JP7480411B1 - Facial beauty device and its control method - Google Patents

Abstract

[Problem] To provide a facial beauty device and a control method thereof. [Solution] The facial beauty device includes a panel 11, a plurality of first electrodes 12, and a controller. The panel has a plurality of operating areas. Each operating area is provided with at least one first electrode, and each first electrode includes an electrode body 121 and a temperature sensor 122, and the temperature sensor is attached to the inner space of the electrode body and fixedly connected to the electrode body. The controller is electrically connected to the plurality of first electrodes and is used to obtain the detection values of the temperature sensors of the first electrodes in the plurality of operating areas, and adjust the output energy of the electrode body of the first electrode in the corresponding operating area based on the detection value. The facial beauty device has a plurality of operating areas, and the controller can adjust the output energy of the plurality of operating areas, thereby realizing temperature control of each operating area to improve the direction of treatment and care, thereby improving the effect of treatment and care of the facial beauty device. [Selected Figure] Figure 3

Description

This application relates to the technical field of facial beauty devices, and in particular to facial beauty devices.

In facial beauty devices commonly used on the market, the skin treatment and care temperature by the treatment electrode chip is usually set to the same. That is, the skin treatment and care temperature by the entire electrode chip is the same. However, in reality, since different areas of the facial skin have different requirements for treatment and care temperature, during the treatment and care process, the treatment and care temperature of some skin cannot meet the requirements, leading to a situation where the temperature of other parts of the skin is too high, which affects the effect of treatment and care and also affects the user experience.

This application provides a facial beauty device and a control method thereof. The electrode chip of the facial beauty device has multiple treatment and care areas, and the treatment temperature of each treatment and care area can be controlled independently, providing a higher directionality for treatment and care of the facial beauty device.

In a first aspect, the present application provides a facial beauty device. The facial beauty device includes a panel having a plurality of operating areas, each of which is provided with at least one first electrode, each of which includes an electrode body and a temperature sensor, the temperature sensor being attached to the internal space of the electrode body and fixedly connected to the electrode body, and a controller electrically connected to the plurality of first electrodes, for acquiring detection values of the temperature sensors of the first electrodes in the plurality of operating areas, and for adjusting the output energy of the electrode body of the first electrode in the corresponding operating area based on the detection value.

In one possible embodiment, the facial beauty device further comprises at least one second electrode, the second electrode is attached to at least one operating area, one end of the second electrode is exposed from the panel, the second electrode is installed at a distance from the first electrode, and the controller is electrically connected to the second electrode and is also used to adjust the output energy of the second electrode in the corresponding operating area based on the detection value.

In one possible embodiment, multiple active areas are arranged along the length or width of the panel, or multiple active areas are arranged in an array, or at least one active area is arranged surrounding another active area.

In one possible embodiment, the facial beauty device further includes an exchange component electrically connected to the controller, and the controller is used to receive exchange information emitted by the exchange component and control the operating state of the first electrode in at least one operating area based on the exchange information.

In one possible embodiment, the beauty device further comprises a housing and a display screen, the display screen is attached to the housing, the display screen includes a plurality of display areas, the arrangement rules of the plurality of display areas and the plurality of operating areas are the same and correspond one-to-one, the controller is attached inside the housing, the display screen is electrically connected to the controller, and the controller is also used to light up the corresponding display area when the first electrode in at least one operating area is operating.

In one possible embodiment, the facial beauty device further includes a command member electrically connected to the controller, and the controller is also used to control the operating state of the command member.

In one possible embodiment, the first electrode has a head and a body, the body is sleeve-shaped, the head is fixedly connected to one end of the body, at least a portion of the head is exposed from the panel, and the temperature sensor is located in the internal space of the body and fixedly connected to the head.

In one possible embodiment, the facial beauty device further includes a thermally conductive rubber located in the internal space of the electrode body and connected to the head, the temperature sensor, and the main body.

In a second aspect, the present application provides a method for controlling a facial beauty device. The facial beauty device includes a panel, a plurality of first electrodes, and a controller. The panel has a plurality of operating areas, each of which is provided with at least one first electrode. Each of the first electrodes includes an electrode body and a temperature sensor. The temperature sensor is attached to the inner space of the electrode body and is fixedly connected to the electrode body. The controller is electrically connected to the plurality of first electrodes. The method for controlling the facial beauty device includes the controller acquiring detection values of the temperature sensors of the first electrodes in the plurality of operating areas, and the controller adjusting the output energy of the electrode body of the first electrode in the corresponding operating area based on the detection value.

In one possible embodiment, the controller adjusting the output energy of the electrode body of the first electrode in the corresponding operating region based on the detection value includes determining a relationship between the detection value and a threshold range, controlling the output energy of the electrode body of the first electrode in the corresponding operating region so that it does not change if the detection value is within the threshold range, increasing the output energy of the electrode body of the first electrode in the corresponding operating region if the detection value is lower than the threshold range, and decreasing the output energy of the electrode body of the first electrode in the corresponding operating region if the detection value is higher than the threshold range.

In one possible embodiment, the facial beauty device further comprises a housing and a display screen, the display screen is attached to the housing, the display screen includes a plurality of display areas, the arrangement rules of the plurality of display areas and the plurality of operating areas are the same and correspond one-to-one, the controller is located inside the housing, the display screen is electrically connected to the controller, and the control method further includes that when the first electrode in at least one operating area operates, the controller lights up the corresponding display area.

In one possible embodiment, the facial beauty device further includes a replacement component electrically connected to the controller, and the control method further includes the controller receiving replacement information emitted by the replacement component, and the controller controlling an operating state of the first electrode in at least one operating area based on the replacement information.

In one possible embodiment, the exchange information comprises mode selection information and/or stage selection information;
The controller controls the first electrode output energy in at least one operating region of the plurality of operating regions based on the mode selection information, and the controller adjusts a magnitude of the output energy of the first electrode in an operating state based on the stage selection information.

In one possible embodiment, the facial beauty device has a first operating area, a second operating area, and a third operating area arranged along the length of the panel, and when the mode selection information is the first information, the controller controls the first electrodes in the first operating area, the second operating area, and the third operating area to output energy, and when the mode selection information is the second information, the controller controls the first electrodes in the first operating area and the third operating area to output energy.

In one possible embodiment, the facial beauty device further includes an indicator member electrically connected to the controller, and the control method further includes the controller controlling the operating state of the indicator member based on the stage selection information.

The facial beauty device according to the present application has multiple operating areas, and a first electrode is provided in each operating area, and the first electrode is electrically connected to a controller. The first electrode includes an electrode body and a temperature sensor, and the controller obtains the detection value of the temperature sensor of the first electrode in the multiple operating areas, and adjusts the output energy of the electrode body of the first electrode in the corresponding operating area based on the detection value, thereby realizing temperature control of each operating area. In this way, the treatment temperature of each operating area of the facial beauty device becomes more accurate, and the electrode tip is less likely to become uncontrollable in temperature in some areas, affecting the treatment effect.

