CN215461429U - Massage device - Google Patents

Abstract

The application relates to a massage apparatus. This massage appearance includes: the massager comprises a massager body, an electrode assembly, a controller, a liquid storage device and a liquid guide assembly; the liquid storage device is arranged on one side, back to the skin of a human body, of the massage apparatus body and is used for storing conductive liquid; the electrode assembly is arranged on one side of the massage instrument body facing the skin of the human body and used for outputting an electric pulse signal; the liquid guide component is arranged in the massage instrument body and is respectively connected with the liquid storage device and the electrode component; the controller is arranged in the massage instrument body and used for determining the humidity of the joint part of the micropore electrode and the human body; and when the humidity is smaller than a first preset threshold value, controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly, and seeping the conductive liquid through micropores of the micropore electrode in the electrode assembly. The application provides a massager can improve the humidity of skin, increases the area of contact between user's skin and the electrode subassembly, reduces the impedance value of electrode subassembly, promotes user's use and experiences.

Description

Massage device

Technical Field

The application relates to the technical field of massage equipment, in particular to a massage instrument.

Background

With the continuous development of electronic technology, different types of massage instruments with different functions gradually flow into the daily life and work of people. Common massagers include neck massagers, eye massagers, waist massagers and the like. The massage instruments can output electric pulse signals to act on human muscles through the configured electrode assemblies so as to achieve the effects of massaging the muscles and relieving fatigue.

In the related art massage apparatus, the electrode assembly generally includes at least two electrodes, and the two electrodes are respectively used as an anode and a cathode and attached to the skin of the human body during one-time electric pulse output.

However, the correlation between the massage effect of the massage apparatus in the related art and the impedance between the electrodes is very large, and when the skin of the user is in poor fit with the electrodes or the skin of the user is dry, the impedance between the two electrodes is relatively large, so that the current flowing through the skin and the muscle of the human body is very small, the user cannot feel the current, the massage effect is reduced, and the use experience of the user is influenced.

SUMMERY OF THE UTILITY MODEL

In order to solve or partially solve the problem that exists among the correlation technique, the application provides a massage appearance, can improve the humidity of skin, increases the area of contact between user's skin and the electrode subassembly, reduces the impedance value of electrode subassembly, promotes user and uses experience.

The present application provides in a first aspect a massage apparatus comprising: the massager comprises a massager body, an electrode assembly, a controller, a liquid storage device and a liquid guide assembly; wherein the content of the first and second substances,

the liquid storage device is arranged on one side, back to the skin of a human body, of the massage instrument body and comprises a liquid storage cavity for storing conductive liquid;

the electrode assembly is arranged on one side of the massage instrument body facing the skin of the human body and used for outputting electric pulse signals; the electrode assembly comprises at least one group of microporous electrodes, one group of microporous electrodes comprises two microporous electrodes, and at least one micropore is formed in one microporous electrode;

the liquid guide assembly is arranged in the massage instrument body and is respectively connected with the liquid storage device and the electrode assembly;

the controller is arranged in the massager body, is respectively connected with the electrode assembly and the liquid guide assembly and is used for determining the humidity of the joint part of the microporous electrode and the human body; and when the humidity is smaller than a first preset threshold value, controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly, and seeping the conductive liquid through micropores of microporous electrodes in the electrode assembly.

Preferably, the massager further comprises a humidity sensor arranged on the microporous electrode; the humidity sensor is connected with the controller and used for detecting the humidity of the fit part of the microporous electrode and the human body.

Preferably, the liquid storage device is detachably connected with the massage apparatus body.

Preferably, the liquid storage device is detachably connected with the massage instrument body in a magnetic suction mode or a clamping mode.

Preferably, the pore size of the micropores on the microporous electrode is 5 μm to 50 μm.

Preferably, the interval size between two adjacent micropores on the micropore electrode is 200 μm to 500 μm.

Preferably, the massager further comprises a wearing detection assembly arranged on the massager body;

the wearing detection assembly is connected with the controller and used for detecting the wearing state of the massager.

Preferably, the wearing detection assembly comprises at least one capacitive sensor, and the capacitive sensors are arranged on one side of the massager body facing the skin of the human body and are respectively connected with the controller.

Preferably, the wearing detection assembly comprises at least one pressure sensor, and the pressure sensors are arranged on one side of the massager body facing the skin of the human body and are respectively connected with the controller.

Preferably, the wearing detection assembly comprises at least one distance sensor, which is arranged on one side of the massage apparatus body facing the skin of the human body and is respectively connected with the controller.

Preferably, the wearing detection assembly comprises a current sensor, and the current sensor is connected with the controller and is used for detecting the magnitude of the current output by the microporous electrode.

Preferably, the wearing detection assembly comprises a voltage sensor, and the voltage sensor is connected with the controller and is used for detecting the divided voltage on a voltage dividing resistor in an output loop of the microporous electrode.

Preferably, the drainage assembly comprises a first catheter, a liquid pumping-out device and a second catheter; wherein the content of the first and second substances,

one end of the first liquid guide pipe is connected with the liquid storage device, and the other end of the first liquid guide pipe is connected with a liquid inlet of the liquid pumping-out device;

one end of the second liquid guide pipe is connected with a liquid outlet of the liquid pumping-out device, and the other end of the second liquid guide pipe is connected with the electrode assembly;

the liquid pumping-out device is also connected with the controller and is controlled by the controller to pump out the conductive liquid stored in the liquid storage device to the electrode assembly when the humidity is less than a first preset threshold value.

Preferably, the bottom of the liquid storage cavity is provided with at least one through hole, and the first liquid guide pipe is communicated with the liquid storage device through the through hole.

Preferably, the drainage assembly comprises a third drainage tube, an on-off valve and a fourth drainage tube; wherein the content of the first and second substances,

one end of the third liquid guide pipe is connected with the liquid storage device, and the other end of the third liquid guide pipe is connected with the liquid inlet end of the switch valve;

one end of the fourth liquid guide pipe is connected with the liquid outlet end of the switch valve, and the other end of the fourth liquid guide pipe is connected with the electrode assembly;

the switch valve is also connected with the controller and is controlled by the controller.

Preferably, the massage apparatus further comprises a temperature adjusting device connected to the controller for adjusting the temperature of the conductive liquid.

Preferably, the temperature regulating device is arranged in the liquid storage cavity, or the temperature regulating device is arranged at an interface between the liquid storage device and the electrode assembly.

Preferably, the massager further comprises a first temperature sensor arranged on the massager body;

the first temperature sensor is connected with the controller and used for collecting the ambient temperature of the environment where the massager is located.

Preferably, the massager further comprises a second temperature sensor arranged in the liquid storage cavity;

the second temperature sensor is connected with the controller and used for collecting the liquid temperature of the conductive liquid stored in the liquid storage cavity.

Preferably, the massager further comprises a timer arranged in the massager body;

the timer is connected with the controller and used for timing.

Preferably, the controller determines the liquid permeation amount of the conductive liquid according to the humidity, wherein the humidity is in a negative correlation with the liquid permeation amount of the conductive liquid; and controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly according to the determined seepage amount.

Preferably, the electrode assembly includes at least two sets of microporous electrodes, and the controller controls the liquid guiding assembly to guide the conductive liquid stored in the liquid storage device to a set microporous electrode of the at least two sets of microporous electrodes, and to seep out the conductive liquid through micropores of the set microporous electrode, where the set microporous electrode is a microporous electrode in a working mode.

The technical scheme provided by the application can comprise the following beneficial effects:

the massage instrument at least comprises a massage instrument body, an electrode assembly, a controller, a liquid storage device and a liquid guide assembly, wherein the electrode assembly is arranged on one side, facing the skin of a human body, of the massage instrument body; the electrode assembly can comprise at least one group of micropore electrodes, at least one micropore is formed in each micropore electrode, and an electric pulse signal for massage can be output through the electrode assembly; the liquid storage device is used for storing conductive liquid; the liquid guiding component is arranged between the liquid storage device and the electrode component and is used for conducting the liquid storage device and the electrode component; the controller can determine the humidity of the joint part of the microporous electrode and the human body; and when the humidity is smaller than a first preset threshold value, controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly so as to seep out the conductive liquid through micropores on microporous electrodes in the electrode assembly. Through above-mentioned structure, when humidity is less than first predetermined threshold, through leading into electrode subassembly with conducting liquid, ooze out to user's skin on the micropore electrode to can improve the humidity of skin, increase the area of contact between user's skin and the electrode subassembly, reduce electrode subassembly's impedance value, make the electric current increase of user's skin of flowing through, promote user's use and experience.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The foregoing and other objects, features and advantages of the application will be apparent from the following more particular descriptions of exemplary embodiments of the application, as illustrated in the accompanying drawings wherein like reference numbers generally represent like parts throughout the exemplary embodiments of the application.

