CN215961000U - Massage mechanism and massage device - Google Patents

Abstract

The application discloses massage mechanism and massage device relates to massage technical field. The massage device includes the device body and installs massage mechanism on the device body, massage mechanism includes: a first actuation assembly mounted to the device body, the first actuation assembly having a first actuation direction; a second actuating assembly mounted to an output of the first actuating assembly, the second actuating assembly having a second actuating direction different from the first actuating direction; and a massage member mounted to an output of the second actuating assembly. The driving method of the massager can realize a complex massage mode.

Description

Massage mechanism and massage device

Technical Field

The application relates to the technical field of massage, in particular to an actuating massage mechanism and a massage device.

Background

In general, a portable massage apparatus, such as a cervical vertebra massage apparatus, an eye massage apparatus, a waist massage apparatus, a wrist strap type massage apparatus, or a massage pad, implements physical massage by linear motion of a linear motor.

However, the existing massage instrument has the technical problem of single massage mode.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present application provides a massage mechanism and a massage device to solve the above technical problems.

In order to achieve the above object, the present application provides a massage apparatus including an apparatus body and a massage mechanism mounted on the apparatus body, the massage mechanism including:

a first actuating assembly mounted to the device body, the first actuating assembly having a first actuating direction;

a second actuating assembly mounted to the output end of the first actuating assembly, the second actuating assembly having a second actuating direction different from the first actuating direction; an included angle between the second actuating direction and the first actuating direction is greater than or equal to 10 degrees and less than or equal to 170 degrees; and

a massage member mounted to an output of the second actuating assembly.

Optionally, the massage mechanism further includes a first connecting member, the first connecting member has a first mounting surface and a second mounting surface, an included angle between the first mounting surface and the second mounting surface is greater than 0 degree, the first mounting surface is connected with an output end of the first actuating assembly, and the second actuating assembly is mounted on the second mounting surface, so that the first actuating direction is different from the second actuating direction.

Optionally, the first connecting piece is a first connecting block, and the first mounting surface and the second mounting surface are two adjacent side surfaces of the first connecting block respectively.

Optionally, a mounting groove is formed on the second mounting surface, and the second actuating assembly is mounted at the bottom of the mounting groove.

Optionally, the first connecting piece comprises a first connecting plate and a second connecting plate which intersect with each other, the side of the first connecting plate facing the first actuating assembly is the first mounting surface, the second connecting plate is located on one side of the first actuating assembly, and the side of the second connecting plate far away from the actuating centerline of the first actuating assembly is the second mounting surface.

Optionally, the first connecting plate and the second connecting plate are rotatably connected such that an angle between the second actuating direction and the first actuating direction is adjustable.

Optionally, the second actuating assembly is located on an actuating track of the first actuating assembly, the massage mechanism further includes an output conversion member, the output conversion member is mounted at an output end of the second actuating assembly, the output conversion member includes a power output portion located on a side of the second actuating assembly far away from the first actuating assembly, and the massage member is mounted at the power output portion.

Optionally, the massage mechanism further comprises a first connecting member, the first connecting member comprises a first connecting plate and a second connecting plate which are connected, the first connecting plate is mounted at the output end of the first actuating assembly, the second connecting plate extends towards one side of the first connecting plate far away from the first actuating assembly, and the second actuating assembly is mounted on the second connecting plate, so that the second actuating assembly is located on the actuating track of the first actuating assembly.

Optionally, the massage mechanism further includes a third actuating assembly and a second connecting member, the second connecting member includes a third connecting plate and a fourth connecting plate connected to each other, the third connecting plate is mounted at an output end of the third actuating assembly, the fourth connecting plate extends toward a side of the third connecting plate facing the third actuating assembly, the first actuating assembly is mounted at a side of the fourth connecting plate away from the third actuating assembly, and the third actuating assembly is mounted at the device body.

Optionally, an angle between the second actuation direction and the first actuation direction is greater than or equal to 60 degrees and less than or equal to 120 degrees.

Optionally, the first actuation assembly is a flexible actuation assembly for actuation by deformation to have a first actuation direction; and/or the presence of a gas in the gas,

the second actuating assembly is a flexible actuating assembly and is used for being actuated through deformation to have a second actuating direction.

Optionally, the flexible actuating assembly is an electric actuating assembly, the electric actuating assembly includes at least one electric actuating unit arranged in a stacked manner, the electric actuating unit includes an electro-deformable layer and electrodes arranged in a stacked manner, the electro-deformable layer is provided with a plurality of layers, two sides of each electro-deformable layer are provided with one electrode, and two adjacent electro-deformable layers share the same electrode; the electrodeformation layer is used for generating deformation when an electric field is applied so as to enable the electric actuating component to have an actuating direction, and two adjacent electrodes are used for forming the electric field; alternatively, the first and second electrodes may be,

the flexible actuating assembly is a photoinduced assembly, the photoinduced assembly comprises at least one photoinduced actuating unit which is arranged in a stacked mode, the photoinduced actuating unit comprises a photoinduced shell, a light source and a photoinduced film, a photoinduced hole is formed in the photoinduced shell, the photoinduced film is arranged at the photoinduced hole, the light source is arranged in the photoinduced shell, and the photoinduced film is used for deforming when being irradiated by the light source so as to enable the photoinduced assembly to have an actuating direction; alternatively, the first and second electrodes may be,

the flexible actuating assembly is an air actuating assembly which comprises at least one air actuating bag arranged in a stacked mode, and the air actuating bag is used for deforming when being inflated so that the air actuating assembly has an actuating direction.

Optionally, the skin-proximal side of the device body has a receiving groove, and the first actuation component is mounted to a bottom or a side wall of the receiving groove.

Optionally, the massage device is a portable massage device.

Optionally, the massage device is a cervical vertebra massage device, or a waist massage device, or a wrist strap massage device, or a massage cushion, or an eye massage device.