In addition, different operating areas of the facial beauty device may have different treatment temperatures, thereby improving the direction of treatment and care according to the requirements for treatment and care temperature in different areas of the face, thereby improving the effect of treatment and care and improving the user experience.

In addition, after the beauty device realizes area-specific temperature control management, when the beauty device is used to treat and care for small areas on the face such as around the eyes, it can only start the care and treatment of the local area, which helps to reduce power consumption and extend the service life of the beauty device.

FIG. 1 is a structural schematic diagram of a facial beauty device according to an embodiment of the present application. FIG. 2 is a schematic diagram of the structure of the electrode tip shown in FIG. FIG. 3 is an exploded view of the local structure of the electrode tip shown in FIG. FIG. 4 is a structural schematic diagram of another embodiment of the electrode tip shown in FIG. FIG. 5 is a local cross-sectional view of the electrode tip shown in FIG. 2 taken along line AA. FIG. 6 is a local enlarged view of the electrode tip shown in FIG. FIG. 7 is a schematic diagram of a local structure of the fuselage shown in FIG. FIG. 8 is a schematic diagram showing an operation process of the facial beauty device shown in FIG. FIG. 9 is a schematic diagram showing a part of a process of a method for controlling a facial beauty device according to an embodiment of the present application. FIG. 10 is a schematic diagram showing another process of the control method of the facial beauty device shown in FIG.

In the description of the embodiments of the present application, it should be explained that unless otherwise clearly specified and limited, the term "connection" should be understood in a broad sense, for example, "connection" may be a removable connection or a non-removable connection, and may be a direct connection or an indirect connection through an intermediate medium. The term "integral molding" means that in the process of forming one of the multiple members, the member is integrally connected to the other member, and there is no need to connect the two members together by means of reworking (e.g., gluing, welding, buckling, screw connection). The orientation terms mentioned in the embodiments of the present application, such as "top", "inside", "outside", "bottom", "side", etc., refer only to the directions in the drawings, and therefore the orientation terms used are intended to better and more clearly explain and understand the embodiments of the present application, and do not indicate or imply that the devices or elements mentioned necessarily have a specific orientation and must be configured and operated in a specific orientation, and therefore should not be understood to limit the embodiments of the present application. Hereinafter, the terms "first", "second", etc. are for explanatory purposes only and should not be understood as implying or suggesting the relative importance or number of technical features being indicated. Thus, a feature qualified by "first" or "second" may explicitly or implicitly include one or more of said features. "Plurality" refers to at least two.

The following describes the embodiments of the present application with reference to the drawings of the embodiments of the present application.

Figure 1 is a schematic diagram of the structure of a facial beauty device 1000 according to an embodiment of the present application.

As shown in FIG. 1, the facial beautifying device 1000 may be a facial beautifying device for personal care. For example, it may be a high-frequency facial beautifying device, a microcurrent facial beautifying device, etc. The facial beautifying device 1000 may include an electrode tip 100 and a body 200. The electrode tip 100 may be attached to the body 200.

The body 200 of the facial beauty device 1000 may include a housing 21 and a controller (not shown). The controller may be attached inside the housing 21. The electrode tip 100 may be fixed to the outside of the housing 21, and the connection housing 21 may be sealed to prevent external dust or water vapor from entering the inside of the housing 21 and affecting the performance of the controller. For example, the electrode tip 100 may be fixed to the housing 21 by an attachment means.

The electrode tip 100 may be electrically connected to a controller. The controller may be used to receive external information (e.g., user operation information) and adjust the operating state of the electrode tip 100 based on the received external information. The operating state of the electrode tip 100 may include information such as whether the electrode tip 100 is operating, the output power of the electrode tip 100, the operating temperature of the electrode tip 100, and the operating time of the electrode tip 100. The controller may further be used to receive detection information of the electrode tip 100 and adjust the operating state of the electrode tip 100 based on the received detection information.

Figure 2 is a schematic diagram of the structure of the electrode tip 100 shown in Figure 1. Figure 3 is an exploded view of the local structure of the electrode tip 100 shown in Figure 2.

2 and 3, the electrode tip 100 may include a panel 11 and a plurality of first electrodes 12. The plurality of first electrodes 12 may be attached to the panel 11 of the electrode tip 100. The first electrodes 12 can be used to detect the skin temperature of a user and output energy to treat and care for the skin of the user. The controller can adjust the operating temperature of the electrode tip 100 based on the detection value of the first electrode 12. As can be seen, compared with the solution of installing only one first electrode 12 on the entire panel 11, the electrode tip 100 according to the embodiment of the present application has higher temperature uniformity, and is less likely to cause the temperature of a part of the electrode tip 100 (e.g., the edge area of the electrode tip 100 or the area away from the first electrode 12) to become uncontrollable and deviate from the set temperature.

The panel 11 may have multiple operating areas. As will be understood, the electrode tip 100 can divide the panel 11 into multiple operating areas according to the dimensions of the panel 11 and the actual requirements. Illustratively, the panel 11 may be divided into 2-100 operating areas, for example, the panel 11 may have 2-20 operating areas.

As can be understood, the controller can control the operating state of each operating area of the panel 11. Each operating area of the panel 11 can operate independently. The facial beauty device 1000 may have multiple operating modes. According to the operating mode selected by the user, the multiple operating areas of the panel 11 may have similar or different operating states. For the treatment and care of the skin of different areas of the user's face, such as the facial fold area, the fine wrinkle area around the eyes, etc., the controller may control the corresponding operating area on the panel 11 to operate, and may further control the treatment temperature of the operating area in the operating state. In this way, it is helpful to improve the direction of treatment and care and improve the user experience. In addition, since the volume of the facial beauty device product is generally relatively small, the storage elements built into the facial beauty device 1000 are generally also relatively small, and the storage capacity is limited. In the present application, after managing the electrode chip 100 by area, some operating areas can be operated while the remaining operating areas are in a non-operating state, which helps to save power and extend the service life of the facial beauty device 1000.

In one embodiment, the panel 11 may have a track or elliptical shape. Multiple operating areas may be arranged along the length of the panel 11.

For example, the panel 11 may have a first motion area 111, a second motion area 112, and a third motion area 113 arranged along the length of the panel 11. In FIG. 2, the first motion area 111, the second motion area 112, and the third motion area 113 are typically distinguished from each other using dotted lines and hatching.

When the user's facial nasolabial folds need to be treated and cared for, the facial nasolabial fold area is relatively large, so the first operating area 111, the second operating area 112, and the third operating area 113 of the panel 11 can operate simultaneously to cover the entire facial nasolabial fold area of the user. When the user's facial wrinkles around the eyes need to be treated and cared for, the first operating area 111 and the third operating area 113 of the panel 11 can operate simultaneously, but the second operating area 112 may be in a non-operating state. In this way, when it is guaranteed that the fine lines around the eyes of the user's face can be treated and cared for, it not only improves the direction of treatment and care by the facial beauty device 1000, but also helps to save power and extend the service life of the facial beauty device 1000.