Fig. 1a is a perspective structural view of a massage apparatus shown in an embodiment of the present application;

FIG. 1b is a bottom view of the massage apparatus shown in the embodiments of the present application;

FIG. 1c is a top view of the massage apparatus shown in the embodiments of the present application;

fig. 2 is a schematic flow chart illustrating a control method of a massage apparatus according to an embodiment of the present disclosure;

fig. 3 is a schematic flow chart illustrating another control method of the massage apparatus according to the embodiment of the present application;

fig. 4 is a schematic flow chart illustrating another control method for a massage apparatus according to an embodiment of the present disclosure;

fig. 5 is a schematic flow chart illustrating another control method for a massage apparatus according to an embodiment of the present disclosure;

fig. 6 is a schematic flow chart illustrating another control method of the massage apparatus according to the embodiment of the present application;

fig. 7 is a schematic structural diagram of a control device of a massage apparatus according to an embodiment of the present application;

fig. 8 is a block diagram of a massage apparatus according to an embodiment of the present disclosure;

fig. 9 is a block diagram of another massage apparatus according to an embodiment of the present application;

reference numerals: 100. a massage device; 10. an electrode assembly; 20. a liquid storage device; 30. a massage apparatus body; 110. a microporous electrode; 120. and (4) micro-pores.

Detailed Description

Embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While embodiments of the present application are illustrated in the accompanying drawings, it should be understood that the present application may 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 disclosure to those skilled in the art.

It should be understood that although the terms "first," "second," "third," etc. may be used herein to describe various information, these information should not be limited to these terms. These terms are only used to distinguish one type of information from another. For example, first information may also be referred to as second information, and similarly, second information may also be referred to as first information, without departing from the scope of the present application. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In the description of the present application, it is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be considered limiting of the present application.

Unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are intended to be inclusive and mean that, for example, they may be fixedly connected or detachably connected or integrally formed; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

At present, the massage apparatus in the related art is generally provided with an electrode assembly consisting of at least two electrodes to output electric pulse signals to massage the user. When the fit degree of the skin of the user and the electrode assembly is poor or the skin of the user is dry, the contact area between the skin of the user and the electrode assembly is small, the impedance between the electrodes is large, and the current flowing through the skin of the human body is small, so that the massage feeling of the user is small, and the use experience of the user is influenced. To above-mentioned problem, the embodiment of the application provides a massage appearance, can increase the area of contact between user's skin and the electrode subassembly through the sepage, reduces the impedance value of electrode subassembly, promotes user and uses experience. The technical solutions of the embodiments of the present application are described in detail below with reference to the accompanying drawings.

In the embodiment of the present application, the massage apparatus may be a wearable massage apparatus, and may include, but is not limited to, a neck massage apparatus, an eye massage apparatus, a waist massage apparatus, and the like. The embodiment of the present application is explained taking a neck massage apparatus as an example.

Referring to fig. 1a-1c, the present application provides a massage apparatus. As shown in fig. 1a-1c, the massage apparatus 100 may include at least: the massager body 30, the electrode assembly 10, a controller (not shown in the figure), the liquid storage device 20 and the liquid guide assembly (not shown in the figure); wherein the content of the first and second substances,

the electrode assembly 10 can be disposed on a side of the massage apparatus body 30 facing the skin of the human body for outputting an electrical pulse signal; the electrode assembly 10 may include at least one set of microporous electrodes, wherein the one set of microporous electrodes may include two microporous electrodes 110, and at least one micropore 120 may be formed on one microporous electrode 110;

the liquid storage device 20 can be arranged on one side of the massage apparatus body 30, which faces away from the skin of the human body, and the liquid storage device 20 can comprise a liquid storage cavity for storing conductive liquid;

the liquid guiding component can be arranged in the massage instrument body 30 and is respectively connected with the liquid storage device 20 and the electrode component 10;

the controller can be arranged in the massage apparatus body 30, is respectively connected with the electrode assembly 10 and the liquid guide assembly, and is used for determining the humidity of the joint part of the microporous electrode and the human body; when the humidity is less than the first predetermined threshold, the liquid guiding assembly is controlled to guide the conductive liquid stored in the liquid storage cavity into the electrode assembly 10, and the conductive liquid is seeped out through the micropores 120 on the micropore electrode in the electrode assembly 10.

The controller can determine the seepage amount of the conductive liquid according to humidity, wherein the humidity and the seepage amount of the conductive liquid are in a negative correlation relationship; the liquid guiding assembly is controlled to guide the conductive liquid stored in the liquid storage device 20 into the electrode assembly 10 according to the determined seepage amount.

The electrode assembly 10 may include at least two sets of microporous electrodes, and the controller may control the fluid conducting assembly to conduct the conductive fluid stored in the reservoir 20 to a set microporous electrode of the at least two sets of microporous electrodes, and to seep out the conductive fluid through the micropores of the set microporous electrode, where the set microporous electrode may be a microporous electrode in the working mode.

In the embodiment of the present application, when the massage apparatus 100 is worn correctly by the user, the electrode assembly 10 is located on the massage apparatus body 30 and faces towards the skin of the human body, and the liquid storage device 20 is located on the massage apparatus body 30 and faces away from the skin of the human body.

The electrode assembly 10 outputs current pulse signals to electrically stimulate the skin, joints and other parts of the user, thereby achieving a massage effect. The controller may control the operating state of electrode assembly 10, such as shutting off electrode assembly 10 or starting electrode assembly 10.

Wherein, the massage apparatus body 30 can be provided with a placement groove adapted to the size of the liquid storage device 20 for placing the liquid storage device 20. The conductive liquid stored in the liquid storage cavity can be water, aqueous solution or massage liquid with medicine auxiliary function and other conductive liquids. A top cover can be arranged on the liquid storage cavity, so that the sealing and the injection of the conductive liquid are facilitated.

The liquid guiding assembly is disposed between the liquid storage device 20 and the electrode assembly 10, and can be used to conduct the liquid storage device 20 and the electrode assembly 10, so as to guide the conductive liquid in the liquid storage device 20 into the electrode assembly 10. A through hole may be provided in the bottom or the side wall of the reservoir chamber to communicate the reservoir 20 with the drainage assembly. The controller may control an operating state of the fluid-directing assembly, such as turning the fluid-directing assembly off or turning the fluid-directing assembly on.

The application provides a massage appearance, when the humidity of micropore electrode and human body laminating position is less than first predetermined threshold often, lead the leading-in electrode subassembly 10 of conducting liquid in liquid storage device 20 through control drain subassembly, ooze to user's skin on micropore 120 on the micropore electrode 110 to can increase the area of contact between user's skin and the electrode subassembly, reduce electrode subassembly's impedance value, make the electric current increase of user's skin of flowing through, promote user's use and experience.

Optionally, the massager may further include a humidity sensor (not shown in the figure) disposed on the microporous electrode; the humidity sensor is connected with the controller and is used for detecting the humidity of the joint part of the microporous electrode 110 and the human body.

The distribution of micropores 120 on the microporous electrode 110 may be as shown in fig. 1 b. Wherein, the pore size of one micro-pore 120 may be, but not limited to, 5 μm (micrometer) to 50 μm, and the distance between two adjacent micro-pores 120 on one micro-pore electrode 110 may be, but not limited to, 200 μm to 500 μm.

Optionally, the massage apparatus 100 may further include a wearing detection component (not shown in the figures), which may be disposed on the massage apparatus body 30; the wearing detection component is connected with the controller and can be used for detecting the wearing state of the massager 100.

Wherein, the wearing detection component can detect the wearing parameters of the massage apparatus 100, and the wearing parameters can include but are not limited to at least one of the capacitance value, the pressure value, the distance value, the current value, the voltage value, and the like of the wearing detection component.

The wearing detection component may determine the wearing state of the massager 100 according to the detected wearing parameters and feed back the determined wearing state to the controller. Alternatively, the wear detection component may transmit the detected wear parameters to the controller, which determines the wear status of the massager 100.

Wherein, wear the detection subassembly and can include at least one capacitive sensor, set up in the one side of massager body 30 towards human skin, be connected with the controller respectively.

For example, when the capacitance value of the capacitance sensor is detected to be greater than the preset capacitance value, the massager 100 is in a worn state; otherwise, the massager 100 is not worn.

Wherein, wear the detection subassembly and can include at least one pressure sensor, set up in the one side of massager body 30 towards human skin, be connected with the controller respectively.

For example, when it is detected that the pressure value measured by the pressure sensor is greater than the preset pressure value, the massage apparatus 100 is in the worn state; otherwise, the massager 100 is not worn.

Wherein, wear the detection subassembly and can include at least one distance sensor, set up in the one side of massager body 30 towards human skin, be connected with the controller respectively.

For example, when it is detected that the distance value measured by the distance sensor is smaller than the preset distance value, the massage apparatus 100 is in a worn state; otherwise, the massager 100 is not worn.