Optionally, the massage mechanism further comprises a third actuating assembly, the third actuating assembly is mounted to the device body, the first actuating assembly is mounted to an output end of the third actuating assembly, the third actuating assembly has a third actuating direction, and the first actuating direction, the second actuating direction and the third actuating direction are all different.

Optionally, at least any two of the first actuation direction, the second actuation direction, and the third actuation direction are perpendicular to each other.

Optionally, the device body includes an outer shell and a flexible inner shell connected to the outer shell, the outer shell and the flexible inner shell enclose to form an installation cavity, the massage mechanism is installed in the installation cavity, the first actuating component is installed on the outer shell, and the massage member penetrates through the flexible inner shell.

Optionally, an annular elastic telescopic portion is formed on the flexible inner shell, the massage member penetrates through the elastic telescopic portion, and an inner edge of the elastic telescopic portion is connected to the massage member or the second actuating assembly.

Optionally, a plurality of massage mechanisms are distributed on the device body at intervals, and the first actuating directions of the first actuating groups of at least two massage mechanisms are different; and/or

The massage mechanism further comprises a sensor, the sensor is mounted on the massage piece, and the sensor is used for detecting massage parameters of the massage piece; and/or

The massage member is integral with the output end of the second actuating assembly.

In order to solve the above technical problem, the present application further provides a massage mechanism, including:

a first actuation assembly having a first actuation direction;

a second actuating assembly mounted to an output of the first actuating assembly, the second actuating assembly having a second actuating direction different from the first actuating direction; an included angle between the second actuating direction and the first actuating direction is greater than or equal to 10 degrees and less than or equal to 170 degrees; and

a massage member mounted to an output of the second actuating assembly.

Optionally, the first actuation assembly is a flexible actuation assembly for actuation by deformation to have a first actuation direction; and/or the second actuating assembly is a flexible actuating assembly, and the second actuating assembly is used for being actuated through deformation to have a second actuating direction; and/or the presence of a gas in the gas,

the actuating device further comprises a third actuating assembly, the first actuating assembly is mounted at the output end of the third actuating assembly, the third actuating assembly has a third actuating direction, and the first actuating direction, the second actuating direction and the third actuating direction are different; and/or

The massage mechanism further comprises a sensor, the sensor is mounted on the massage piece, and the sensor is used for detecting massage parameters of the massage piece; and/or

The massage member is integral with the output end of the second actuating assembly.

Has the advantages that: be different from prior art, this application is installed in the output of first actuating assembly through setting up the second actuating assembly, and the first actuating direction of first actuating assembly and the second actuating direction of second actuating assembly are different, consequently through mutually supporting of first actuating assembly and second actuating assembly, can realize multidimension massage to can realize massage mode diversification.

Before the massage starts, the first actuating component and/or the second actuating component can be adjusted and actuated to attach the massage piece to the massage position; then the first actuating component and/or the second actuating component are/is started to perform massage actuation, so that the adaptability of the massage device to different users is improved.

Drawings

Fig. 1 is a schematic structural view of a first embodiment of a massage mechanism of the present application;

fig. 2 is a schematic structural view of a second embodiment of the massage mechanism of the present application;

fig. 3 is a schematic view of the massage mechanism viewed in the C1 view direction shown in fig. 2;

fig. 4 is a schematic structural view of a third embodiment of the massage mechanism of the present application;

fig. 5 is a schematic structural view of a fourth embodiment of the massage mechanism of the present application;

fig. 6 is a schematic view of the massage mechanism viewed in the C2 view direction shown in fig. 5;

fig. 7 is a schematic structural view of a fifth embodiment of a massage mechanism of the present application;

fig. 8 is a schematic structural view of a sixth embodiment of the massage mechanism of the present application;

fig. 9 is a schematic view of the massage mechanism viewed in the C3 viewing direction shown in fig. 8;

FIG. 10 is a schematic structural diagram of one embodiment of a flexible actuating assembly according to the present application;

FIG. 11 is a schematic structural view of the extended state of the electric actuator unit of FIG. 10;

FIG. 12 is a schematic structural view of the retracted state of the electric actuator unit of FIG. 10;

FIG. 13 is a schematic structural view of another embodiment of a flexible actuating assembly of the present application;

FIG. 14 is a schematic structural view of a retracted state of the optical actuator unit of FIG. 13;

FIG. 15 is a schematic structural view of an extended state of the optical actuator unit of FIG. 13;

fig. 16 is a schematic structural view of a seventh embodiment of a massage mechanism of the present application;

fig. 17 is a schematic structural view of an eighth embodiment of a massage mechanism of the present application;

fig. 18 is a schematic view of the massage mechanism viewed from the C4 viewing direction shown in fig. 17;

fig. 19 is a schematic structural view of a ninth embodiment of a massage mechanism of the present application;

fig. 20 is a schematic structural view of a tenth embodiment of a massage mechanism of the present application;

fig. 21 is a schematic structural view of an eleventh embodiment of a massage mechanism of the present application;

fig. 22 is a schematic view of the massage mechanism viewed from the C5 viewing direction shown in fig. 21;

FIG. 23 is a schematic structural view of yet another embodiment of a flexible actuating assembly herein;

FIG. 24 is a schematic illustration of the retracted configuration of the air bladder of FIG. 23;

FIG. 25 is a schematic illustration of the configuration of FIG. 23 showing the air bladder in an extended condition;

fig. 26 is a schematic structural view of a twelfth embodiment of a massage mechanism of the present application;

FIG. 27 is a schematic view of the structure of an embodiment of the massage device of the present application;

fig. 28 is a schematic cross-sectional view of the massage mechanism of fig. 27;

fig. 29 is a schematic view of the internal structure of the massage device of fig. 27.

Detailed Description

In order to make the technical solutions of the present application better understood by those skilled in the art, the present application is described in further detail below with reference to the accompanying drawings and the detailed description. It is to be understood that the described embodiments are merely some embodiments of the present application and not all embodiments. All other embodiments obtained by a person of ordinary skill in the art without any creative effort based on the embodiments in the present application belong to the protection scope of the present application.