Figure 4 is a schematic diagram of the structure of another embodiment of the electrode tip 100 shown in Figure 2.

As shown in FIG. 4, the multiple motion areas may be arranged along the width direction of the panel 11. For example, the panel 11 may have a first motion area 111, a second motion area 112, and a third motion area 113 arranged along the width direction of the panel 11. In FIG. 4, the first motion area 111, the second motion area 112, and the third motion area 113 are typically distinguished from each other using dotted lines and hatching.

In another embodiment, the multiple operating areas may be arranged in an array. In yet another embodiment, at least one operating area may be arranged to surround further operating areas.

As shown in Figs. 2 and 3, each operating area of the panel 11 is provided with at least one first electrode 12. In this way, the first electrode 12 can be used to detect the temperature of the corresponding area, and the controller can control the operating temperature of the corresponding area. Compared with a solution in which the controller is used to control the operating temperature of the entire panel 11, the facial beauty device according to the embodiment of the present application has a relatively high temperature control accuracy of each operating area, and the treatment and care efficiency of the facial beauty device is relatively high.

For example, each operating area of the panel 11 may be provided with one first electrode 12. Each operating area of the panel 11 may have one first through-hole. The first through-hole may pass through the panel 11. The first electrode 12 may be fixed within the first through-hole.

In another embodiment, a plurality of first electrodes 12 may be provided in at least one operating area of the panel 11. The at least one operating area of the panel 11 may have a plurality of first through holes. The plurality of first electrodes 12 may be fixed in one-to-one correspondence within the first through holes.

Figure 5 is a local cross-sectional view of the electrode tip 100 at line A-A shown in Figure 2. Figure 6 is a local enlarged view of the electrode tip 100 at line B shown in Figure 5.

As shown in Figures 3, 5 and 6, the first electrode 12 may include an electrode body 121 and a temperature sensor 122.

For example, the electrode body 121 may include a head 1211 and a body 1212. The body 1212 of the electrode body 121 may be sleeve-shaped, that is, the body 1212 of the electrode body 121 has a hollow structure with openings at both ends, and the openings at both ends of the body 1212 communicate the internal space of the body 1212 with the outside. The head 1211 of the electrode body 121 is fixedly connected to one end of the body 1212, and the opening at one end of the body 1212 can be sealed. At least a part of the head 1211 of the electrode body 121 may be exposed from the panel 11 through the first through hole 114, and is for contacting the user's skin to detect the user's skin temperature and outputting a current to treat the user's skin.

In one embodiment, the material of the electrode body 121 may be a metal material. The electrode body 121 can be used to generate high-frequency energy by conducting electricity and heat to realize the treatment and care functions of the facial beauty device 1000.

For example, the material of the electrode body 121 may be a pure copper material. In this way, the electrode body 121 may have excellent thermal conductivity and the manufacturing cost is relatively low. In other embodiments, the material of the electrode body 121 may be other metal materials such as silver, copper-tungsten alloy, silver-tungsten alloy, stainless steel, etc.

As shown in Figures 5 and 6, the temperature sensor 122 may be attached to the internal space of the electrode body 121 and fixedly connected to the electrode body 121. The temperature sensor 122 can be used to detect the user's skin temperature.

For example, at least a portion of the temperature sensor 122 may be located in the internal space of the body portion 1212 of the electrode body 121 and fixedly connected to the head 1211 of the electrode body 121. When the head 1211 of the electrode body 121 contacts the user's skin, heat of the user's skin may be transferred to the head 1211 of the electrode body 121. The temperature sensor 122 can detect the user's skin temperature through the head 1211 of the electrode body 121.

For example, the temperature sensor 122 may include a detection portion 1221 and a connection portion 1222. The connection portion 1222 may be fixed to one end of the detection portion 1221. The other end of the detection portion 1221 may be fixed to the head portion 1211 of the electrode body 121, and the head portion 1211 of the electrode body 121 is used to detect the user's skin temperature when in contact with the user's skin.

Exemplarily, the temperature sensor 122 may be a negative temperature coefficient (NTC) thermistor. The thermistor has a relatively high sensitivity to temperature, which helps improve the accuracy of detecting the user's skin temperature, and is relatively low cost. In other embodiments, the temperature sensor 122 may employ other temperature measuring elements, such as other infrared temperature sensors.

In one embodiment, the facial beauty device 1000 may further include a thermally conductive rubber 123. The thermally conductive rubber 123 may be located in the internal space of the electrode body 121. The thermally conductive rubber 123 may be connected to the temperature sensor 122, the head 1211 and the body 1212 of the electrode body 121. As can be understood, the thermally conductive rubber 123 can be used to transfer heat from the electrode body 121 to the temperature sensor 122, and can be used to fix the temperature sensor 122 in the internal space of the electrode body 121.

For example, the thermally conductive rubber 123 may be installed between the detection unit 1221 of the temperature sensor 122 and the head 1211 of the electrode body 121. When the head 1211 of the electrode body 121 contacts the user's skin, heat from the user's skin is transferred to the head 1211 of the electrode body 121, and the thermally conductive rubber 123 can transfer the heat from the head 1211 of the electrode body 121 to the temperature sensor 122, thereby allowing the detection unit 1221 of the temperature sensor 122 to obtain more accurate information about the user's skin temperature.

For example, the thermally conductive rubber 123 may be further disposed between the detection portion 1221 of the temperature sensor 122 and the body portion 1212 of the electrode body 121. In this manner, the connection area between the temperature sensor 122 and the electrode body 121 can be increased, thereby making the connection between the temperature sensor 122 and the electrode body 121 more stable.

In one embodiment, the thermally conductive rubber 123 may be made of a resin having good thermal conductivity, such as epoxy resin, polyurethane, and thermally conductive silicone grease. In this way, the thermally conductive rubber 123 has good thermal conductivity and can reduce the influence of the temperature sensor 122 on the detection of the user's skin temperature, which helps to improve the accuracy of the temperature sensor 122 in detecting the user's skin temperature.

In one embodiment, the controller is electrically connected to the multiple first electrodes 12. The controller can be used to obtain detection values of the temperature sensors 122 of the first electrodes 12 in the multiple operating regions, and adjust the output energy of the electrode body 121 of the first electrodes 12 in the corresponding operating regions based on the detection values.

The first electrode 12 in each operating area can be used to detect the user's skin temperature and transmit the detected temperature information to the controller, so that the controller can control the operating temperatures of the multiple operating areas. In this way, the uniformity and accuracy of the operating temperature of each operating area of the electrode tip 100 is better during the treatment and care process.

For example, the controller can obtain the detection values of the temperature sensor 122 of the first electrode 12 in multiple operating regions, and then determine the relationship between the detection values and a predetermined threshold range of the facial beauty device.