Wherein, wear the detection subassembly and can include current sensor, and current sensor is connected with the controller, can be used for detecting the electric current size of micropore electrode 110 output.

For example, when the current value output by the microporous electrode 110 is detected to be greater than the preset current value, the massage apparatus 100 is in a worn state; otherwise, the massager 100 is not worn.

Wherein, wear the detection assembly and can include voltage sensor, and voltage sensor is connected with the controller, can be used to detect the partial pressure voltage on the divider resistance in the output circuit of micropore electrode 110.

For example, when the divided voltage on the voltage dividing resistor is detected to be greater than the preset voltage value, the massager 100 is in a worn state; otherwise, the massager 100 is not worn.

It will be appreciated that the wear detection assembly may include two or more of the sensors described above. The accuracy of wearing detection can be improved by combining various sensors.

Alternatively, the drainage assembly may include a first catheter, a fluid pump-out device, and a second catheter; wherein, one end of the first liquid guide pipe is connected with the liquid storage device 20, and the other end of the first liquid guide pipe is connected with the liquid inlet of the liquid pumping-out device; one end of the second liquid guide pipe is connected with a liquid outlet of the liquid pumping-out device, and the other end of the second liquid guide pipe is connected with the electrode assembly 10; the liquid pumping device is also connected with and controlled by the controller.

Wherein, the bottom of the liquid storage cavity can be provided with at least one through hole, and the first liquid guide pipe is communicated with the liquid storage device 20 through the through hole.

It will be understood that a through hole may be formed in the sidewall of the reservoir chamber to communicate the first liquid guiding tube with the reservoir device 20.

Wherein, the liquid pumping-out device can be a liquid pump or an air pump. The fluid pump-out device may be connected at one end to the reservoir 20 via a first catheter and at the other end to the electrode assembly 10 via a second catheter. The controller may control the operating state (e.g., on or off) of the fluid pumping device. In use, the fluid pumping device operates to deliver the conductive fluid from the reservoir 20 to the electrode assembly 10 to form micro-droplets through the micro-pores 120 of the micro-porous electrode 110.

Wherein the number of the second catheters can be matched with the number of the microporous electrodes 110. For example, when electrode assembly 10 includes two microporous electrodes 110, two second conduits may be provided, each communicating with two microporous electrodes 110; when the electrode assembly 10 includes four microporous electrodes 110, four second conduits may be provided, each communicating with four microporous electrodes 110.

Wherein, each second catheter can be controlled independently, and only the conductive liquid can be led into the microporous electrode in the working state, and the microporous electrode which does not work does not seep liquid.

Optionally, the drainage assembly may include a third catheter, an on-off valve, and a fourth catheter; one end of the third liquid guide pipe is connected with the liquid storage device 20, and the other end of the third liquid guide pipe is connected with the liquid inlet end of the switch valve; one end of the fourth liquid guide pipe is connected with the liquid outlet end of the switch valve, and the other end of the fourth liquid guide pipe is connected with the electrode assembly 10; the switch valve is also connected with the controller and is controlled by the controller.

Wherein, one end of the switch valve can be connected with the liquid storage device 20 through a third liquid guide pipe, and the other end can be connected with the electrode assembly 10 through a fourth liquid guide pipe. The controller may control the operating state (e.g., open or closed) of the on-off valve, when the on-off valve is open, the conductive liquid in the reservoir 20 may flow into the electrode assembly 10; when the on-off valve is closed, the conductive liquid in the reservoir 20 cannot flow into the electrode assembly 10.

Wherein the number of the fourth catheters can be matched with the number of the microporous electrodes 110. Each fourth catheter can be controlled independently, and only the conductive liquid can be introduced into the microporous electrode in the working state, and the microporous electrode in the non-working state is not subjected to liquid seepage.

Optionally, the massage device 100 may further include a temperature adjusting device (not shown) connected to the controller for adjusting the temperature of the conductive liquid.

The temperature adjusting device can be arranged in the liquid storage cavity and can adjust the temperature of all conductive liquid in the liquid storage cavity;

alternatively, a temperature regulating device may be provided at the interface of the reservoir 20 and the electrode assembly 10. For example at the catheter (e.g. wound around the catheter in the form of a coil). At this time, the temperature adjusting means may perform temperature adjustment only on the portion of the conductive liquid to be introduced into the electrode assembly 10.

Wherein, the massage apparatus 100 may further include a first temperature sensor, which may be disposed on the massage apparatus body 30; the first temperature sensor is connected to the controller and can be used to collect the ambient temperature of the environment in which the massager 100 is located.

For example, when the ambient temperature measured by the first temperature sensor is lower than a first preset ambient temperature, the controller may control the temperature adjustment device to heat the conductive liquid, so that the heated conductive liquid seeps through the micro-holes 120.

For example, when the ambient temperature measured by the first temperature sensor is higher than the second preset ambient temperature, the controller may control the temperature adjustment device to refrigerate the conductive liquid, so that the refrigerated conductive liquid seeps through the micro holes 120.

The massager can also comprise a second temperature sensor which can be arranged in the liquid storage cavity; the second temperature sensor is connected with the controller and used for collecting the liquid temperature of the conductive liquid stored in the liquid storage cavity.

For example, the controller may control the temperature adjustment device to heat the conductive liquid when the liquid temperature measured by the second temperature sensor is lower than a first preset liquid temperature.

For example, when the liquid temperature measured by the second temperature sensor is higher than the second preset liquid temperature, the controller may control the temperature adjustment device to refrigerate the conductive liquid.

It will be appreciated that the first temperature sensor and the second temperature sensor may be present simultaneously, jointly regulating the temperature of the conductive liquid by combining the ambient temperature and the liquid temperature.

Optionally, the massage apparatus 100 may further include a timer (not shown in the drawings) disposed in the massage apparatus body 30; the timer is connected with the controller and can be used for timing.

The working time of the liquid guiding assembly can be timed by utilizing the timer, and the guiding amount of the conductive liquid can be controlled by controlling the working time of the liquid guiding assembly (such as the pumping-out time of a liquid pumping-out device or the opening time of a switch valve), so that excessive liquid can be prevented from seeping at one time.

Optionally, the liquid storage device 20 and the massage apparatus body 30 may be detachably connected.

Wherein, the liquid storage device 20 can be detachably connected with the massage apparatus body 30 in a magnetic attraction manner or a clamping manner.

In addition, the liquid storage device 20 and the massage apparatus body 30 may be detachably connected by other methods, such as a threaded connection, which is not limited herein.

In practical applications, the massage apparatus 100 may include other functional components, such as a laser irradiation component, a function key (e.g., a duration adjustment key, a power key, a mode selection key, etc.), and the like, besides the above components, which is not limited herein.

The application provides a massage appearance, when the humidity of micropore electrode and human body laminating position is less than first predetermined threshold, lead into electrode subassembly 10 with the conducting liquid in the stock solution device 20 through control drain subassembly, ooze to user's skin on micropore 120 on the micropore electrode 110 to can increase the area of contact between user's skin and the electrode subassembly, reduce electrode subassembly's impedance value, make the electric current increase of user's skin of flowing through, promote user's use and experience.

In addition, through setting up temperature regulation apparatus, can carry out temperature regulation to conducting liquid, make liquid temperature more be suitable for the user, further promote user and use experience. Through setting up the timer, can control the operating duration of drain subassembly to the amount of exporting of control conducting liquid can avoid once oozing too much liquid.

It should be understood that fig. 1a-1c show only one of the configurations of the neck massager, and the massager in the embodiment of the present application is not limited to the configurations shown in fig. 1a-1c, but may also be other configurations, and the embodiment of the present application is not limited thereto.

Referring to fig. 2, fig. 2 is a schematic flow chart illustrating a control method of a massage apparatus according to an embodiment of the present application. The method may be applied to the massage machine 100 described above. As shown in fig. 2, the method may include:

and step S210, determining the humidity of the joint part of the microporous electrode and the human body.

In the embodiment of the application, after the massager is started, the humidity of the joint part of the micropore electrode and the human body can be detected. It should be noted that the humidity of the portion where the microporous electrode is attached to the human body may also be detected periodically, that is, the humidity of the portion where the microporous electrode is attached to the human body may be detected once every preset time period, where the preset time period may be 5 minutes, 10 minutes, 20 minutes, 30 minutes, or other values. The preset duration can be adaptively adjusted according to user requirements and/or actual application scenarios.

Wherein, can detect the humidity of micropore electrode and human laminating position through humidity transducer. The humidity sensor may be disposed at the microporous electrode. The humidity may comprise air humidity and/or human skin humidity. The humidity sensor in the present application may be a single-function humidity sensor, or may be a temperature and humidity sensor having humidity and temperature detection functions.