The application provides a massage mechanism and a massage device with the massage mechanism, and aims to solve the problem that the massage mode of the massage device is single.

Specifically, referring to fig. 27, the massage device 700 includes a device body 710 and a massage mechanism 720 mounted on the device body 710, the device body 710 defining the overall shape of the massage device 700. The massage mechanism 720 is disposed on the device body 710, and the massage mechanism 720 is actuated to output a massage motion to a massage subject.

The massage device 700 can be a portable massage device, such as a wearable massage device (e.g., a cervical vertebra massage device, a waist massage device, a wrist strap massage device, or an eye massage device), or other portable massage devices (e.g., a massage cushion, a massage shoe, etc.).

Specifically, the shape of the device body 710 may be designed according to the type of the massage device 700. For the wearable massage device, the device body 710 may be configured to have an outer shape for wearing on the human body corresponding to the massage portion as needed, for example, the device body 710 may be configured to have an outer shape for wearing on the human body corresponding to the neck portion, so that the massage mechanism 720 is used for massaging the neck portion, that is, the device body 710 may be provided in a ring shape; for example, the device body 710 may be configured to have an outer shape for wearing on a human body corresponding to a waist, so that the massage mechanism 720 is used to massage the waist, i.e., the device body 710 is a belt body; for example, the device body 710 may be configured to have a wrist strap shape for wearing on a wrist so that the massage mechanism 720 is used for massaging the wrist, and then the device body 710 is a wrist strap type body; for example, the device body 710 may be configured to have an outer shape corresponding to the eye to be worn on the human body so that the massage mechanism 700 is used to massage the circumference of the eye, and the device body 710 is an eye-worn main body.

For a non-wearable massage device, the device body 710 may be a sleeping mat, a seat cushion, or a floor mat, and the device body 710 is a mat body.

The device body 710 may be provided with a plurality of massage mechanisms 720, and the plurality of massage mechanisms 720 are distributed at intervals. The massage apparatus 700 can sufficiently massage the portion to be massaged of the massage target by the plurality of massage mechanisms 720.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a first embodiment of a massage mechanism of the present application.

As shown in fig. 1, the massage mechanism 100 includes a first actuating assembly 110 and a second actuating assembly 120.

The first actuating assembly 110 has a first actuating direction H, the second actuating assembly 120 is mounted to an output end of the first actuating assembly 110, and the second actuating assembly 120 has a second actuating direction L different from the first actuating direction H.

In the first embodiment, since the second actuating assembly 120 is installed at the output end of the first actuating assembly 110, and the first actuating direction H of the first actuating assembly 110 is different from the second actuating direction L of the second actuating assembly 120, the first actuating assembly 110 and the second actuating assembly 120 are matched with each other to actuate simultaneously or sequentially, so that massage effects in two directions can be realized, i.e., multi-dimensional massage can be realized, more complicated massage actions can be realized, and the massage modes can be diversified. Moreover, the actuating positions of the first actuating assembly 110 and the second actuating assembly 120 at the beginning of the massage can be adjusted according to the massage parameters or other instructions detected by the sensors on the massage piece (for example, according to the massage parameters, the first actuating assembly 110 and/or the second actuating assembly 120 can be adjusted to actuate in a debugging way to attach the massage piece to the massage position, and then the first actuating assembly 110 and/or the second actuating assembly 120 can be started to actuate in the massage way), so that the adaptability of the massage piece to different users can be improved.

It should be noted that the actuation direction referred to in the present application includes a linear actuation direction generated by the movement of the actuation member, and also includes a rotational actuation direction generated by the rotation of the actuation member. The following description mainly takes a linear actuating direction as an example, but when one of the actuating directions of the first actuating assembly 110 and the second actuating assembly 120 is a linear actuating direction and the other actuating direction is a rotary actuating direction, the effects of both the impact massage and the spinning massage can be achieved.

In this first embodiment, and in each of the subsequent embodiments, the output for transferring kinetic energy between different actuating assemblies may be defined as the actuation transfer output, and the output for finally outputting a massage action to the massage subject as the massage output, wherein the longest sequence of transfer of kinetic energy between the actuating assemblies of the massage mechanism 100 is defined as the actuation transfer sequence of the massage mechanism 100.

For example, in one embodiment, the massage mechanism 100 includes only two actuating assemblies, namely the first actuating assembly 110 and the second actuating assembly 120, which are connected by the above-mentioned positional relationship, and the longest kinetic energy transmission sequence between the actuating assemblies of the massage mechanism 100 is from the first actuating assembly 110 to the second actuating assembly 120, that is, from the first actuating assembly 110 to the second actuating assembly 120, which is the actuation transmission sequence of the massage mechanism 100.

Of course, in this first embodiment, the number of actuating units (such as an electric actuating unit, a light actuating unit, or a pneumatic actuating bag, etc., described below) included in the massage mechanism 100 is not limited, and the actuating units of the actuating components included in the massage mechanism 100 may be specifically configured according to the complexity of the massage action to be output.

In this first embodiment, the output of the first actuation assembly 110 is used to transmit kinetic energy to the second actuation assembly 120, i.e., the output of the first actuation assembly 110 is an actuation transmission output, and the output of the second actuation assembly 120 may be used to output a massage action to the massage subject, i.e., the output of the second actuation assembly 120 is a massage output.

In this first embodiment, a massage element may be mounted at the massage output (e.g., the output of the second actuating assembly 120) as a location in direct contact with the massage subject. Of course, in other embodiments (not shown), the massage output end can be used as a portion directly contacting the massage object, i.e., the massage member can be integrated with the massage output end (e.g., the output end of the second actuating assembly 120).

The massage object can be a human body, and the massage part can be a hand, a head, a neck, the periphery of eyes, a wrist or other positions of the human body. Of course, in other embodiments, the massage object may be an animal, and the massage area may be the neck, around the eyes, feet, head, or other location of the animal. In this embodiment, the massage area is not limited.