When the detection value of the temperature sensor 122 of the first electrode 12 is within a predetermined threshold range of the facial beauty device 1000, the controller can control the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area on the panel 11 so as not to change. This can prevent the occurrence of a situation in which the temperature of the electrode tip 100 is too high and burns the user's skin.

When the detection value of the temperature sensor 122 of the first electrode 12 is lower than a predetermined threshold range of the facial beauty device 1000, the controller can increase the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area on the panel 11. In this way, it is possible to avoid the occurrence of a situation in which the output energy of the electrode tip 100 is insufficient to achieve a therapeutic effect.

When the detection value of the temperature sensor 122 of the first electrode 12 is higher than the predetermined threshold range of the facial beauty device 1000, the controller can reduce the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area on the panel 11. In this way, it is possible to avoid the occurrence of a situation in which the output energy of the electrode tip 100 is too high and burns the user's skin.

As shown in Figs. 3 and 5, the facial beauty device 1000 may further include at least one second electrode 13. The second electrode 13 is attached to at least one active area of the panel 11. One end of the second electrode 13 may be exposed from the panel 11 and is used to treat and care for the user's skin. The second electrode 13 may be installed at a distance from the first electrode 12.

As can be seen, the second electrode 13 can output energy to treat and care for the user's skin. The second electrode 13 may not include a temperature sensor 122, and its manufacturing cost may be lower than the manufacturing cost of the first electrode. By installing the second electrode 13, it is possible to contribute to the effect of treatment and care, and to reduce the number of first electrodes 12, thereby contributing to reducing the manufacturing cost of the facial beauty device 1000.

Exemplarily, at least one active area of the panel 11 may have at least one second through hole 115. The second through hole 115 may be spaced apart from the first through hole. The second electrode 13 may be mounted within the second through hole 115 of the panel 11 and may be partially exposed from the panel 11.

In one embodiment, each operating area of the panel 11 may be provided with a plurality of second electrodes 13. The plurality of second electrodes 13 in each operating area may be disposed surrounding the first electrode 12.

For example, each operating area of the panel 11 may have a plurality of second through holes 115. The plurality of second through holes 115 may be arranged to surround the first through hole. The plurality of second electrodes 13 may be attached in one-to-one correspondence within the plurality of second through holes 115.

In one embodiment, the controller is electrically connected to the second electrode 13. The controller may further be used to adjust the output energy of the second electrode 13 in the corresponding operating region based on the detected value.

In other embodiments, the facial beauty device 1000 may not include the second electrode 13. In this case, the electrode tip 100 outputs energy through multiple first electrodes 12.

As shown in Figures 3, 5 and 6, the electrode chip 100 may further include a circuit board 14. The circuit board 14 of the electrode chip 100 may be located on the opposite side of the panel 11 from the first electrode 12 and may be fixedly connected to the panel 11.

Exemplarily, the electrode chip 100 may further include a peripheral sidewall 15 around the connection panel 11. The panel 11 and the peripheral sidewall 15 may be an integrally molded structural member. The panel 11 and the peripheral sidewall 15 may enclose an accommodation space 116. The circuit board 14 may be mounted within the accommodation space 116 of the electrode chip 100. A portion of the first electrode 12 may be located within the accommodation space 116.

In one embodiment, the circuit board 14 may be electrically connected to the controller and the first electrode 12. The circuit board 14 may receive and convert control information from the controller and transmit the control information to the first electrode 12 so as to realize the control of the operating state of the first electrode 12 by the controller. The control information may include start information, stop information, power adjustment information, operating time information, etc. The operating state of the first electrode 12 may include information such as whether the first electrode 12 is operating, the output power of the first electrode 12, the operating temperature of the first electrode 12, and the operating time of the first electrode 12. The circuit board 14 may further receive and convert temperature information from the first electrode 12 and transmit the temperature information to the controller, and the controller may send control information to the circuit board 14 based on the temperature information of the first electrode 12 to control the operating state of the first electrode 12.

In one embodiment, the temperature sensor 122 of the first electrode 12 may be electrically connected to the circuit board 14. In this manner, the temperature sensor 122 can transmit the detected temperature information to the controller via the circuit board 14. The controller can receive the transmitted temperature signal from the circuit board 14 and control the output energy of the electrode tip 100 based on the temperature signal.

For example, one end of the connection portion 1222 of the temperature sensor 122 may be fixedly connected to the detection portion 1221, and the other end may extend from the internal space of the electrode body 121 and be used to electrically connect to the circuit board 14.

In one embodiment, the electrode body 121 of the first electrode 12 may be electrically connected to the circuit board 14. In this manner, the controller can control the operating state of the first electrode 12 by performing information conversion via the circuit board 14.

In one embodiment, the electrode tip 100 may further include a conductive spring 124. The conductive spring 124 may abut against the first electrode 12 and the circuit board 14.

For example, the outer wall of the body portion 1212 of the electrode body 121 may have a groove 1213. The groove 1213 may be surrounded along the circumferential direction of the body portion 1212. The groove 1213 may be provided at an end of the body portion 1212 away from the head portion 1211.

For example, the outer wall of the body portion 1212 of the electrode body 121 may include a first wall surface 1214 and a second wall surface 1215. The bottom wall of the groove 1213 is connected to the first wall surface 1214 and the second wall surface 1215. The first wall surface 1214 may be located on the side of the groove 1213 that is close to the circuit board 14. The second wall surface 1215 may be located on the side of the groove 1213 that is away from the circuit board 14.

For example, one end of the conductive spring 124 may be fitted into the first wall surface 1214 of the electrode body 121 and the bottom wall of the groove 1213, and may be tightly fitted into the first wall surface 1214 and the bottom wall of the groove 1213.

As shown in Figures 3, 5 and 6, a plurality of first pads 141 may be provided on the circuit board 14. The plurality of first pads 141 may be provided on the side of the circuit board 14 facing the panel 11. The plurality of first pads 141 may be installed facing the plurality of first electrodes 12 in one-to-one correspondence. The other end of the conductive spring 124 may contact the first pad 141 on the circuit board 14 and be electrically connected.

Exemplarily, the conductive spring 124 may be in a compressed state. In this manner, the conductive spring 124 may abut against the first electrode 12 and the circuit board 14 by its elasticity. The conductive spring 124 may be held in contact with pads on the first electrode 12 and the circuit board 14, thereby making the electrical connection between the first electrode 12 and the circuit board 14 more stable.

By way of example, the material of the conductive spring 124 may be stainless steel. In other embodiments, the material of the conductive spring 124 may be other materials with good conductive properties.

In one embodiment, the circuit board 14 may be provided with a plurality of limiting grooves (not shown). The openings of the limiting grooves may be located on the side of the circuit board 14 facing the panel 11. The plurality of limiting grooves may correspond one-to-one to the plurality of first through holes of the panel 11. The other end of the conductive spring 124 may extend into the limiting groove of the circuit board 14. As can be understood, the limiting groove of the circuit board 14 can limit the conductive spring 124 to move along the length and width directions of the circuit board 14 relative to the circuit board 14, making it difficult for the conductive spring 124 to be detached from the circuit board 14, thereby making the connection between the first electrode 12 and the circuit board 14 more stable.