Wherein, the electrode assembly can include at least one group of micropore electrodes, and one group of micropore electrodes includes two micropore electrodes, and one micropore electrode can be provided with one or more micropores. For example, the pore size of one micro-pore may be, but is not limited to, 5 μm (micrometer) to 50 μm, and the distance between two adjacent micro-pores on one micro-pore electrode may be, but is not limited to, 200 μm to 500 μm.

And step S220, when the humidity is smaller than a first preset threshold value, conducting liquid stored in the liquid storage device is led into the electrode assembly, and the conducting liquid seeps out through micropores of the micropore electrode in the electrode assembly.

When the humidity is less than the first predetermined threshold, it may indicate that the impedance between the electrode assembly and the skin of the user is large, which may cause the current flowing through the skin of the user to be small, resulting in poor massage feeling for the user. At this time, the conductive liquid stored in the liquid storage device can be guided into the electrode assembly, the conductive liquid can be seeped out to the skin of a user through the micropores on the micropore electrodes in the electrode assembly, after the liquid soaks the skin, the humidity of the skin is improved, the contact area between the skin and the electrode assembly can be increased, the dielectric constant between the skin and the electrode assembly is changed, the impedance value of the electrode assembly is reduced, and the massage effect is improved. The conductive liquid may include water, an aqueous solution, or a massage liquid having a drug-assisted function.

In the embodiment of the present application, the first predetermined threshold regarding humidity may be set empirically, and the value may be set with reference to the dielectric constant of the air interface layer between the microporous electrode and the human body attachment portion. For example, the first predetermined threshold may be a humidity at which the above-mentioned dielectric constant is minimized, and the humidity exceeds the first predetermined threshold, and the need for the amount of liquid permeating is small. For example, the first predetermined threshold may be a value between 0.8 and 0.9. It will be readily appreciated that, within a certain range, the greater the humidity, the better the air conductivity and the greater its dielectric constant. When the humidity is lower than the first predetermined threshold, the dryness is considered to be high, and the conductive liquid is required to be used for wetting.

When the electrode assembly comprises a plurality of groups of microporous electrodes, the liquid can be seeped only for the microporous electrodes in the working mode, and the liquid can not be seeped for the microporous electrodes in the non-working mode. Alternatively, all of the microporous electrodes may be infiltrated.

Wherein, before the seepage liquid, can suitably adjust the temperature of conducting liquid to the conducting liquid seepage after with temperature regulation to can avoid the temperature too low or too high to cause the discomfort for the user.

In addition, after the liquid seepage, the humidity of the part, attached to the human body, of the microporous electrode can be continuously detected to determine whether the humidity is reduced, and if the detected humidity is smaller than the first preset threshold value again, the liquid seepage can be performed again. The amount of liquid per bleed may be fixed, e.g., 0.1 ml/time, 0.2 ml/time, 0.5 ml/time, or other values. Because the working frequency of the massager is high, the whole process can be finished within 2 seconds, and excessive waiting time can not be caused to users.

In addition, the seepage amount of the conductive liquid can also be determined according to the detected humidity, wherein the humidity and the seepage amount of the conductive liquid are in a negative correlation relationship. In other words, the smaller the humidity, the more the determined exudate amount, whereas the larger the humidity, the less the determined exudate amount. It is easy to understand that the smaller the humidity, the higher the dryness and the higher the dielectric constant of the air interface layer between the microporous electrode and the human body, therefore, more seepage is needed to seep to the joint part of the microporous electrode and the human body to reduce the dryness and the dielectric constant.

Wherein, the negative correlation between the humidity and the seepage quantity can be represented by an inverse proportion function or a corresponding relation table. For example, if the correspondence is expressed by an inverse proportional function, the corresponding amount of fluid seepage can be calculated by substituting the corresponding humidity value into the inverse proportional function after the humidity is detected. Correspondingly, if the corresponding relation is presented by the corresponding relation table, after the humidity is detected, the corresponding relation table is inquired according to the corresponding humidity value, and the corresponding seepage amount can be determined according to the table look-up result.

Wherein, before carrying out the sepage operation, can detect earlier whether the massage appearance is in by the state of wearing, only carry out the sepage when being worn, otherwise do not carry out the sepage.

According to the method provided by the embodiment of the application, the humidity of the joint part of the microporous electrode and the human body can be determined, and when the humidity is smaller than a first preset threshold value, the conductive liquid stored in the liquid storage device is introduced into the electrode assembly, so that the conductive liquid can seep out through micropores of the microporous electrode in the electrode assembly. Through the processing, when the humidity is smaller than the first preset threshold value, the conductive liquid is led into the electrode assembly and seeps out of the skin of the user through the micropores in the micropore electrode, so that the humidity of the skin can be improved, the contact area between the skin of the user and the electrode assembly is increased, the impedance value of the electrode assembly is reduced, the current flowing through the skin of the user is increased, the massage effect is improved, and the massage experience of the user is improved.

Referring to fig. 3, fig. 3 is a schematic flow chart illustrating a control method of a massage apparatus according to another embodiment of the present application. The embodiment of fig. 3 can periodically detect the humidity of the joint part of the microporous electrode and the human body, and realize multiple times of liquid seepage. As shown in fig. 3, the method may include:

step S310, periodically detecting the humidity of the joint part of the microporous electrode and the human body.

In the embodiment of the application, the humidity of the joint part of the microporous electrode and the human body can be detected periodically, that is, the humidity of the joint part of the microporous electrode and the human body can be detected once every preset time, and the preset time can be 5 minutes, 10 minutes, 20 minutes, 30 minutes or other values. The preset duration can be adaptively adjusted according to user requirements and/or actual application scenarios.

Wherein, can detect the humidity of micropore electrode and human laminating position through humidity transducer. The humidity sensor may be disposed at the microporous electrode. The humidity may comprise air humidity and/or human skin humidity. The humidity sensor in the present application may be a single-function humidity sensor, or may be a temperature and humidity sensor having humidity and temperature detection functions.

And step S320, when the humidity is smaller than a first preset threshold value, conducting liquid stored in the liquid storage device is led into the electrode assembly, and the conducting liquid seeps out through micropores of the micropore electrode in the electrode assembly.

When the humidity is less than the first predetermined threshold, it may indicate that the impedance between the electrode assembly and the skin of the user is large, which may cause the current flowing through the skin of the user to be small, resulting in poor massage feeling for the user. At this time, the conductive liquid stored in the reservoir device may be introduced into the electrode assembly, and exuded to the skin of the user through the micropores of the microporous electrode in the electrode assembly.

After the liquid seepage, if the user uses the electrode for a long time, the liquid can be slowly evaporated, so that the humidity of the part, attached to the human body, of the microporous electrode can be continuously detected after the first liquid seepage to determine whether the humidity is reduced, and if the detected humidity is smaller than the first preset threshold value again, the liquid seepage can be performed again, namely, the conductive liquid is seeped through the micropores of the microporous electrode in the electrode assembly again.

For a more detailed description of step S320, reference may be made to the description of step S220, which is not described herein again.

The method provided by the embodiment of the application can periodically detect the humidity of the fit part of the microporous electrode and the human body, and when the humidity is detected to be smaller than a first preset threshold value for the first time or again, the conductive liquid can be introduced into the electrode assembly and seeps out of the skin of a user through the micropores in the electrode, so that the contact area between the skin of the user and the electrode assembly can be increased, the impedance value of the electrode assembly is reduced, the current flowing through the skin of the user is increased, and the massage experience of the user is improved.

Referring to fig. 4, fig. 4 is a schematic flow chart illustrating a control method of a massage apparatus according to another embodiment of the present application. In the embodiment of fig. 4, the wearing state of the massage apparatus is first detected. As shown in fig. 4, the method may include:

and S410, detecting the wearing state of the massage instrument.

The massage instrument can comprise a wearing detection component for detecting wearing parameters of the massage instrument, and the wearing parameters can include but are not limited to at least one of capacitance values, pressure values, distance values and the like of the wearing detection component. Then, the wearing state of the massage apparatus can be determined according to the wearing parameters.

Detecting the wearing state of the massager may include: and acquiring the wearing parameters of the massage instrument, and determining the wearing state of the massage instrument according to the wearing parameters. In an optional embodiment, the wearing detection assembly may include one or more capacitive sensors, and by acquiring capacitance values of the capacitive sensors and comparing the capacitance values of the capacitive sensors with a preset capacitance value, when the capacitance values of the capacitive sensors are greater than the preset capacitance value, it may be determined that the massage apparatus is in a worn state; when the capacitance value of the capacitance sensor is smaller than or equal to the preset capacitance value, the massager can be determined to be in an unworn state. Wherein, capacitive sensor can be capacitanc proximity sensor, and when the human body was close to capacitive sensor, the capacitance value increased, when the human body was kept away from capacitive sensor, the capacitance value reduced.