Alternatively, when the massage device 700 is a cervical vertebra massage device, a plurality of massage mechanisms 720 are spaced apart from each other in the circumferential direction of the side of the wearing body 710 contacting the neck.

Optionally, the massage device 700 is an eye massage device (not shown), the device body has a left eye massage area (not shown) for the left eye and a right eye massage area (not shown) for the right eye, and a plurality of massage mechanisms 720 are disposed around the left eye massage area for outputting massage actions to the periphery of the left eye; a plurality of massage mechanisms 720 are annularly arranged in the right eye massage area and used for outputting massage actions to the periphery of the right eye; thereby, the eyes can be massaged sufficiently.

The first actuation assembly in the actuation transmission sequence of the massage mechanism 100 in this first embodiment may be configured to be mounted to the device body 710, which may be referred to as a mounting end actuation assembly; the last actuation assembly is configured for acting on a massage site and may be referred to as a massage end actuation assembly.

For example, when the massage mechanism 100 only includes the first actuating element 110 and the second actuating element 120, the mounting end actuating element is the first actuating element 110 to be mounted on the device body 710; the massage end actuating assembly is the second actuating assembly 120 to act on the massage site. When the massage mechanism 100 sequentially comprises the third actuating component, the first actuating component 110 and the second actuating component 120 which are installed according to the actuating transmission sequence, the installation end actuating component can be the third actuating component to be installed on the device body 710, that is, the first actuating component 110 is installed on the device body 710 through the third actuating component; the massage end actuating assembly may be made the second actuating assembly 120.

When the massage mechanism 100 is applied (mounted) to the massage device 700, it can be mounted/designed with reference to the actuation direction of the massage end actuation assembly, e.g., the actuation direction of the massage end actuation assembly can be made perpendicular to the massage site to perform a pressing massage to the massage site; or the actuating direction of the massage end actuating component is parallel to the massage part so as to carry out kneading massage/kneading pushing massage on the massage part, and the actuating part of the massage end actuating component can be parallel to the massage part by acting an output conversion piece (such as an L-shaped steering plate and the like); or the actuating direction of the massage end actuating component is arranged at a preset angle (such as an acute angle or an obtuse angle) with the massage part, so that the massage part can be subjected to both pressing massage and kneading massage/scraping massage/kneading massage.

For example, when the massage mechanism 100 includes only the first actuating element 110 and the second actuating element 120, the second actuating direction L may be perpendicular to the massage area, may be parallel to the massage area, or may be disposed at a predetermined angle to the massage area when the massage mechanism is applied (mounted) to the massage device 700.

It should be noted that, since the surface of the massage part is not generally planar, the term parallel in this application means tangential to the surface of the massage part.

The actuation direction of the massage end actuation assembly can be set in roughly three cases at the time of a particular application.

1. The actuating direction of the massage end actuating component is biased to be perpendicular to the surface of the massage part, for example, the preset angle between the actuating direction of the massage end actuating component and the massage part can be greater than or equal to 70 degrees and less than 89 degrees (such as 75 degrees, 80 degrees, or 85 degrees), or greater than 91 degrees and less than or equal to 110 degrees (such as 95 degrees, 100 degrees, or 105 degrees).

Thus, the acting force effect of the massage end actuating component can be deflected to the pressing effect, so as to enhance the pressing massage effect on the massage part.

2. The actuating direction of the massage end actuating component can be biased to be parallel to the surface of the massage part; for example, the predetermined angle between the actuating direction of the massage end actuating component and the massage portion may be greater than 0 degree and less than or equal to 20 degrees (e.g., 5 degrees, 10 degrees, or 15 degrees), or greater than or equal to 160 degrees and less than 180 degrees (e.g., 165 degrees, 170 degrees, or 175 degrees).

Thus, the acting force effect of the massage end actuating component can be biased towards the rubbing and scraping effect, so as to enhance the rubbing and scraping massage effect on the massage part.

3. The acting force effect of the massage end actuating component can be relatively balanced with the pressing effect and the kneading and scraping effect, and at the moment, the preset angle between the actuating direction of the massage end actuating component and the massage part can be larger than or equal to 30 degrees and smaller than or equal to 60 degrees (such as 35 degrees, 40 degrees, 45 degrees, 50 degrees, or 55 degrees) or larger than or equal to 120 degrees and smaller than or equal to 150 degrees (such as 125 degrees, 130 degrees, 135 degrees, 140 degrees, or 145 degrees).

The following description is mainly provided in terms of the direction of actuation of the massage end actuation assembly perpendicular or parallel to the surface of the massage portion, but is not intended to limit the present application.

In this first embodiment, the first actuating assembly 110 may be a flexible actuating assembly, the first actuating assembly 110 being configured to have a first actuating direction H by deformation actuation; and/or the second actuating assembly 120 is a flexible actuating assembly, and the second actuating assembly 120 is configured to be actuated by deformation to have the second actuating direction L.

As such, by providing the first actuating assembly 110 and/or the second actuating assembly 120 as a flexible actuating assembly, since the flexible actuating assembly is actuated by deformation, the actuation process is relatively slow and free of sudden changes, which enables actuation of the massage mechanism 100 relative to the motor, with advantages such as: no pause and noise, more energy saving and portability.

Of course, in other embodiments, as shown in fig. 27-29, the first and second actuator assemblies may also be non-flexible actuator assemblies such as linear motors/voice coil motors.

In the first embodiment, as shown in fig. 1, the first actuating assembly 110 and the second actuating assembly 120 are illustrated as flexible actuating assemblies.

In particular, the flexible actuation assembly has an extended state and a retracted state, the flexible actuation assembly being adapted to be deformed from the retracted state to the extended state or from the extended state to the retracted state.

In this first embodiment, both the first actuating assembly 110 and the second actuating assembly 120 may be used to extend, retract, remain extended, or remain retracted.