For example, the first pad 141 of the circuit board 14 may be provided on the bottom wall of the limiting groove, and the conductive spring 124 may be in contact with and electrically connected to the first pad 141.

In one embodiment, the second electrode 13 may be electrically connected to the circuit board 14. The circuit board 14 may receive and convert control information from the controller and transmit the control information to the second electrode 13, thereby enabling the controller to control the operating state of the second electrode 13. The operating state of the second electrode 13 may include information such as whether the second electrode 13 is operating, the output power of the second electrode 13, the operating temperature of the second electrode 13, and the operating time of the second electrode 13.

For example, one end of the second electrode 13 may be exposed from the panel 11, and the other end may abut the circuit board 14.

For example, a second pad (not shown) may be provided on the circuit board 14. The second pad may be provided on the side of the circuit board 14 facing the panel 11. The second pad may be installed at a distance from the first pad 141. The second pad may be installed opposite to correspond to the second electrode 13. The other end of the second electrode 13 may contact the second pad of the circuit board 14.

Figure 7 is a schematic diagram of the local structure of the fuselage 200 shown in Figure 1.

As shown in FIG. 7, the facial beauty device 1000 may further include an exchange component 22. The exchange component 22 is electrically connected to the controller. The controller is used to receive exchange information emitted by the exchange component 22 and control the operating state of the first electrode 12 in at least one operating region based on the exchange information.

Exemplarily, the replacement component 22 may be attached to the housing 21. A portion of the replacement component 22 may be exposed from the housing 21, and another portion may be located inside the housing 21 so as to be electrically connected to the controller. The user can control the operating state of the electrode chip 100 of the facial beauty device 1000 by the replacement component 22, thereby realizing the replacement function inside and outside the facial beauty device 1000.

In one embodiment, the replacement information may include start and stop information. The user can control the start and stop of the facial beauty device 1000 via the replacement component 22.

In another embodiment, the replacement information may further include step adjustment information and/or mode selection information, etc. The user can select the operation mode of the facial beauty device 1000 by the replacement component 22. The controller can control the first electrode 12 in at least one of the multiple operation areas based on the mode selection information to output energy.

For example, the replacement component 22 may be a button or a touch panel. The user can select the operation mode of the facial beauty device 1000 by pressing the button or touching the touch panel. After the user selects the operation mode, the replacement component 22 transmits mode selection information to the controller, and the controller receives the mode selection information and controls the first electrode 12, or the first electrode 12 and the second electrode 13, in the corresponding operation area on the panel 11 based on the mode selection information to output energy.

In one embodiment, the mode selection information may include first information and second information. The facial beautifying device 1000 may include a first operating mode and a second operating mode. The facial beautifying device 1000 may execute the first operating mode based on the first information, or execute the second operating mode based on the second information. Exemplarily, the first information may be nasolabial fold treatment and care information. The first operating mode may be a nasolabial fold treatment and care mode. The second information may be fine line treatment and care information. The second operating mode may be a fine line treatment and care mode.

For example, the beauty device 1000 may have a first operating area 111, a second operating area 112, and a third operating area 113 arranged along the length direction of the panel 11. When the mode selection information is the first information, i.e., nasolabial fold treatment and care information, the beauty device 1000 may start the first operating mode, i.e., the nasolabial fold care and treatment mode. The controller can control the first electrode 12 in the first operating area 111, the second operating area 112, and the third operating area 113 to output energy. At this time, the treatment and care area of the electrode tip 100 is relatively large, and the first operating area 111, the second operating area 112, and the third operating area 113 of the beauty device 1000 can be used to treat and care for nasolabial folds that occupy a relatively large area of the face. When the mode selection information is the second information, i.e., fine wrinkle treatment and care information, the beauty device 1000 may start the second operating mode, i.e., the fine wrinkle care and treatment mode. The controller can control the first electrodes 12 in the first and third operating areas 111 and 113 to output energy. At this time, the first and third operating areas 111 and 113 of the facial massager 1000 can be used to treat and care for fine lines that occupy a relatively small area of the face (e.g., around the eyes). The second operating area 112 can be in a non-operating state, which helps to reduce power consumption and extend the service life of the facial massager 1000.

In other embodiments, the mode selection information may include two or more pieces of information. The facial beauty device 1000 may have two or more operating modes. The facial beauty device 1000 may execute a corresponding operating mode based on each piece of information in the mode selection information.

In one embodiment, the user can further select an operating stage of the facial beauty device 1000 by the replacement component 22. The controller can further adjust the magnitude of the output energy of the first electrode 12 in the operating state based on the stage selection information.

For example, the user can select the operation stage of the facial beauty device 1000 by pressing a button or touching a touch panel. When the user selects an operation stage, the replacement component 22 transmits stage adjustment information to the controller, and the controller receives the stage adjustment information and adjusts the magnitude of output energy of the first electrode 12, or the first electrode 12 and the second electrode 13, which are in an operating state on the panel 11, based on the stage adjustment information.

In one embodiment, each operating mode of the facial beauty device 1000 may include 2 to 30 stages. For example, each operating mode of the facial beauty device 1000 may have three stages.

As shown in FIG. 7, the facial beauty device 1000 may further include a display screen 23. The display screen 23 may be attached to the housing 21 of the facial beauty device 1000. The display screen 23 can be used to indicate the operating mode of the electrode tip 100.

For example, the display screen 23 may include multiple display areas. The multiple display areas have the same arrangement rules as the multiple operating areas on the panel 11 and correspond one-to-one. As will be understood, the multiple display areas having the same arrangement rules as the multiple operating areas on the panel 11 means that the number of display areas on the display screen 23 is the same as the number of operating areas on the panel 11, and the relative positions between the multiple display areas on the display screen 23 are the same as the relative positions between the multiple operating areas, but the shape and dimensions of the display screen 23 do not need to be strictly the same as the shape and dimensions of the panel 11.

Exemplarily, the shape of the display screen 23 may be a track type or an ellipse. The display screen 23 may include a first display area 231, a second display area 232, and a third display area 233 arranged along the length direction of the display screen 23. The first display area 231, the second display area 232, and the third display area 233 may correspond one-to-one according to the same arrangement rule as the first motion area 111, the second motion area 112, and the third motion area 113 on the panel 11. For example, the first display area 231 may correspond to the first motion area 111 on the panel 11. The second display area 232 may correspond to the second motion area 112 on the panel 11. The third display area 233 may correspond to the third motion area 113 on the panel 11.

In other embodiments, the shape of the display screen 23 may be rectangular, circular, or other shapes. This application is not specifically limited in this respect.