In an optional embodiment, the wearing detection assembly may include one or more pressure sensors, and by acquiring a pressure value measured by the pressure sensors and comparing the pressure value measured by the pressure sensors with a preset pressure value, when the pressure value measured by the pressure sensors is greater than the preset pressure value, it may be determined that the massage apparatus is in a worn state; when the pressure value measured by the pressure sensor is less than or equal to the preset pressure value, the massage instrument can be determined to be in an unworn state. Wherein, pressure sensor can be used for measuring the pressure value between certain position on the massage appearance and the human body. When a human body contacts with the massage apparatus, a pressure value is generated. When the human body is not in contact with the massage apparatus, the pressure value tends to 0.

In an optional embodiment, the wearing detection assembly may include one or more distance sensors, and by acquiring a distance value measured by the distance sensors and comparing the distance value measured by the distance sensors with a preset distance value, when the distance value measured by the distance sensors is smaller than the preset distance value, it may be determined that the massager is in a worn state; when the distance value measured by the distance sensor is greater than or equal to the preset distance value, the massager can be determined to be in an unworn state. Wherein, the distance sensor can be used for measuring the distance value between a certain position on the massage instrument and the human body. The distance sensor may be at least one of an infrared distance sensor, a laser distance sensor, an ultrasonic distance sensor, and the like. When the human body approaches the massager, the distance value becomes smaller; when the human body is far away from the massage instrument, the distance value becomes larger.

It can be understood that when the wearing state of the massage apparatus is detected by two or more of the above manners, it is determined that the massage apparatus is in the worn state only after respective conditions are satisfied, otherwise, the massage apparatus is not worn. The wearing detection accuracy can be improved by combining multiple modes to carry out detection together.

For example, when the capacitance value and the pressure value are detected together, when the capacitance value is larger than a preset capacitance value and the pressure value is larger than a preset pressure value, it is determined that the massage apparatus is in a worn state, and if one of the capacitance value and the pressure value is not satisfied, it is determined that the massage apparatus is in an unworn state.

For example, when the pressure value and the distance value are detected together, when the pressure value is greater than a preset pressure value and the distance value is less than a preset distance value, it is determined that the massage apparatus is in a worn state, and if one of the pressure value and the distance value is not satisfied, it is determined that the massage apparatus is in an unworn state.

For example, when the capacitance value and the distance value are detected together, when the capacitance value is larger than a preset capacitance value and the distance value is smaller than a preset distance value, it is determined that the massage apparatus is in a worn state, and if one of the capacitance value and the distance value is not satisfied, it is determined that the massage apparatus is in an unworn state.

For example, when the capacitance value, the pressure value and the distance value are detected together, when the capacitance value is larger than a preset capacitance value, the pressure value is larger than a preset pressure value, and the distance value is smaller than a preset distance value, it is determined that the massage apparatus is in a worn state, and if one of the values is not satisfied, it is determined that the massage apparatus is in an unworn state.

And step S420, when the massage instrument is in a worn state, determining the humidity of the joint part of the microporous electrode and the human body.

When the massager is in a worn state, the humidity of the joint part of the microporous electrode and the human body can be detected through the humidity sensor. The humidity sensor may be disposed at the microporous electrode. The humidity may comprise air humidity and/or human skin humidity. The humidity sensor in the present application may be a single-function humidity sensor, or may be a temperature and humidity sensor having humidity and temperature detection functions.

When the massager is not worn, the step S420 may not be performed, and the detection of the worn state may be continued.

And step S430, when the humidity is smaller than a first preset threshold value, conducting liquid stored in the liquid storage device is introduced into the electrode assembly, and the conducting liquid seeps out through micropores of the micropore electrode in the electrode assembly.

In the embodiment of the application, when the massage instrument is in a worn state and the humidity is less than a first preset threshold value, the liquid seepage operation can be carried out. When the massage apparatus is in an unworn state, or the massage apparatus is in an unworn state but the humidity is greater than or equal to the first predetermined threshold, liquid permeation may not be performed, so that waste of liquid may be prevented. In order to avoid the problem that excessive liquid seeps out at one time, the liquid is wasted, and the excessive liquid can cause discomfort for users. Therefore, the amount of the conductive liquid oozed per time can be controlled to a preset amount, which may be 0.1 ml/time, 0.2 ml/time, 0.5 ml/time, or other values.

In addition, when the massage instrument comprises a plurality of groups of micropore electrodes, the liquid can be seeped only on the micropore electrodes in the working mode. The microporous electrode in the working mode may include a microporous electrode having a resistance value greater than a first preset resistance value, and may also include a microporous electrode having a resistance value less than a first preset resistance value. When the massage apparatus comprises a plurality of groups of micropore electrodes, the contact between some micropore electrodes and the skin of a user is good, the impedance value is small, the contact between some micropore electrodes and the skin of the user is poor, the impedance value is large, and if all micropore electrodes are subjected to liquid seepage, liquid waste can be caused. Therefore, the liquid permeation is performed only for the microporous electrode in the operation mode.

In addition, the impedance values between each group of microporous electrodes can be respectively detected and respectively compared with the first preset impedance value, and only the microporous electrodes with the impedance values exceeding the first preset impedance value are subjected to liquid seepage, while other microporous electrodes with the impedance values not exceeding the first preset impedance value are not subjected to liquid seepage.

In an alternative embodiment, the massage apparatus may further comprise a fluid pumping device for pumping the conductive fluid stored in the reservoir device to the electrode assembly when the humidity is less than a first predetermined threshold. Wherein, the liquid pumping-out device can be a liquid pump or an air pump. One end of the liquid pumping-out device is connected with the liquid storage device through a liquid guide pipe, and the other end of the liquid pumping-out device is connected with the electrode assembly through the liquid guide pipe. When the liquid pump-out device is used, the liquid pump-out device works to convey the conductive liquid in the liquid storage device to the electrode assembly, and micro liquid drops are formed through micropores in the micropore electrode. Wherein, the stock solution device can be detachable, can be connected with the massager body is dismantled through magnetism mode or buckle mode for example.

It is understood that the above-mentioned implementation of pumping out the conductive liquid by using the liquid pumping-out device is only one, and the massage apparatus in the embodiment of the present application is not limited to this implementation, but other implementations are also possible, such as providing a switch valve, and controlling the switch valve to open when liquid seepage is required so as to make the conductive liquid in the liquid storage device flow to the electrode assembly, and controlling the seepage amount of the conductive liquid by controlling the open duration of the switch valve. When the seepage is finished, the control switch valve is closed.

According to the method provided by the embodiment of the application, when the massage instrument is worn by a user and the humidity is smaller than the first preset threshold value, the conductive liquid can be introduced into the electrode assembly and seeps out of the skin of the user through the micropores in the electrode, so that the contact area between the skin of the user and the electrode assembly can be increased, the impedance value of the electrode assembly is reduced, the current flowing through the skin of the user is increased, and the massage experience of the user is improved. In addition, the liquid seepage is only carried out when the user wears the electric conduction liquid leakage protective device, and the waste of the electric conduction liquid can be prevented.

Referring to fig. 5, fig. 5 is a schematic flow chart illustrating a control method of a massage apparatus according to another embodiment of the present application. In the embodiment of fig. 5, the temperature of the conductive liquid stored in the liquid storage device can be adjusted. As shown in fig. 5, the method may include:

and step S510, determining the humidity of the joint part of the microporous electrode and the human body.

Before determining the humidity of the joint part of the microporous electrode and the human body, the massager can be worn and detected. When the massager is in a worn state, the subsequent operation can be further executed, otherwise, the operation is finished. The step S510 can refer to the description in the step S210, and is not described herein again.

And step S520, when the humidity is smaller than a first preset threshold value, acquiring the ambient temperature of the environment where the massage instrument is located.

This application embodiment can set up first temperature sensor on the massage appearance for measure ambient temperature. And when the humidity is smaller than a first preset threshold value, acquiring the ambient temperature of the environment where the massage instrument is located. Alternatively, the ambient temperature may be provided by a mobile device (e.g., a mobile phone, a computer, etc.) connected to the massager.

And step S530, adjusting the temperature of the conductive liquid stored in the liquid storage device according to the acquired environmental temperature.

Wherein, the massage instrument can also comprise a temperature adjusting device for adjusting the temperature of the conductive liquid. The temperature adjusting device can adjust the temperature of all conductive liquid in the liquid storage device, so that the subsequent temperature adjusting times can be reduced. At this time, the temperature adjusting device may be disposed in the liquid storage device.

The temperature adjusting means may also adjust the temperature of only the portion of the conductive liquid to be introduced into the electrode assembly, which can reduce power consumption. In this case, the temperature regulation device can be arranged at the catheter, for example wound around the catheter in the manner of a coil.

And step S540, introducing the conductive liquid subjected to temperature adjustment into the electrode assembly, and seeping the conductive liquid through micropores of the micropore electrode in the electrode assembly.