When applied to the massage device 700, the second actuation direction L can be biased to be perpendicular to the massage area, and one of the massage modes is: the first actuating member 110 is extended or contracted to move the second actuating member 120 in the first actuating direction H, while the second actuating member 120 can remain retracted or extended. Thus, the kneading and pushing massage can be simulated. In this manner, the back-and-forth movement frequency of the kneading massage can be adjusted by adjusting the alternating frequency of the extension deformation and the contraction deformation of the first actuating member 110.

In another massage mode, the second actuating element 120 can be continuously alternated between the extended state and the retracted state, and the first actuating element 110 is extended or retracted to move the second actuating element 120 in the first actuating direction H. Thus, the double massage effects of pressing and kneading and pushing can be simulated.

In yet another massage mode, the second actuator assembly 120 can be continuously alternated between the extended state and the retracted state while the first actuator assembly 110 is maintained in the extended or retracted state to achieve a massage simulating the pressing of a finger.

On the contrary, when the second actuating direction L is deviated to be parallel to the massage part, in the massage mode, the second actuating element 120 is driven to move in the first actuating direction H by the extending deformation or the contracting deformation of the first actuating element 110, so as to adjust the pressure on the massage part, thereby realizing the pressing massage of the simulated fingers; by making the second actuating component 120 expand or contract, the massage of kneading and pushing of fingers is simulated.

As shown in fig. 1, in the first embodiment, the massage mechanism 100 further includes a first connecting member 130, the first connecting member 130 has a first mounting surface a and a second mounting surface B, an included angle between the first mounting surface a and the second mounting surface B is greater than 0 degree, the first mounting surface a is connected to an output end of the first actuating assembly 110, and the second actuating assembly 120 is mounted on the second mounting surface B, so that the first actuating direction H is different from the second actuating direction L.

It will be appreciated that the actuating assembly will typically have a mounting base (i.e. to form a mounting end) perpendicular to its direction of actuation, the mounting base being for connection to other components (e.g. a device body or a connector). Therefore, when the first mounting surface a is connected to the output end of the first actuating assembly 110, the actuating direction of the first actuating assembly 110 is perpendicular to the first mounting surface a; when the second actuating assembly 120 is mounted on the second mounting surface B, the actuating direction of the second actuating assembly 120 is perpendicular to the second mounting surface B; such that the angle between said second actuation direction and the first actuation direction is greater than 0 degrees, i.e. different.

In this manner, by providing the first linkage 130 to connect the first actuating assembly 110 and the second actuating assembly 120, it may be facilitated to have the first actuating direction H different from the second actuating direction L.

As shown in fig. 1, in the first embodiment, the first connecting member 130 may be a first connecting block 130a, and the first mounting surface a and the second mounting surface B are two adjacent side surfaces of the first connecting block 130a, respectively. Thus, by configuring the first connecting member 130 as a block structure, i.e., the first connecting block 130a, the transmission stability of the first connecting member 130 can be improved, and the structure can also be simplified.

As shown in fig. 1, in the first embodiment, further, a mounting groove 10 is provided on the second mounting surface B, and the second actuating assembly 120 is mounted at the bottom of the mounting groove 10.

Wherein the depth of the mounting groove 10 can be optionally smaller than the length of the second actuating assembly 120 in the second actuating direction when the second actuating assembly 120 is maximally contracted. As such, the maximum actuation capability of the second actuation assembly 120 may be preserved while reducing the overall length of the massage mechanism 100 in the second actuation direction L, such that the overall size of the massage mechanism 100 can be reduced.

Alternatively, for the purpose of further reducing the overall size of the massage mechanism 100, the projection of the mounting groove 10 on the projection plane perpendicular to the first actuating direction H at least partially overlaps the projection of the first actuating member 110 on the projection plane perpendicular to the first actuating direction H. It is to be understood that the projection plane is a virtual plane assumed for the sake of explanation.

In a particular application, the angle between the second actuation direction L and the first actuation direction H may be greater than or equal to 10 degrees and less than or equal to 170 degrees.

Specifically, an included angle between the first mounting surface a and the second mounting surface B is related to an included angle between the first actuating direction H and the second actuating direction L, for example, when the first mounting surface a is connected to the output end of the first actuating assembly 110, the actuating direction of the first actuating assembly 110 is perpendicular to the first mounting surface a; when the second actuating assembly 120 is mounted on the second mounting surface B, the actuating direction of the second actuating assembly 120 is perpendicular to the second mounting surface B; therefore, the included angle between the first mounting surface a and the second mounting surface B may be greater than or equal to 10 degrees and less than or equal to 170 degrees, so that the included angle between the second actuating direction L and the first actuating direction H may be greater than or equal to 10 degrees and less than or equal to 170 degrees.

It will be appreciated that if the angle is too small or too large, it is not conducive to a differential arrangement of the actuation directions of the massage mechanism.

Further, the angle between the second actuating direction L and the first actuating direction H may be greater than or equal to 30 degrees, and less than or equal to 150 degrees, such as greater than or equal to 60 degrees, and less than or equal to 120 degrees, such as 70 degrees, 80 degrees, 90 degrees, 100 degrees, or 110 degrees. Correspondingly, the included angle between the first mounting surface a and the second mounting surface B may be greater than or equal to 30 degrees, and less than or equal to 150 degrees, such as greater than or equal to 60 degrees, and less than or equal to 120 degrees, such as 70 degrees, 80 degrees, 90 degrees, 100 degrees, or 110 degrees.

In this manner, the included angle between the second actuating direction L and the first actuating direction H can be set according to the specific structure of the device body 710 and the desired massage effect. Moreover, when the second actuating direction L is not perpendicular to the first actuating direction H, the first actuating member 110 can enhance the effect of the second actuating member 120 on the massage area.

Referring to fig. 2-3, the massage mechanism 100 of the second embodiment is based on a modification of the massage mechanism 100 of the first embodiment, which is partly realized by adding a third actuating component 140, as follows.

As shown in fig. 2-3, the massage mechanism 100 further includes a third actuating component 140, the third actuating component 140 is mounted to the device body 710, the first actuating component 110 is mounted to an output end of the third actuating component 140, the third actuating component 140 has a third actuating direction W, and the first actuating direction H, the second actuating direction L and the third actuating direction W are different.