In one embodiment, the display screen 23 is electrically connected to the controller. The controller can also be used to light up the corresponding display area on the display screen 23 when the first electrode 12 in at least one operating area of the panel 11 is operating. For example, when the facial beauty device 1000 starts the care and treatment mode for nasolabial folds, the first display area 231, the second display area 232, and the third display area 233 of the display screen 23 are lit up when the first operating area 111, the second operating area 112, and the third operating area 113 of the panel 11 are in an operating state. And when the facial beauty device 1000 starts the care and treatment mode for fine wrinkles, the first display area 231 and the third display area 233 of the display screen 23 are lit up when the first operating area 111 and the third operating area 113 of the panel 11 are in an operating state. In this way, the user can directly observe the treatment and care area currently in the operating state of the facial beauty device 1000 through the display screen 23, which makes it easy for the user to select the treatment and care area that suits him/her, and helps to improve the user experience.

In one embodiment, the facial beautifying device 1000 may further include an indicator member. The indicator member can be used to indicate the current operation stage of the facial beautifying device 1000. The indicator member is electrically connected to the controller. The controller can also be used to control the operation state of the indicator member. As can be understood, when the controller adjusts the magnitude of the output energy of the first electrode 12 in the operation state based on the stage adjustment information, the indicator member can be further controlled to adjust the displayed stage indication information. In this way, the user can directly observe the current energy output status of the facial beautifying device 1000, which makes it easy for the user to select an operation stage that suits him/her, and helps to improve the user experience.

In one embodiment, the indicator member may be an indicator lamp. The controller may control the number of times the indicator lamp is illuminated based on the step adjustment information.

Exemplarily, the indicator lights may be three in number and may be used to indicate three operational stages of the electrode tip 100. In other embodiments, the number of indicator lights may be two or may be greater than three.

In other embodiments, the facial beauty device 1000 may not have an indicator. In this case, the display screen 23 of the facial beauty device 1000 may be used to indicate the current operation stage of the electrode tip 100. The controller may control the display information of the display screen 23 based on the stage adjustment information.

Referring to FIG. 1, and also as shown in FIG. 7, the housing 21 of the body 200 may have an opening 211 and an internal cavity 212. The electrode tip 100 may be attached to the opening 211 of the body 200. The peripheral side wall 15 of the electrode tip 100 may be engaged with the housing 21.

In one embodiment, the facial beauty device 1000 may further include a sealing ring (not shown). The sealing ring can hermetically connect the electrode tip 100 and the housing 21. As can be understood, by the sealing ring hermetically connecting the electrode tip 100 and the housing 21, it is possible to eliminate a gap between the electrode tip 100 and the housing 21. In this way, it is possible to prevent external dust or water vapor from entering the inside of the electrode tip 100 through the gap between the electrode tip 100 and the housing 21 and affecting the performance of the facial beauty device 1000.

For example, the sealing ring may be fitted to the outside of the peripheral sidewall 15 of the electrode tip 100. When the electrode tip 100 is attached to the housing 21, the sealing ring may be located between the peripheral sidewall 15 of the electrode tip 100 and the inner wall of the housing 21.

For example, the sealing ring may be made of a sealing soft rubber, etc.

Figure 8 is a schematic diagram showing the operating principle of the facial beauty device 1000 shown in Figure 1.

As shown in FIG. 8, the exchange component 22 of the facial beauty device 1000 can obtain operation information and transmit exchange information to the controller based on the operation information, where the exchange information includes mode selection information and/or stage selection information. The operation information is information generated by the exchange component 22 in response to a user's operation.

The controller receives the exchange information emitted by the exchange component 22 and transmits control information to the first electrode 12, or the first electrode 12 and the second electrode 13, thereby controlling the operating state of the first electrode 12, or the first electrode 12 and the second electrode 13, in the corresponding operating area on the panel 11.

If the exchange information is mode selection information, the controller controls the first electrode 12, or the first electrode 12 and the second electrode 13, in the corresponding operating area on the panel 11 to output energy. At the same time, the controller transmits display information to the display screen 23 to light up the corresponding display area on the display screen 23. In this way, the user can directly observe the treatment and care area currently in the operating state of the facial beauty device 1000 through the display screen 23, which facilitates the user to select the treatment and care area that suits them, and helps to improve the user experience.

If the exchange information is stage selection information, the controller adjusts the magnitude of the output energy of the first electrode 12, or the first electrode 12 and the second electrode 13, in the corresponding operating area on the panel 11. At the same time, it adjusts the stage display information on the display screen 23 or controls the number of lit up indicators by sending display information to the display screen 23 or the indicator. In this way, the user can directly observe the current energy output status of the facial beauty device 1000, which facilitates the user to select the treatment and care stage that suits them, and helps to improve the user experience.

Figure 9 is a schematic diagram showing the process of the control method for the facial beauty device 1000 according to an embodiment of the present application.

As shown in FIG. 9, the control method for the facial beauty device 1000 may be applied to the facial beauty device 1000 shown in FIG. 1. The control method for the facial beauty device 1000 may include the following steps S10 and S20.

Step S10: The controller acquires the detection values of the temperature sensor 122 of the first electrode 12 in multiple operating regions.

Step S20: The controller adjusts the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area based on the detected value. According to the control method of the facial beauty device 1000 of the embodiment of the present application, the controller can control the output energy of the first electrode 12 in each operating area on the panel 11, improving the temperature uniformity of the electrode tip 100, and making it less likely that the temperature of a part of the electrode tip 100 (e.g., the edge area of the electrode tip 100 or an area away from the first electrode 12) will become uncontrollable and deviate from the set temperature.

Exemplarily, step S20 may further include judging the relationship between the detection value of the temperature sensor 122 and a predetermined threshold range of the facial beauty device. If the detection value is within the threshold range, step S201 is executed to control the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area so as not to change. If the detection value is lower than the threshold range, step S202 is executed to increase the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area. In this way, it is possible to avoid the occurrence of a situation in which the output energy of the electrode tip 100 is insufficient and the therapeutic effect cannot be achieved. If the detection value is higher than the threshold range, step S203 is executed to reduce the output energy of the electrode body 121 of the first electrode 12 in the corresponding operating area. In this way, it is possible to avoid the occurrence of a situation in which the output energy of the electrode tip 100 is too high and burns the skin of the user. Figure 10 is a schematic diagram showing a process in another embodiment of the control method of the facial beauty device 100 shown in Figure 9.

As shown in FIG. 10, the control method for the facial beauty device 1000 may further include the following step S30.

Step S30: The controller receives the exchange information emitted by the exchange component 22. The controller controls the operating state of the first electrode 12 in at least one operating area on the panel 11 based on the exchange information.

Exemplarily, the exchange information may include mode selection information and/or stage selection information. Step S30 may further include the following two sub-steps.
The controller controls the output energy of the first electrode 12 in at least one of the plurality of operating regions on the panel 11 based on the mode selection information. The controller adjusts the magnitude of the output energy of the first electrode 12 in an operating state based on the stage selection information.

