 120 are electrically connected to form a loop. At this time, since the current outputted from the main body 200 is a pulse current, the user obtains an intermittent electric stimulation effect under the action of the pulse current, so as to achieve the effects of massage, physical therapy or muscle exercise.

Furthermore, the host 200 is provided with a size adjustment button for outputting current, so that when a user needs to increase the electric excitation intensity, the user only needs to adjust to increase the current output, and conversely, the user needs to adjust to decrease the current output.

Finally, when the user finishes using, the host 200 is directly closed.

According to the technical scheme of the invention, the sole electrical stimulation massager 10 is matched with the main machine 200 by adopting the base plate 100, so that the effects of massage, motor physical therapy, meridian dredging and muscle electrical stimulation can be realized. Moreover, the height of the pad 100 can be set freely, and the weight of the pad 100 is extremely light, so that the use, carrying and the like of the foot electro-stimulation massager 10 are greatly facilitated.

On the basis of the above embodiment, please refer to fig. 5 to 10, a battery is disposed in the main machine 200, and a power generating device is mounted on the pad 100, and is used for generating power to charge the battery in the main machine 200 when the pad 100 is stepped.

It is easy to understand that the foot massage device 10 mainly plays a role of physiotherapy, exercise, etc., and in this embodiment, a power generating device is added to generate power when the mat 100 is stepped on to charge the battery in the main body 200. Therefore, it can be understood that, after the operation of the foot electro-stimulation massager 10 is stopped, the user can perform stepping (or jumping) motion on the mat 100, and the generated mechanical energy is converted into electric energy by the power generation device to charge the battery, and the user can enhance the exercise effect during stepping or jumping.

Wherein, the power generation device mainly generates electricity by cutting the magnetic induction line. Specifically, the power generation device comprises a magnet, a magnetic induction linear cutting element and two leads L which are respectively connected with two ends of the magnetic induction linear cutting element; referring to fig. 12, the power generation device is electrically connected to a rectifier through two wires L, and the rectifier is electrically connected to a battery in the main machine 200 through a charging circuit. The magnetic induction wire cutting element is used for cutting the magnetic induction wire of the magnet to perform magnetic induction electricity when the backing plate 100 is stepped on, so as to charge the storage battery in the main machine 200. Among them, there are various ways of cutting the magnetic induction line to generate electricity, for example:

first, referring to fig. 5 and 6, a first accommodating cavity is disposed in the pad 100, and the first accommodating cavity is disposed corresponding to the first conductive pedal region. The bottom of the first accommodating cavity is provided with a first magnet 300, the upper surface of the first magnet 300 is provided with a first compression spring 400, the lower end of the first compression spring 400 is fixed with the first magnet 300 in an insulating way, the upper end of the first compression spring 400 is abutted against the top of the backing plate 100 in an insulating way, two ends of the first compression spring 400 are connected with leads L, the two leads L are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host 200 through a charging circuit.

Specifically explained, the magnetic induction line of the magnet goes from the N pole to the S pole, just as the first compression spring 400 is inside the magnetic induction line. When the user steps on the first conductive pedal, the first compression spring 400 performs a compression return motion to cut the magnetic induction line to generate a current. The current flows to the rectifier through the wires L at both ends of the first compression spring 400 to convert the ac power into the dc power, and then the charging circuit charges the secondary battery in the main unit 200, which can be used for the generation of the pulse current.

As will be explained next, in order to ensure that the magnetic generating current is not affected, both ends of the first compression spring 400 are disposed in insulated contact with the first magnet 300 and the top of the pad 100, respectively. Specific insulation methods are provided in various ways, for example: both ends of the first compression spring 400 are coated with an insulating paste (the two wires L are not connected to the insulating layer), and then the lower end of the first compression spring 400 is fixed to the first magnet 300 by means of bonding (or wire-bonding). Alternatively, the lower end of the first compression spring 400 is fixed by means of insulation bonding (or wire bonding), and the upper end of the first compression spring 400 abuts against the top of the pad 100 through an insulation plate 800. More alternatively, both ends of the first compression spring 400 are fixed to the first magnet 300 and abut against the top of the pad plate 100 through the insulating plate 800, respectively.