It will be appreciated that in this second embodiment, the mounting end actuating assembly is the third actuating assembly 140 and the massage end actuating assembly is the second actuating assembly 120.

In this way, by arranging the first actuating assembly 110, the second actuating assembly 120 and the third actuating assembly 140 which are connected in sequence, the first actuating assembly 110, the second actuating assembly 120 and the third actuating assembly 140 can be actuated simultaneously or sequentially, so that the massage mechanism 100 has 3 directions of actuation, and thus the massage end actuating assembly (i.e. the second actuating assembly 120) can massage the massage part in three directions, and diversification of massage modes can be realized.

Referring to the first embodiment, in the second embodiment, the specific structure of the third actuating element 140 can refer to the first actuating element 110, and need not be described herein.

In this second embodiment, the first actuating assembly 110, the second actuating assembly 120, and the third actuating assembly 140 can be flexible actuating assemblies, and when the massage mechanism 100 is applied to the massage device 700, the first actuating assembly 110, the second actuating assembly 120, and the third actuating assembly 140 can be used for extending deformation, contracting deformation, maintaining an extended state, or maintaining a retracted state, so as to simulate various massage modes.

For example, one may: first, the first actuating component 110 is deformed by extension or contraction, and simultaneously or sequentially the third actuating component 140 is deformed by extension or contraction, so as to drive the second actuating component 120 to move and adjust the corresponding position of the second actuating component 120 to be massaged on the massage object. While the second actuating assembly 120 may remain retracted; the second actuating assembly 120 may then be extended to an extended state. Therefore, the transposition pressing massage of the fingers can be simulated.

As another example, one may: firstly, the first actuating component 110 is deformed by extension or contraction, and simultaneously or sequentially the third actuating component 140 is deformed by extension or contraction to drive the second actuating component 120 to move; while the second actuating assembly 120 may remain extended. Thus, the soft pushing massage of the fingers can be simulated.

It is understood that when the first actuating assembly 110 and the third actuating assembly 140 are deformed simultaneously, the moving direction of the second actuating assembly 120 is the vector sum of the moving speed generated by the second actuating assembly 110 based on the deformation of the first actuating assembly 110 and the moving speed generated by the second actuating assembly 120 based on the deformation of the third actuating assembly 140. Thus, the third actuating element 140 can be deformed by extension or contraction while the first actuating element 110 is deformed by extension or contraction; so as to drive the second actuating component 120 to move along a curved or linear moving track.

Further, as shown in fig. 2 to 3, the massage mechanism 100 includes a second connecting member 150, the second connecting member 150 has a third mounting surface D and a fourth mounting surface E, an included angle between the third mounting surface D and the fourth mounting surface E is greater than 0 degree and an included angle between the third mounting surface D and the second mounting surface B is greater than 0 degree, the third mounting surface D is connected with an output end of the third actuating assembly 140, and the first actuating assembly 110 is mounted on the fourth mounting surface E so that the third actuating direction W is different from the second actuating direction L and the first actuating direction H.

The structure and the arrangement of the second connecting member 150 can refer to the first connecting member 130, and need not be described in detail herein.

In this second embodiment, at least any two of the first actuation direction H, the second actuation direction L, and the third actuation direction W may be made perpendicular to each other. Any two of the first actuating direction H, the second actuating direction L and the third actuating direction W can be perpendicular to each other. Thus, the design can be simplified.

To facilitate an understanding of the present application, the application of the massage mechanism 100 is illustrated below. When the massage mechanism 100 is applied to the massage device 700 (e.g., an eye massager), the second actuating direction L can be perpendicular to the massage area, the first actuating direction H can be an up-down direction, and the third actuating direction W can be a left-right direction, so that the massage device can control the pressing parameters by controlling the actuation of the second actuating component 120, the kneading parameters in the up-down direction by controlling the actuation of the first actuating component 110, and the kneading parameters in the left-right direction by controlling the actuation of the third actuating component 130. Of course, the second actuating direction (bias) can be arranged parallel to the massage portion by installing an output converting member at the output end of the second actuating assembly 120, and the second actuating direction L can be an up-down direction, the first actuating direction H can be perpendicular to the massage portion, and the third actuating direction W can be a left-right direction.

Alternatively, referring to fig. 4, the massage mechanism 100 provided in the third embodiment is based on a modification of the massage mechanism 100 in the first embodiment, the modified portion being on the structure of the first connecting member 130, even if the first connecting member 130 is a plate-like structure, as follows.

As shown in fig. 4, the first connecting member 130 includes a first connecting plate 131B and a second connecting plate 132B intersecting with each other, a side of the first connecting plate 131B facing the first actuating assembly 110 is a first mounting surface a, the second connecting plate 132B is located on a side of the first actuating assembly 110, and a side of the second connecting plate 132B away from an actuating centerline of the first actuating assembly 110 is a second mounting surface B.

In a particular application, the second connecting plate 132b may be extended toward a side of the first connecting plate 131b away from the first actuating assembly 110, so as to bias the second actuating assembly 120 toward a side of the first connecting plate 131b away from the first actuating assembly 110; the second connecting plate 132b may also extend toward a side of the first connecting plate 131b facing the first actuating assembly 110 to bias the second actuating assembly 120 toward the side of the first connecting plate 131b facing the first actuating assembly 110. It is even possible to have one end of the second connecting plate 132b extend toward a side of the first connecting plate 131b away from the first actuating assembly 110 and the other end extend toward a side of the first connecting plate 131a toward the first actuating assembly 110, so that the middle of the second actuating assembly 120 in the first actuating direction H is disposed near the first connecting plate 131 b.

In this way, the first actuating assembly 110 and the second actuating assembly 120 can be more flexibly arranged, and materials can be saved.

In particular, when the second connecting plate 132b extends toward a side of the first connecting plate 131b facing the first actuating assembly 110, the first actuating assembly 110 and the second actuating assembly 120 can be at the same height, so as to reduce the height of the braking device 100 in the first actuating direction H.