For example, the replacement component 22 may be a button or a touch panel. The user can select the operation mode of the facial beauty device 1000 by pressing the button or touching the touch panel. After the user selects the operation mode, the replacement component 22 transmits mode selection information to the controller, and the controller receives the mode selection information and controls the first electrode 12 in the corresponding operation area on the panel 11 to output energy based on the mode selection information. The user can further select the operation stage of the facial beauty device 1000 by pressing the button or touching the touch panel. When the user selects the operation stage, the replacement component 22 transmits stage adjustment information to the controller, and the controller receives the stage adjustment information and adjusts the magnitude of the output energy of the first electrode 12 in the operation state on the panel 11 based on the stage adjustment information.

According to the control method of the facial beauty device 1000 according to the embodiment of the present application, the controller can independently control the output energy of the first electrode 12 in each operating area of the panel 11. The facial beauty device 1000 may have multiple operating modes. According to the operating mode selected by the user, the output energy of the first electrode 12 in the multiple operating areas of the panel 11 may be the same or different. For the treatment and care of the skin in different areas of the user's face, such as the facial nasolabial fold area, the fine wrinkle area around the eyes, etc., the controller can control the first electrode 12 in the corresponding operating area on the panel 11 to output energy. In this way, it is possible to improve the direction of treatment and care, and to improve the user experience. In addition, since the volume of a facial beauty device product is generally relatively small, the storage element built into the facial beauty device 1000 is also generally relatively small, and the storage capacity is limited. According to the control method of the facial beauty device 1000 according to the embodiment of the present application, the first electrodes 12 in some operating areas can be controlled to output energy, but the first electrodes 12 in the remaining operating areas can be controlled not to output energy, thereby saving power and helping to extend the service life of the facial beauty device 1000.

In one embodiment, the mode selection information may include a first operating mode and a second operating mode. The facial beauty device 1000 may execute the first operating mode based on the first information, or execute the second operating mode based on the second information. Exemplarily, the first information may be nasolabial fold treatment and care information. The first operating mode may be a nasolabial fold treatment and care mode. The second information may be fine line treatment and care information. The second operating mode may be a fine line treatment and care mode.

For example, the beauty device 1000 may have a first operating area 111, a second operating area 112, and a third operating area 113 arranged along the length direction of the panel 11. When the mode selection information is the first information, i.e., nasolabial fold treatment and care information, the beauty device 1000 may start the first operating mode, i.e., the nasolabial fold care and treatment mode. The controller controls the first electrode 12 in the first operating area 111, the second operating area 112, and the third operating area 113 to output energy. At this time, the treatment and care area of the electrode tip 100 is relatively large, and the first operating area 111, the second operating area 112, and the third operating area 113 of the beauty device 1000 can be used to treat and care for nasolabial folds that occupy a relatively large area of the face. When the mode selection information is the second information, i.e., fine wrinkle treatment and care information, the beauty device 1000 may start the second operating mode, i.e., the fine wrinkle care and treatment mode. The controller controls the first electrodes 12 in the first and third operating areas 111 and 113 to output energy. At this time, the first and third operating areas 111 and 113 of the facial massager 1000 can be used to treat and care for fine lines that occupy a relatively small area of the face (e.g., around the eyes). The second operating area 112 can be in a non-operating state, which helps to reduce power consumption and extend the service life of the facial massager 1000.

In other embodiments, the mode selection information may include two or more pieces of information. The facial beauty device 1000 may have two or more operating modes. The facial beauty device 1000 may execute a corresponding operating mode based on each piece of information in the mode selection information.

The control method of the facial beauty device 1000 according to the embodiment of the present application may further include triggering step S10 after step S30. Illustratively, the controller may respond to the exchange information, and after enabling the facial beauty device 1000 to start the corresponding operation mode and operation stage, the controller may further obtain the detection values of the temperature sensor 122 of the first electrode 12 in multiple operation regions. In some embodiments, the control method of the facial beauty device 1000 may further include the following step S40.

Step S40: If the first electrode 12 in at least one operating area on the panel 11 is operating, the controller lights up the corresponding display area on the display screen 23.

In one embodiment, the display screen 23 may include a first display area 231, a second display area 232, and a third display area 233 arranged along the length direction of the display screen 23. The first display area 231, the second display area 232, and the third display area 233 may correspond one-to-one to the arrangement rules of the first operating area 111, the second operating area 112, and the third operating area 113 on the panel 11. When the facial beauty device 1000 starts the care and treatment mode for nasolabial folds and the controller controls the first operating area 111, the second operating area 112, and the third operating area 113 to be in an operating state, the first display area 231, the second display area 232, and the third display area 233 of the display screen 23 are lit up. Then, when the facial beauty device 1000 starts the fine wrinkle care and treatment mode and the first operating area 111 and the third operating area 113 of the panel 11 are in an operating state, the first display area 231 and the third display area 233 of the display screen 23 are lit up. In this way, the user can directly observe the treatment and care areas that are currently in the operating state of the facial beauty device 1000 through the display screen 23, making it easier for the user to select an operating mode that suits them, and helping to improve the user experience.

In some embodiments, the control method of the facial beauty device 1000 includes:
The method may further include a step S50 in which the controller controls the operating state of the indicating member based on the stage selection information.

Exemplarily, the indicator member may be an indicator lamp. The controller may control the number of indicator lamps that are illuminated based on the step adjustment information.

For example, the display screen of the facial beauty device 1000 may be the indication member. The controller can adjust the stage indication information on the display screen based on the stage adjustment information.

In one embodiment, the facial beauty device 1000 may further include at least one second electrode 13. The second electrode 13 is attached to at least one active area of the panel 11. One end of the second electrode 13 may be exposed from the panel 11 and is used to treat and care for the user's skin. The second electrode 13 may be installed at a distance from the first electrode 12.

Step S30 may further include the controller receiving the exchange information emitted by the exchange component 22. The controller controls the operating state of the second electrode 13 of at least one operating area on the panel 11 based on the exchange information.

Exemplarily, the exchange information may include mode selection information and/or stage selection information. The controller may control the second electrode 13 of at least one of the multiple operating areas on the panel 11 based on the mode selection information to output energy. The controller may adjust the magnitude of the output energy of the second electrode 13 in an operating state based on the stage selection information. For a specific method of controlling the second electrode 13, refer to the method of controlling the first electrode 12 in step S30 above, and a detailed description thereof will be omitted here.

Note that the steps of the above control method are not fixed, and the steps shown in Figures 9 and 10 may be increased, decreased, or replaced according to actual needs.

In addition, unless there is a conflict, the embodiments and features of the embodiments of the present application can be combined with each other, and any combination of features of different embodiments is also included in the scope of protection of the present application, that is, the multiple embodiments described above can further be arbitrarily combined according to actual needs.