In an alternative embodiment, the temperature adjustment of the conductive liquid stored in the liquid storage device according to the acquired environmental temperature may include: when the environment temperature is lower than a first preset environment temperature, controlling a temperature adjusting device to heat the conductive liquid stored in the liquid storage device;

accordingly, the introducing the temperature-adjusted conductive liquid to the electrode assembly may include: the heated conductive liquid is introduced into the electrode assembly.

The first preset ambient temperature may be a default temperature set by the system, and may also allow the user to set and modify the preset ambient temperature by himself, which is not limited in the present application. For example, the first predetermined ambient temperature may be 20 degrees, 18 degrees, 15 degrees, 10 degrees, or other values.

When the ambient temperature is lower than the first preset ambient temperature, the current air temperature can be indicated to be lower (for example, the air temperature in winter is low), the conductive liquid can be heated, the temperature of the liquid is increased, and therefore stimulation to a user caused by too cold liquid can be avoided, and the massage experience of the user is influenced.

Wherein, controlling temperature regulation apparatus to heat the conducting liquid of storage in the stock solution device can include: and controlling the temperature adjusting device to heat the conductive liquid stored in the liquid storage device until the liquid temperature of the conductive liquid is increased to a first preset liquid temperature. The first preset liquid temperature may be a default temperature or a user-defined temperature according to the user's own needs. For example, the first predetermined liquid temperature may be 30 degrees, 35 degrees, 36 degrees, 38 degrees, or other values. For example, when the temperature is lower than 10 ℃ in winter, the liquid can be heated to be close to the body temperature of a human body, for example, the liquid seeps at 36 ℃, so that the stimulation to a user caused by too cold liquid can be avoided, and the user can be prevented from being scalded caused by too hot liquid.

In an alternative embodiment, controlling the temperature adjustment device to adjust the temperature of the conductive liquid stored in the liquid storage device according to the ambient temperature may include: when the environment temperature is higher than a second preset environment temperature, controlling the temperature adjusting device to refrigerate the conductive liquid stored in the liquid storage device; wherein the introducing of the temperature-adjusted conductive liquid to the electrode assembly may include: and introducing the refrigerated conductive liquid into the electrode assembly.

The second preset ambient temperature may be a default temperature, or may allow the user to set and modify the size of the second preset ambient temperature by himself, which is not limited in the present application. For example, the second predetermined ambient temperature may be 28 degrees, 30 degrees, 32 degrees, 35 degrees, or other values. When ambient temperature is higher than the preset ambient temperature of second, can show that current temperature is higher (like when summer is hot), can refrigerate conducting liquid, make the liquid temperature reduce to can alleviate the summer-heat gas on the user, cool down for the user, promote user's massage and experience.

Wherein, control temperature regulation apparatus refrigerates the electrically conductive liquid of storage in to the stock solution device can include: and controlling the temperature adjusting device to refrigerate the conductive liquid stored in the liquid storage device until the liquid temperature of the conductive liquid is reduced to a second preset liquid temperature. The second preset liquid temperature may be a default temperature or a user-defined temperature according to the user's own needs. The second preset liquid temperature may be 25 degrees, 20 degrees, 18 degrees, 15 degrees, or other values. For example, when the temperature is higher than 30 ℃ in summer, the temperature of the liquid can be reduced to be lower than 25 ℃ and then the liquid seeps out, so that the stimulation to a user caused by too cold liquid can be avoided.

In an alternative embodiment, the liquid temperature of the conductive liquid stored in the liquid storage device may also be obtained, and the temperature of the conductive liquid may be adjusted by combining the ambient temperature and the liquid temperature. Wherein a second temperature sensor may be provided within the massage device for measuring the temperature of the liquid. The second temperature sensor may be disposed within the reservoir.

Wherein, when this ambient temperature is less than first preset ambient temperature, control temperature regulation apparatus and heat the conducting liquid who stores in the stock solution device and can include: when the environment temperature is lower than the first preset environment temperature and the liquid temperature is lower than the third preset liquid temperature, the temperature adjusting device is controlled to heat the conductive liquid stored in the liquid storage device. The third preset liquid temperature may be a default temperature set by the system, or may allow a user to set and modify the size of the third preset liquid temperature by himself, which is not limited in the present application. The third predetermined liquid temperature is lower than the first predetermined liquid temperature. For example, the temperature of the liquid may be detected when the temperature of the air is lower than 10 degrees in winter, and the conductive liquid may be heated to raise the temperature of the liquid when the temperature of the liquid is lower than a third predetermined liquid temperature, for example, lower than 25 degrees. The heating operation can be more definite by combining the liquid temperature, and repeated heating when the liquid temperature is not low is avoided.

In an optional embodiment, when the ambient temperature is higher than the second preset ambient temperature, controlling the temperature adjustment device to refrigerate the conductive liquid stored in the liquid storage device may include: when the ambient temperature is higher than the second preset ambient temperature and the liquid temperature is higher than the fourth preset liquid temperature, the temperature adjusting device is controlled to refrigerate the conductive liquid stored in the liquid storage device. The fourth preset liquid temperature may be a default temperature set by the system, or may allow a user to set and modify the size of the fourth preset liquid temperature by himself, which is not limited in the present application. The fourth predetermined liquid temperature is higher than the second predetermined liquid temperature. For example, the temperature of the liquid may be detected when the summer air temperature is higher than 30 degrees, and the conductive liquid may be cooled to lower the temperature of the liquid when the temperature of the liquid is higher than a fourth predetermined liquid temperature, such as higher than 28 degrees. The refrigeration operation can be more definite by combining the liquid temperature, and repeated refrigeration when the liquid temperature is not high is avoided.

The method provided by the embodiment of the application adjusts the temperature of the conductive liquid through the environmental temperature, so that the liquid temperature is more suitable for users, and the massage experience of the users is further improved. Furthermore, the temperature of the conductive liquid is adjusted together by combining the ambient temperature and the liquid temperature, so that the temperature adjustment is more definite, and repeated adjustment for many times is avoided.

Referring to fig. 6, fig. 6 is a schematic flow chart illustrating a control method of a massage apparatus according to another embodiment of the present application. Different first predetermined thresholds may be preconfigured for different users in the embodiment of fig. 6. As shown in fig. 6, the method may include:

and step S610, determining the humidity of the joint part of the microporous electrode and the human body.

The step S610 can refer to the description in the step S210, and is not described herein again.

And S620, acquiring user information of a user wearing the massage instrument, and matching a corresponding first preset threshold according to the user information, wherein the first preset threshold is configured in advance according to different users.

According to the embodiment of the application, different first preset thresholds can be configured in advance for different users, and the corresponding relation between the user information and the first preset thresholds can be stored in the memory. In this step, user information of a user wearing the massage apparatus may be acquired; after the user information is obtained, a corresponding first preset threshold value is matched for the current user according to the user information and the corresponding relation.

And step S630, when the humidity is smaller than a first preset threshold value, conducting liquid stored in the liquid storage device is led into the electrode assembly, and the conducting liquid seeps out through micropores of the micropore electrodes in the electrode assembly.

When the humidity is less than the first predetermined threshold, it may indicate that the impedance between the electrode assembly and the skin of the user is large, which may cause the current flowing through the skin of the user to be small, resulting in poor massage feeling for the user. At this time, the conductive liquid stored in the liquid storage device can be guided into the electrode assembly, the conductive liquid can be seeped out to the skin of a user through the micropores on the micropore electrodes in the electrode assembly, after the liquid soaks the skin, the humidity of the skin is improved, the contact area between the skin and the electrode assembly can be increased, the dielectric constant between the skin and the electrode assembly is changed, the impedance value of the electrode assembly is reduced, and the massage effect is improved. The conductive liquid may include water, an aqueous solution, or a massage liquid having a drug-assisted function.

The details of step S630 can be referred to the description of step S220, and are not described herein again.

It should be further noted that the embodiment of the present application may support a user to set and modify the first predetermined threshold by himself, and after the modification, the corresponding relationship between the user information and the first predetermined threshold is updated in the memory.

Since different users sense the current differently, the user can be allowed to set and modify the magnitude of the first predetermined threshold value by himself. Specifically, the massage apparatus may be connected to a mobile phone of a user, an application program for controlling the massage apparatus is installed in the mobile phone, and the user initiates an operation instruction for modifying the first predetermined threshold in the application program.

In addition, different users can sense different current, and the user can control seepage automatically. Even if the humidity is not less than the first predetermined threshold, the user can control the massage apparatus to perform liquid seepage. The user can directly operate the keys on the massage instrument to enable the massage instrument to seep liquid, and can also initiate an operation instruction for indicating the seepage liquid of the massage instrument in an application program on the mobile phone.

The above detailed description describes the control method of the massage apparatus of the present application, and correspondingly, the present application further provides a control device of the massage apparatus and the massage apparatus.