Furthermore, in order to ensure the generation amount of enough electric energy, a power generation device is also arranged at the corresponding position of the second conductive pedal area. Specifically, a second accommodating cavity is further arranged in the pad plate 100, and the second accommodating cavity is arranged corresponding to the second conductive pedal area; the bottom of the second accommodating cavity is provided with a second magnet 310, the upper surface of the second magnet 310 is provided with a second compression spring 410, the lower end of the second compression spring 410 is fixed with the second magnet 310 in an insulating manner, the upper end of the second compression spring 410 is abutted against the top of the backing plate 100 in an insulating manner, two ends of the second compression spring 410 are connected with leads L, the two leads L are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host 200 through a charging circuit. The structure and the installation manner of the power generation device in this embodiment may refer to the structure in the first accommodating cavity, which is not described herein again; it should be noted that the rectifier connected in this embodiment may be a rectifier connected to the power generation device in the first accommodation cavity, or may be another rectifier.

Secondly, referring to fig. 7 and 8, a first cavity is formed in the pad 100, and the first cavity is disposed corresponding to the first conductive pedal region; the bottom of the first cavity is provided with a third magnet 320, the upper surface of the third magnet 320 is provided with a first elastic sheet 500, the lower end of the first elastic sheet 500 is fixed with the third magnet 320 in an insulating way, the upper end of the first elastic sheet 500 is abutted against the top of the backing plate 100 in an insulating way, two ends of the first elastic sheet 500 are connected with leads L, the two leads L are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host 200 through a charging circuit.

It is easy to understand that the magnetic induction line of the magnet is from N pole to S pole, and the first elastic sheet 500 is just in the magnetic induction line. When the user steps on the first conductive pedal, the first elastic sheet 500 is sprung up and down, and the magnetic induction line is cut to generate current. The current flows to the rectifier through the wires L at both ends of the first resilient sheet 500 to convert the ac current into the dc current, and then the charging circuit charges the battery in the main unit 200, which can be used for generating the pulse current.

As will be further explained, in order to ensure that the magnetic current is not affected, both ends of the first resilient plate 500 are disposed in insulated contact with the third magnet 320 and the top of the pad 100, respectively. Specific insulation methods are provided in various ways, for example: two ends of the first elastic sheet 500 are coated with an insulating adhesive (two wires L are not connected to the insulating layer), and then the lower end of the first elastic sheet 500 is fixed on the third magnet 320 by means of bonding (or wire binding). Alternatively, the lower end of the first resilient plate 500 is fixed by insulation bonding (or wire bonding), and the upper end of the first resilient plate 500 abuts against the top of the pad 100 through an insulation plate 800. More alternatively, both ends of the first resilient sheet 500 are fixed to the third magnet 320 and abut against the top of the backing plate 100 through the insulating plate 800.

Furthermore, in order to ensure the generation amount of enough electric energy, a power generation device is also arranged at the corresponding position of the second conductive pedal area. Specifically, a second cavity is further arranged in the pad plate 100, and the second cavity is arranged corresponding to the second conductive pedal area; the bottom of the second cavity is provided with a fourth magnet 330, the upper surface of the fourth insulating plate 800 is provided with a second elastic sheet 510, the lower end of the second elastic sheet 510 is fixed to the fourth magnet 330 in an insulating manner, the upper end of the second elastic sheet 510 is abutted to the top of the backing plate 100 in an insulating manner, two ends of the second elastic sheet 510 are connected with leads L, the two leads L are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host 200 through a charging circuit. The structure and the installation manner of the power generation device in this embodiment may refer to the structure of the first cavity, which is not described herein again; it should be noted that the rectifier connected in this embodiment may be a rectifier connected to the power generation device in the first cavity, or may be another rectifier.