Alternatively, in this third embodiment, the first connecting plate 131b and the second connecting plate 132b are rotatably connected such that the angle between the second actuating direction L and the first actuating direction H is adjustable. Therefore, the included angle between the second actuating direction L and the first actuating direction H can be flexibly adjusted according to the actual massage requirement, and a more multidimensional massage mode can be conveniently realized.

Of course, the first connecting plate 131b and the second connecting plate 132b may be fixedly connected, for example, the first connecting member 130 may have an L-shaped plate structure.

Referring to fig. 5-6, the massage mechanism 100 provided in the fourth embodiment is based on a modification of the massage mechanism 100 provided in the second embodiment, in that the first connecting member 130 and/or the second connecting member 150 are defined as a plate-shaped structure, as follows.

As shown in fig. 5-6, the first connecting member 130 and the second connecting member 150 are both plate-shaped structures, that is, the first connecting member 130 includes a first connecting plate 131B and a second connecting plate 132B which intersect with each other, a side of the first connecting plate 131B facing the first actuating assembly 110 is a first mounting surface a, the second connecting plate 132B is located on one side of the first actuating assembly 110, and a side of the second connecting plate 132B away from the actuating centerline of the first actuating assembly 110 is a second mounting surface B.

Second link 150 includes intersecting third link plate 151b and fourth link plate 152b, the side of third link plate 151b facing third actuating assembly 140 being third mounting face D, fourth link plate 152b being located on the side of third actuating assembly 140, and the side of fourth link plate 152b facing away from the actuating centerline of third actuating assembly 140 being fourth mounting face E.

In this fourth embodiment, the second connecting plate 132b may be extended toward the side of the first connecting plate 131b facing the first actuating assembly 110, and the fourth connecting plate 152b may be extended toward the side of the third connecting plate 151b facing the third actuating assembly 140, so that the massage mechanism 100 has an overall L-shaped structure to reduce the overall size of the massage mechanism 100.

In the fourth embodiment, the structure and the arrangement of the second connecting element 150 can refer to the structure and the arrangement of the first connecting element 130 in the third embodiment, and are not repeated herein.

Referring to fig. 7, in the fifth embodiment of the massage mechanism, the massage mechanism 100 includes a first actuating element 110 and a second actuating element 120, the first actuating element 110 has a first actuating direction H, the second actuating element 120 is mounted at an output end of the first actuating element 110, and the second actuating element 120 has a second actuating direction L different from the first actuating direction H.

With continued reference to fig. 7, the second actuating element 120 is located on the actuating track of the first actuating element 110, the massage mechanism 100 further includes an output converter 160, the output converter 160 is mounted at the output end of the second actuating element 120, and the output converter 160 includes a power output portion 161 located at a side of the second actuating element 120 away from the first actuating element 110. In this embodiment, the massage end actuating assembly is a second actuating assembly 120.

It should be noted that the actuation trajectory of the first actuation assembly 110 refers to a trajectory formed by the output end of the first actuation assembly 110 when the first actuation assembly 110 is actuated in the first actuation direction H.

In this way, by arranging the second actuating assembly 120 on the actuating trajectory of the first actuating assembly 110, one of the projection of the second actuating assembly 120 on the projection plane perpendicular to the first actuating direction H and the projection of the first actuating assembly 110 on the projection plane can be positioned within the other, so that the size of the massage mechanism 100 in the second actuating direction L can be reduced. It is to be understood that the projection plane is a virtual plane assumed for the sake of explanation.

Furthermore, by providing the output conversion member 160 and making the output conversion member 160 include the power output portion 161 located at a side of the second actuating assembly 120 away from the first actuating assembly 110, the power output portion 161 can be located in the first actuating direction H. When applied to the massage device 700, the output power of the second actuating assembly 120 can be outputted through the power output portion 161 at one side thereof to realize power conversion.

Specifically, when applied to the massage device 700, the side (i.e., massage face) of the power output portion 161 away from the first actuating member 110 may be disposed parallel to or obliquely with respect to the massage area, so that the power output portion 161 may massage the massage area when the second actuating member 120 drives the output conversion member 160 to move; and simultaneously, the power output part 161 can move in the direction of the pressing massage part by matching with the power driving of the first actuating component 110, so as to realize the pressing massage.

Specifically, as shown in fig. 7, the massage mechanism 100 further includes a first connecting member 130, the first connecting member 130 includes a first connecting plate 131b and a second connecting plate 132b connected to each other, the first connecting plate 131b is mounted at the output end of the first actuating assembly 110, the second connecting plate 132b extends toward the side of the first connecting plate 131b away from the first actuating assembly 110, and the second actuating assembly 120 is mounted on the second connecting plate 132b, so that the second actuating assembly 120 is located on the actuating track of the first actuating assembly 110. In this manner, by providing the first connecting member 130 as a plate-shaped structure, it is convenient to locate the second actuating assembly 120 on the actuating track of the first actuating assembly 110.

In the fifth embodiment, please refer to the above embodiment and fig. 7 for other specific structural relationships of the first connecting element 130.

In this fifth embodiment, the output conversion member 160 may include an output connection portion 162 and a power output portion 161. The output connecting portion 162 is installed at the output end of the second actuating assembly 120, and the power output portion 161 is connected to the output connecting portion 162 and extends to a side of the output connecting portion 162 facing the second actuating assembly 120, so that the power output portion 161 is located at a side of the second actuating assembly 120 far away from the first actuating assembly 110. Optionally, the output conversion member 160 is an L-shaped conversion plate.

In this modified embodiment of the fifth embodiment, the second actuating assembly 120 may be provided with two massage outputs, namely, the power output 161 and the output connection 162, and specifically, when the massage mechanism 100 is applied to the massage apparatus 700, the massage mechanism 100 may be rotatably mounted on the apparatus body 710 such that the second actuating direction L has two states of being parallel to the massage site and perpendicular to the massage site, and when the second actuating direction L is parallel to the massage site, the power output 161 serves as a massage output such that the second actuating assembly 120 is used for kneading the massage site; when the second actuating direction L is perpendicular to the massage site, the output connection 162 serves as a massage output such that the second actuating assembly 120 is used to press the massage site.