Referring to fig. 7, fig. 7 is a schematic structural diagram of a control device of a massage apparatus according to an embodiment of the present application. The control device 70 of the massage apparatus may be used to execute any of the control methods of the massage apparatus described in the foregoing embodiments. The massage instrument can comprise an electrode assembly for outputting electric pulse signals and a liquid storage device for storing conductive liquid, wherein the electrode assembly can comprise at least one group of micropore electrodes, and the micropore electrodes are provided with micropores. As shown in fig. 7, the control device 70 of the massage apparatus may include: a humidity detection module 710 and a seepage control module 720.

And the humidity detection module 710 is used for determining the humidity of the joint part of the microporous electrode and the human body. The humidity may comprise air humidity and/or human skin humidity. The humidity detection module 710 may periodically detect the humidity of the bonding portion of the microporous electrode and the human body, that is, the humidity of the bonding portion of the microporous electrode and the human body may be detected once every preset time period, where the preset time period may be 5 minutes, 10 minutes, 20 minutes, 30 minutes, or other values. The preset duration can be adaptively adjusted according to user requirements and/or actual application scenarios.

And the seepage control module 720 is used for guiding the conductive liquid stored in the liquid storage device into the electrode assembly and seeping the conductive liquid out through the micropores of the micropore electrodes in the electrode assembly when the humidity detection module 710 determines that the humidity is smaller than the first preset threshold value. When the humidity is less than the first predetermined threshold, it may indicate that the impedance between the electrode assembly and the skin of the user is large, which may cause the current flowing through the skin of the user to be small, resulting in poor massage feeling for the user. At this time, the conductive liquid stored in the liquid storage device can be introduced into the electrode assembly through the liquid seepage control module 720, the conductive liquid can be seeped out onto the skin of the user through the micropores on the micropore electrodes in the electrode assembly, after the liquid soaks the skin, the humidity of the skin is improved, the contact area between the skin and the electrode assembly can be increased, the dielectric constant between the skin and the electrode assembly is changed, and therefore the impedance value of the electrode assembly is reduced, and the massage effect is improved. The conductive liquid can comprise water, aqueous solution or massage liquid with drug auxiliary function

Optionally, the apparatus shown in fig. 7 may further comprise a wear detection module (not shown in the figure). And the wearing detection module is used for detecting the wearing state of the massage instrument before the humidity detection module 710 detects the humidity of the joint part of the micropore electrode and the human body, and when the massage instrument is in the wearing state, the wearing detection module 710 is triggered to detect the humidity of the joint part of the micropore electrode and the human body.

Optionally, the massage apparatus may further include a wear detection module, and the wear detection module may include: a parameter obtaining submodule and a state determining submodule; wherein:

the parameter acquisition sub-module is used for acquiring wearing parameters of the massager, and the wearing parameters can include but are not limited to at least one of capacitance values, pressure values, distance values and the like of the wearing detection assembly;

and the state determining submodule is used for determining the wearing state of the massage instrument according to the wearing parameters.

Optionally, the wearing detection assembly may include at least one capacitive sensor, and the manner of acquiring the wearing parameters of the massage apparatus by the parameter acquiring sub-module may include: the parameter acquisition submodule acquires a capacitance value of the capacitance sensor; accordingly, the manner of determining the wearing state of the massage apparatus by the state determining sub-module according to the wearing parameter may include: and when the capacitance value of the capacitance sensor is larger than the preset capacitance value, the state determination submodule determines that the massager is in a worn state.

Optionally, the wearing detection assembly may include at least one pressure sensor, and the manner of acquiring the wearing parameters of the massage apparatus by the parameter acquiring sub-module may include: the parameter acquisition submodule acquires a pressure value measured by the pressure sensor; accordingly, the manner of determining the wearing state of the massage apparatus by the state determining sub-module according to the wearing parameter may include: and when the pressure value measured by the pressure sensor is greater than the preset pressure value, the state determination submodule determines that the massager is in a worn state.

Optionally, the wearing detection assembly may include at least one distance sensor, and the manner of acquiring the wearing parameters of the massage apparatus by the parameter acquiring sub-module may include: the parameter acquisition submodule acquires a distance value measured by the distance sensor; accordingly, the manner of determining the wearing state of the massage apparatus by the state determining sub-module according to the wearing parameter may include: and the state determining submodule determines that the massager is in a worn state when the distance value measured by the distance sensor is smaller than the preset distance value.

Optionally, the massage apparatus may further include a temperature adjustment device, and the device shown in fig. 7 may further include: a temperature acquisition module and a temperature adjustment module (not shown in the figures).

The temperature acquisition module is used for acquiring the ambient temperature of the environment where the massage instrument is located;

the temperature adjusting module is used for controlling the temperature adjusting device to adjust the temperature of the conductive liquid stored in the liquid storage device according to the environmental temperature acquired by the temperature acquiring module;

the seepage control module 720 guides the temperature-adjusted conductive liquid to the electrode assembly.

Optionally, the temperature adjusting module controls the temperature adjusting device to adjust the temperature of the conductive liquid stored in the liquid storage device according to the ambient temperature, and the method may include:

when the environment temperature is lower than a first preset environment temperature, the temperature adjusting module controls the temperature adjusting device to heat the conductive liquid stored in the liquid storage device; the seepage control module 720 guides the heated conductive liquid to the electrode assembly.

The temperature adjusting module controls the temperature adjusting device to heat the conductive liquid stored in the liquid storage device until the liquid temperature of the conductive liquid is increased to a first preset liquid temperature.

Optionally, the temperature adjusting module controls the temperature adjusting device to adjust the temperature of the conductive liquid stored in the liquid storage device according to the environmental temperature, and the method may include: when the environment temperature is higher than a second preset environment temperature, the temperature adjusting module controls the temperature adjusting device to refrigerate the conductive liquid stored in the liquid storage device; the seepage control module 720 guides the refrigerated conductive liquid to the electrode assembly.

The temperature adjusting module controls the temperature adjusting device to refrigerate the conductive liquid stored in the liquid storage device until the liquid temperature of the conductive liquid is reduced to a second preset liquid temperature.

Optionally, the temperature obtaining module may be further configured to obtain a liquid temperature of the conductive liquid stored in the liquid storage device; when the ambient temperature of the temperature adjusting module is lower than the first preset ambient temperature and the liquid temperature is lower than the third preset liquid temperature, the temperature adjusting module controls the temperature adjusting device to heat the conductive liquid stored in the liquid storage device.

When the ambient temperature is higher than the second preset ambient temperature and the liquid temperature is higher than the fourth preset liquid temperature, the temperature adjusting module controls the temperature adjusting device to refrigerate the conductive liquid stored in the liquid storage device.

Optionally, the massage apparatus may further comprise a fluid pumping device, and the seepage control module 720 is configured to pump the conductive fluid stored in the reservoir device to the electrode assembly through the fluid pumping device when the humidity is less than the first predetermined threshold.

Optionally, when the electrode assembly includes at least two sets of microporous electrodes, the seepage control module 720 guides the conductive liquid stored in the liquid storage device to the microporous electrodes in the working mode, and seeps out the conductive liquid through the micropores on the microporous electrodes in the working mode.

The device that this application embodiment provided, when humidity is less than first predetermined threshold, through leading into electrode subassembly with conducting liquid, ooze to user's skin on the micropore on the electrode, improve the humidity of skin to can increase the area of contact between user's skin and the electrode subassembly, reduce the impedance value of electrode subassembly, make the electric current increase of user's skin of flowing through, promote user's massage experience. Just carry out the sepage when the user wears, can prevent to cause the waste of conducting liquid. In addition, the temperature of the conductive liquid is adjusted through the ambient temperature, so that the liquid temperature is more suitable for users, and the massage experience of the users is further improved.

With regard to the apparatus in the above-described embodiment, the specific manner in which each module performs the operation has been described in detail in the embodiment related to the method, and will not be elaborated here.

Referring to fig. 8, fig. 8 is a block diagram of a massage apparatus according to an embodiment of the present application. The massage machine may be used to execute any of the control methods of the massage machines described in the foregoing embodiments. As shown in fig. 8, the massage apparatus 80 may include: the electrode assembly 810, the liquid storage device 820 and the controller 830, wherein the electrode assembly 810 can comprise at least one group of microporous electrodes, and the electrode assembly 810 is respectively connected with the liquid storage device 820 and the controller 830;

the electrode assembly 810 may be used to output electrical pulse signals;

reservoir 820 may be used to store a conductive liquid;

the controller 830 may be configured to determine the humidity of the portion of the microporous electrode attached to the human body, and when the humidity is less than a first predetermined threshold, introduce the conductive liquid stored in the liquid storage device 820 into the electrode assembly 810, and seep the conductive liquid through the micropores of the microporous electrode in the electrode assembly 810.