Note that all of the above figures are illustrative illustrations of the present application and do not represent the actual size of the product. Furthermore, the dimensional ratios between the core components in the drawings do not limit the actual product of the present application.

The above description is merely a specific embodiment of the present application, but the scope of protection of the present application is not limited thereto, and any modifications or replacements that a person skilled in the art can easily conceive within the technical scope disclosed in the present application should be included in the scope of protection of the present application. Therefore, the scope of protection of the present application should be in accordance with the scope of protection of the above claims.

Claims (12)

A facial beauty device,
a panel having a plurality of active areas;
Each of the active regions is provided with at least one first electrode, each of the first electrodes includes an electrode body and a temperature sensor, the temperature sensor is attached to the inner space of the electrode body, and a plurality of first electrodes are fixedly connected to the electrode body;
a controller electrically connected to the first electrodes, acquiring detection values of the temperature sensors of the first electrodes in the operating regions, and adjusting output energy of the electrode bodies of the first electrodes in the operating regions based on the detection values ;
The facial beauty device further comprises a replacement component electrically connected to the controller, wherein the controller receives replacement information emitted by the replacement component and controls the operational state of the first electrode in at least one of the operating areas based on the replacement information . a panel having a plurality of active areas;
Each of the active regions is provided with at least one first electrode, each of the first electrodes includes an electrode body and a temperature sensor, the temperature sensor is attached to the inner space of the electrode body, and a plurality of first electrodes are fixedly connected to the electrode body;
a controller electrically connected to the first electrodes, acquiring detection values of the temperature sensors of the first electrodes in the operating regions, and adjusting output energy of the electrode bodies of the first electrodes in the operating regions based on the detection values;
The facial beauty device further includes a housing and a display screen, the display screen is attached to the housing, the display screen includes a plurality of display areas, and the arrangement rules of the plurality of display areas and the plurality of operating areas are the same and correspond one-to-one;
A facial beauty device characterized in that the controller is mounted inside the housing, the display screen is electrically connected to the controller, and the controller is also used to light up the corresponding display area when the first electrode in at least one of the operating areas is operating. A facial beauty device,
a panel having a plurality of active areas;
Each of the active regions is provided with at least one first electrode, each of the first electrodes includes an electrode body and a temperature sensor, the temperature sensor is attached to the inner space of the electrode body, and a plurality of first electrodes are fixedly connected to the electrode body;
a controller electrically connected to the first electrodes, acquiring detection values of the temperature sensors of the first electrodes in the operating regions, and adjusting output energy of the electrode bodies of the first electrodes in the operating regions based on the detection values;
the first electrode has a head and a body, the body has a sleeve shape, the head is fixedly connected to one end of the body, at least a portion of the head is exposed from the panel, the temperature sensor is located in an internal space of the body and fixedly connected to the head ,
The facial beauty device further comprises a heat conductive rubber located in the internal space of the electrode body and connected to the head, the temperature sensor and the main body . The facial beauty device further includes at least one second electrode, the second electrode is attached to at least one of the operating areas, one end of the second electrode is exposed from the panel, and the second electrode is disposed at a distance from the first electrode;
The facial beauty device of any one of claims 1, 2 or 3, characterized in that the controller is electrically connected to the second electrode and is also used to adjust the output energy of the second electrode in the corresponding operating area based on the detection value. A plurality of the operating areas are arranged along the length or width of the panel; or
A plurality of the active areas are arranged in an array, or
4. The facial beauty device according to claim 1, 2 or 3, wherein at least one of the operating areas is arranged to surround another of the operating areas. The facial beauty device according to any one of claims 1, 2 or 3, further comprising an indicating member electrically connected to the controller, the controller further controlling the operating state of the indicating member. A method for controlling a facial beauty device, comprising:
The facial beauty device includes a panel, a plurality of first electrodes, and a controller, the panel has a plurality of operating areas, each of the operating areas is provided with at least one of the first electrodes, each of the first electrodes includes an electrode body and a temperature sensor, the temperature sensor is attached to the inner space of the electrode body and fixedly connected to the electrode body, and the controller is electrically connected to the plurality of first electrodes;
The control method includes:
The controller acquires detection values of a temperature sensor of a first electrode in a plurality of operating regions;
and the controller adjusting an output energy of the electrode body of the first electrode in the corresponding operating region based on the detected value ;
The facial beauty device further comprises a housing and a display screen, the display screen being attached to the housing;
The display screen includes a plurality of display areas, and the plurality of display areas correspond to the plurality of action areas in a one-to-one manner according to the same arrangement rule;
the controller is located within the housing, the display screen is electrically connected to the controller;
The control method includes:
The method for controlling a facial beauty device further comprises, when the first electrode in at least one operating area operates, the controller lights up the corresponding display area . A method for controlling a facial beauty device, comprising:
The facial beauty device includes a panel, a plurality of first electrodes, and a controller, the panel has a plurality of operating areas, each of the operating areas is provided with at least one of the first electrodes, each of the first electrodes includes an electrode body and a temperature sensor, the temperature sensor is attached to the inner space of the electrode body and fixedly connected to the electrode body, and the controller is electrically connected to the plurality of first electrodes;
The control method includes:
The controller acquires detection values of a temperature sensor of a first electrode in a plurality of operating regions;
and the controller adjusting an output energy of the electrode body of the first electrode in the corresponding operating region based on the detected value;
The facial beauty device further includes a replacement component electrically connected to the controller,
The control method includes:
receiving, by the controller, exchange information originating from the exchange component;
The method of claim 1, further comprising: the controller controlling an operational state of the first electrode in at least one operational region based on the exchanged information. The exchange information includes mode selection information and/or stage selection information;
the controller controls a first electrode output energy in at least one of the plurality of operating regions based on the mode selection information;
The method of claim 8 , wherein the controller adjusts the magnitude of the output energy of the first electrode in an operating state based on the step selection information. The facial beauty device includes a first operating area, a second operating area, and a third operating area arranged along a length direction of the panel,
When the mode selection information is first information, the controller controls the first electrode in the first operating area, the second operating area, and the third operating area to output energy;
The method of claim 9 , wherein when the mode selection information is the second information, the controller controls the first electrodes in the first operating area and the third operating area to output energy. The facial beauty device further includes a pointing member electrically connected to the controller,
The control method includes:
The method of claim 9 , further comprising: controlling an operating state of the indicating member by the controller based on the step selection information. The controller adjusts the output energy of the electrode body of the first electrode in the corresponding operating region based on the detected value,
determining a relationship between the detected value and a threshold range;
When the detection value is within the threshold range, controlling the output energy of the electrode body of the first electrode in the corresponding operating region so as not to change;
increasing an output energy of an electrode body of the first electrode in the corresponding operating region when the detected value is lower than the threshold range;
The control method for a facial beauty device according to claim 7 or 8, further comprising: reducing the output energy of the electrode body of the first electrode in the corresponding operating area when the detection value is higher than the threshold range.