Thirdly, referring to fig. 9 and 10, a first air cavity 600 and a second air cavity 610 are disposed in the pad 100, the first air cavity 600 is disposed corresponding to the first conductive pedal region, the second air cavity 610 is disposed corresponding to the second conductive pedal region, and the first air cavity 600 and the second air cavity 610 are both provided with air outlets 620, and the two air outlets 620 are disposed opposite to each other. An installation cavity is arranged between the first air cavity 600 and the second air cavity 610, two magnets are oppositely arranged on the bottom surface and the top surface of the installation cavity, and the N pole and the S pole of each magnet are oppositely arranged. The accommodating cavity is further provided with a conductive rotating vane 700, one end of the conductive rotating vane 700 is rotatably fixed, the other end of the conductive rotating vane 700 penetrates through the two magnets and extends to the space between the first air cavity 600 and the air outlet 620 of the second air cavity 610, meanwhile, both ends of the conductive rotating vane 700 are connected with leads L, the two leads L are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host 200 through a charging circuit.

Specifically, the first air chamber 600 and the second air chamber 610 are both closed chambers, but each chamber has an air outlet 620, and the two air outlets 620 are disposed opposite to each other. Secondly, the installation cavity between the first air chamber 600 and the second air chamber 610 is also a closed cavity which is simultaneously communicated with the two air outlets 620, and thus, when the first air chamber 600 exhausts air from the air outlets 620, the air is directly exhausted into the second air chamber 610 through the installation cavity. That is, when any one of the first and second air chambers 600 and 610 is exhausted, an air flow path is formed between the outlet ports 620 of the two air chambers. Just, one end of the conductive rotating blade 700 is fixed in rotation, and the other end extends to between the two air outlets 620 (also located in the air flow path), so that when the air flows, the conductive rotating blade 700 is blown to swing. Meanwhile, since the conductive rotating blade 700 is inserted between the two magnets, when the conductive rotating blade 700 swings, the magnetic induction line is cut to generate a current, the generated current flows to the rectifier through the wires L at the two ends of the conductive blade to convert the alternating current into the direct current, and then the charging circuit charges the storage battery in the main machine 200, and the storage battery can be used for generating the pulse current.

It is easy to understand that the two feet of the user are respectively placed in the first conductive pedal area and the second conductive pedal area, and then when the user steps on the first conductive pedal area, the gas in the first gas chamber 600 runs towards the second gas chamber 610 to blow the conductive rotating vane 700 to rotate clockwise (or counterclockwise), and when the user steps on the second conductive pedal area, the gas in the second gas chamber 610 runs towards the first gas chamber 600 to blow the conductive rotating vane 700 to rotate counterclockwise (or clockwise), so that the rotation of the conductive rotating vane 700 is repeatedly realized, and the magnetic induction lines are cut and the magnetic induction generates electricity.

It should be noted that, in order to facilitate the installation of the magnets, it is preferable that the two magnets are opposite poles on the same U-shaped magnet 340 in this embodiment, but it is also possible to use two different magnets.

In another embodiment, referring to fig. 2 and 11, the pad 100 includes an insulating silicone rubber base plate 140 and a conductive silicone rubber layer disposed on an upper surface of the insulating silicone rubber base plate 140; the conductive silica gel layer comprises a first conductive silica gel layer 112 and a second conductive silica gel layer 122 which are arranged at intervals, the first conductive silica gel layer 112 forms the first conductive treading area 110, and the second conductive silica gel layer 122 forms the second conductive treading area 120; moreover, a plurality of convex hulls 900 are convexly arranged on the surface of the conductive silica gel layer. It can be understood that when a plurality of convex hulls 900 are arranged, the convex hulls 900 massage the acupuncture points of the feet of the user when the feet of the user step on the conductive silica gel layer for electric stimulation, so as to achieve better health care effect.

In another embodiment, a storage battery is disposed in the host 200, and a heat-generating carbon film (not shown) is disposed in the pad 100 or at the bottom of the pad 100, and the heat-generating carbon film is electrically connected to the storage battery.