The detailed structure and function of the controller 830 can be seen from the related description of the control device of the massage apparatus in fig. 7, and are not described herein again.

Referring to fig. 9, fig. 9 is a block diagram of another massage apparatus according to an embodiment of the present application. The massage machine may be used to execute any of the control methods of the massage machines described in the foregoing embodiments.

As shown in fig. 9, the massage apparatus 900 may include: a processor 910 and a memory 920. Wherein the processor 910 is communicatively coupled to the memory 920. It is understood that the structure of the massage apparatus 900 shown in fig. 9 does not limit the embodiments of the present application, and may include more components than those shown in the drawings, such as an electrode assembly, a communication interface (e.g., a bluetooth module, a WIFI module, etc.), an input/output interface (e.g., a button, a touch screen, a speaker, a microphone, etc.), a sensor, and so on. Wherein:

the Processor 910 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic device, discrete hardware component, etc. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The memory 920 may include various types of storage units, such as system memory, Read Only Memory (ROM), and permanent storage. Wherein the ROM may store static data or instructions for the processor 910 or other modules of the computer. The persistent storage device may be a read-write storage device. The persistent storage may be a non-volatile storage device that does not lose stored instructions and data even after the computer is powered off. In some embodiments, the persistent storage device employs a mass storage device (e.g., magnetic or optical disk, flash memory) as the persistent storage device. In other embodiments, the permanent storage may be a removable storage device (e.g., floppy disk, optical drive). The system memory may be a read-write memory device or a volatile read-write memory device, such as a dynamic random access memory. The system memory may store instructions and data that some or all of the processors require at runtime. In addition, the memory 920 may include any combination of computer-readable storage media, including various types of semiconductor memory chips (DRAM, SRAM, SDRAM, flash, programmable read only memory), magnetic and/or optical disks, among others. In some embodiments, memory 920 may include a removable storage device that is readable and/or writable, such as a Compact Disc (CD), a digital versatile disc read only (e.g., DVD-ROM, dual layer DVD-ROM), a Blu-ray disc read only, an ultra-dense disc, a flash memory card (e.g., SD card, min SD card, Micro-SD card, etc.), a magnetic floppy disk, or the like. Computer-readable storage media do not contain carrier waves or transitory electronic signals transmitted by wireless or wired means.

The memory 920 has stored thereon executable code, which when processed by the processor 910, causes the processor 910 to perform some or all of the steps of the methods described above.

Furthermore, the method according to the present application may also be implemented as a computer program or computer program product comprising computer program code instructions for performing some or all of the steps of the above-described method of the present application.

Alternatively, the present application may also be embodied as a non-transitory machine-readable storage medium (or computer-readable storage medium, or machine-readable storage medium) having stored thereon executable code (or a computer program, or computer instruction code) which, when executed by a processor of an electronic device (or electronic device, server, etc.), causes the processor to perform some or all of the various steps of the above-described methods in accordance with the present application.

The aspects of the present application have been described in detail hereinabove with reference to the accompanying drawings. In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments. Those skilled in the art should also appreciate that the acts and modules referred to in the specification are not necessarily required in the present application. In addition, it can be understood that the steps in the method of the embodiment of the present application may be sequentially adjusted, combined, and deleted according to actual needs, and the modules in the device of the embodiment of the present application may be combined, divided, and deleted according to actual needs.

Having described embodiments of the present application, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (22)

1. A massage apparatus, comprising: the massager comprises a massager body, an electrode assembly, a controller, a liquid storage device and a liquid guide assembly; wherein the content of the first and second substances,

the liquid storage device is arranged on one side, back to the skin of a human body, of the massage instrument body and comprises a liquid storage cavity for storing conductive liquid;

the electrode assembly is arranged on one side of the massage instrument body facing the skin of the human body and used for outputting electric pulse signals; the electrode assembly comprises at least one group of microporous electrodes, one group of microporous electrodes comprises two microporous electrodes, and at least one micropore is formed in one microporous electrode;

the liquid guide assembly is arranged in the massage instrument body and is respectively connected with the liquid storage device and the electrode assembly;

the controller is arranged in the massager body, is respectively connected with the electrode assembly and the liquid guide assembly and is used for determining the humidity of the joint part of the microporous electrode and the human body; and when the humidity is smaller than a first preset threshold value, controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly, and seeping the conductive liquid through micropores of microporous electrodes in the electrode assembly.

2. The massager of claim 1, further comprising a humidity sensor disposed on said microporous electrode;

the humidity sensor is connected with the controller and used for detecting the humidity of the fit part of the microporous electrode and the human body.

3. The massager of claim 1, wherein the liquid storage device is detachably connected with the massager body.

4. The massager of claim 3, wherein the liquid storage device is detachably connected with the massager body in a magnetic attraction manner or a clamping manner.

5. The massager of claim 1, wherein the pore size of the micropores on the microporous electrode is 5 μm to 50 μm.

6. The massager of claim 5, wherein the distance between two adjacent micropores on the micropore electrode is 200 μm to 500 μm.

7. The massager of claim 1, further comprising a wear detection assembly disposed on the massager body;

the wearing detection assembly is connected with the controller and used for detecting the wearing state of the massager.

8. The massager of claim 7, wherein the wearing detection assembly comprises at least one capacitive sensor disposed on a side of the massager body facing the skin of the human body and respectively connected to the controller.

9. The massager of claim 7, wherein the wearing detection assembly comprises at least one pressure sensor disposed on a side of the massager body facing the skin of the human body and respectively connected to the controller.

10. The massager of claim 7, wherein the wearing detection assembly comprises at least one distance sensor disposed on a side of the massager body facing the skin of the human body and respectively connected to the controller.

11. The massager of claim 7, wherein said wear detection assembly comprises a current sensor connected to said controller for detecting the magnitude of current output from said micro-porous electrodes.

12. The massager of claim 7, wherein said wear detection assembly comprises a voltage sensor connected to said controller for detecting a divided voltage across a voltage dividing resistor in an output circuit of said micro-porous electrode.

13. The massager of claim 1, wherein said drainage assembly comprises a first fluid conduit, a fluid pumping means and a second fluid conduit; wherein the content of the first and second substances,

one end of the first liquid guide pipe is connected with the liquid storage device, and the other end of the first liquid guide pipe is connected with a liquid inlet of the liquid pumping-out device;

one end of the second liquid guide pipe is connected with a liquid outlet of the liquid pumping-out device, and the other end of the second liquid guide pipe is connected with the electrode assembly;

the liquid pumping-out device is also connected with the controller and is controlled by the controller to pump out the conductive liquid stored in the liquid storage device to the electrode assembly when the humidity is less than a first preset threshold value.

14. The massage apparatus as claimed in claim 13, wherein the bottom of the liquid storage chamber is provided with at least one through hole, and the first liquid guiding tube is communicated with the liquid storage device through the through hole.

15. The massager of claim 1, wherein said drainage assembly comprises a third drainage tube, a switch valve and a fourth drainage tube; wherein the content of the first and second substances,

one end of the third liquid guide pipe is connected with the liquid storage device, and the other end of the third liquid guide pipe is connected with the liquid inlet end of the switch valve;

one end of the fourth liquid guide pipe is connected with the liquid outlet end of the switch valve, and the other end of the fourth liquid guide pipe is connected with the electrode assembly;

the switch valve is also connected with the controller and is controlled by the controller.

16. The massager of any one of claims 1-15, further comprising a temperature adjusting device connected to said controller for adjusting the temperature of said conductive liquid.

17. The massager of claim 16, wherein the temperature regulating device is disposed within the reservoir chamber or at an interface of the reservoir and the electrode assembly.

18. The massager of claim 16, further comprising a first temperature sensor disposed on said massager body;

the first temperature sensor is connected with the controller and used for collecting the ambient temperature of the environment where the massager is located.

19. The massager of claim 16, further comprising a second temperature sensor disposed within said reservoir;

the second temperature sensor is connected with the controller and used for collecting the liquid temperature of the conductive liquid stored in the liquid storage cavity.

20. The massager of any one of claims 1-15, further comprising a timer disposed within the massager body;

the timer is connected with the controller and used for timing.

21. The massage apparatus as claimed in any one of claims 1 to 15, wherein:

the controller determines the liquid permeation amount of the conductive liquid according to the humidity, wherein the humidity and the liquid permeation amount of the conductive liquid are in a negative correlation relationship; and controlling the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into the electrode assembly according to the determined seepage amount.

22. The massage apparatus as claimed in any one of claims 1 to 15, wherein:

the electrode assembly comprises at least two groups of micropore electrodes, the controller controls the liquid guide assembly to guide the conductive liquid stored in the liquid storage device into a set micropore electrode in the at least two groups of micropore electrodes, the conductive liquid is seeped out through micropores of the set micropore electrode, and the set micropore electrode is a micropore electrode in a working mode.

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