It should be explained that the storage battery in this embodiment may be a storage battery that provides pulse current generation, or may be a storage battery that is separately provided to electrically connect the heat-generating carbon film, and the former is preferable. The on/off of the heat-generating carbon film and the battery may be controlled directly by a switch for controlling the pulse current, or may be controlled by a separate switch. Specifically, the same switch is used for controlling the pulse current and the operation of the heat-generating carbon film.

Therefore, it is easy to understand that, in the specific operation, after the user turns on the switch on the host 200, the pulse current flows to the two conductive stepping areas, and the heating carbon film performs the heating operation. In this embodiment, the heating carbon film is provided to heat the feet of the user, thereby promoting blood circulation and achieving better electric stimulation. Secondly, when the user uses the foot electric stimulation massager 10 in a lower temperature environment, the user can not feel cold due to the foot exposure.

In another embodiment, referring to fig. 4, in order to prevent the motion of the electro-stimulation massager for foot sole 10 during the use process, the bottom of the pad 100 is provided with anti-slip patterns to avoid the above problems. The anti-skid lines are arranged in various ways, such as a lattice shape, a transverse line shape, a broken line shape, a curved shape or an irregular shape; preferably, in this implementation, the anti-slip patterns are arranged in a wavy pattern. The anti-slip pattern may be formed on the bottom of the mat 100, may be formed by protruding the bottom of the mat 100, or may be formed by recessing the bottom of the mat 100.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (4)

1. A plantar electrical stimulation massager is characterized by comprising:

the upper surface of the base plate is provided with a first conductive treading area and a second conductive treading area at intervals, and the two conductive treading areas are provided with an electric connection point;

the host is used for outputting pulse current, is arranged on the base plate and is provided with two current output contacts, and the host is respectively and correspondingly electrically connected with the two electric connection points on the conductive area through the connection of the two current output contacts;

a storage battery is arranged in the main machine;

the base plate is provided with a power generation device, and the power generation device is used for generating power to charge a storage battery in the main machine when the base plate is trampled;

a first air cavity and a second air cavity are arranged in the backing plate, the first air cavity is arranged corresponding to the first conductive pedal area, the second air cavity is arranged corresponding to the second conductive pedal area, air outlets are arranged in the first air cavity and the second air cavity, and the two air outlets are arranged oppositely;

an installation cavity is arranged between the first air cavity and the second air cavity, two magnets are oppositely arranged on the bottom surface and the top surface of the installation cavity, and the N poles and the S poles of the two magnets are oppositely arranged;

the accommodating cavity is also internally provided with a conductive rotating blade, one end of the conductive rotating blade is fixed in a rotating way, the other end of the conductive rotating blade penetrates through the two magnets and extends to the space between the air outlets of the first air cavity and the second air cavity, meanwhile, both ends of the conductive rotating blade are connected with leads, the two leads are connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit.

2. The plantar electrical stimulation massager of claim 1, wherein the pad comprises an EVA base plate and a PU plate disposed on an upper surface of the EVA base plate;

the upper surface coating of PU board is equipped with silver thick liquid layer, first silver thick liquid layer and second silver thick liquid layer that silver thick liquid layer set up including the interval, first silver thick liquid layer is formed first electrically conductive trample the district, second silver thick liquid layer is formed the electrically conductive trample the district of second.

3. The plantar electrical stimulation massager of claim 1, wherein the pad comprises an insulating silicone base plate and a conductive silicone layer disposed on an upper surface of the insulating silicone base plate;

the conductive silica gel layer comprises a first conductive silica gel layer and a second conductive silica gel layer which are arranged at intervals, the first conductive silica gel layer forms the first conductive trampling area, and the second conductive silica gel layer forms the second conductive trampling area.

4. The electrical foot sole stimulation massager of claim 1, wherein the power generating means comprises a magnet, a magnetic wire cutting element, and two wires connected to both ends of the magnetic wire cutting element, respectively; the two lead wires are electrically connected with a rectifier, and the rectifier is electrically connected with a storage battery in the host machine through a charging circuit;

the magnetic induction line cutting element is used for cutting the magnetic induction lines of the magnet to carry out magnetic induction electricity when the base plate is trampled, and further charges a storage battery in the host machine.

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