Referring to fig. 8-9, in the sixth embodiment, the massage mechanism 100 is obtained by modifying the massage mechanism 100 in the fifth embodiment, in which a third actuating element 140 and a second connecting element 150 are added, that is, the massage mechanism 100 further includes the third actuating element 140 and the second connecting element 150, and the structures of the third actuating element 140 and the second connecting element 150 can basically refer to the embodiments in the above embodiments, which need not be described in detail herein, but need to be described in detail below.

With continued reference to fig. 8-9, the second connecting member 150 includes a third connecting plate 151b and a fourth connecting plate 152b connected to each other, the third connecting plate 151b is mounted at an output end of the third actuating element 140, the fourth connecting plate 152b extends toward a side of the third connecting plate 151b facing the third actuating element 140, and the first actuating element 110 is mounted at a side of the fourth connecting plate 152b away from the third actuating element 140, such that the third actuating element 140, the first actuating element 110 and the second actuating element 120 are sequentially distributed in the first actuating direction H.

As such, it may be advantageous to reduce the size of the massage mechanism 100 in a direction perpendicular to the first actuation direction H, such that the massage mechanism 100 as a whole extends in the first actuation direction H.

In this sixth embodiment, the massage end actuating assembly is the second actuating assembly 120 and the mounting end actuating assembly is the third actuating assembly 140.

Taking the three actuating directions perpendicular to each other as an example, when applied to a massage device (such as an eye massager), the third actuating assembly 140 may be mounted on the device body, and the side surface (i.e., the massage surface) of the power output portion 161 away from the first actuating assembly 110 may be parallel or obliquely disposed on the massage portion, the second actuating direction L (in the up-down direction) may be parallel to the massage portion, the first actuating direction H may be perpendicular to the massage portion, and the third actuating direction W (in the left-right direction) may be parallel to the massage portion.

Thus, when the second actuating assembly 120 drives the output conversion member 160 to move, the power output part 161 can rub and push the massage part (in the up-down direction); and simultaneously, the power output part 161 can move in the direction of the pressing massage part by matching with the power drive of the first actuating component 110, so as to realize the pressing massage; and simultaneously, the power output part 161 can be driven to rub and push the massage part (in the left and right directions) by matching with the power driving of the third actuating component 140.

It should be noted that the orientation descriptions (such as the left-right direction and the up-down direction) in the present application are based on the descriptions in the specific installation/use states, and when the installation/use states are changed, the corresponding descriptions will be changed accordingly.

Specifically, the device body 710 has a skin-proximal side facing the massage area, the skin-proximal side of the device body 710 has a receiving groove, and the first actuating member 110 is mounted to a bottom or a side wall of the receiving groove.

Thus, the massage mechanism 100 is installed by the accommodating groove, and the side wall of the accommodating groove can be conveniently used for limiting the massage mechanism 100, so that the installation stability of the massage mechanism 100 is improved.

Specifically, for the above embodiment, when the massage mechanism 100 includes two actuating assemblies, i.e., the first actuating assembly 110 and the second actuating assembly 120, the mounting bottom of the first actuating assembly 110 can be mounted to the side wall of the receiving groove; however, when the massage mechanism 100 further includes the output conversion member 160, the mounting base of the first actuating member 110 can be mounted to the bottom of the receiving groove. When the massage mechanism 100 includes three actuating assemblies, i.e., the third actuating assembly 140, the first actuating assembly 110 and the second actuating assembly 120, the mounting bottom of the third actuating assembly 140 can be mounted to the side wall of the receiving groove.

In the above embodiments, the flexible actuating assembly may be an electric actuating assembly 200a, a light actuating assembly 200b, or a gas actuating assembly 200c, and the specific structure thereof is as follows:

referring to fig. 10-12, in an embodiment of the flexible actuator assembly, the flexible actuator assembly is an electric actuator assembly 200a, which may include at least one electric actuator unit 210a disposed in a stacked manner, the electric actuator unit 210a includes an electro-deformable layer 211a and electrodes 212a disposed in a stacked manner, the electro-deformable layer 211a has multiple layers, two sides of each electro-deformable layer 211a are disposed with one electrode 212a, and two adjacent electro-deformable layers 211a share the same electrode 212 a; the electro-deformable layer 211a is used for deforming when an electric field is applied, so that the electric actuating element 200a has an actuating direction S1, and two adjacent electrodes 212a are used for forming the electric field. It is understood that the two electrodes 212a on the two sides of each electro-deformable layer 211a are an anode layer and a cathode layer, respectively.

Among these, there are various ways of forming the electric actuating unit 210a, which are exemplified as follows:

for example, the electrodes 212a on both sides of the electro-deformable layer 211a can be used to connect a power supply to access electric energy, and in the electric actuator assembly 200a, a single electro-deformable layer 211a can form an independent power supply circuit with the power supply through the electrodes 212a on both sides thereof to form an electric actuator unit 210a, such as the power supply circuit of the power supply epsilon 2 shown in fig. 10.

As another example, a single electro-deformable layer 211a may be connected in parallel with electrodes 212a on both sides of other electro-deformable layers 211a via electrodes 212a on both sides to form a shared power supply circuit with the power supply in common to form an electrical actuation unit 210a, such as the power supply circuit of power supply ∈ 1 and power supply ∈ 3 shown in fig. 10.

The electrostrictive layer 211a is an elastic electrostrictive film, which can generate electrostrictive effect, and elastically deform in an electric field, and deform in the opposite direction after the electric field is reduced or disappears.

Alternatively, the electrostrictive film may be made of an electrostrictive material such as PDMS (polydimethylsiloxane material), PVC-gel (polyvinyl chloride gel material), or the like, i.e., the electrostrictive film may be selected to be a PDMS film or a PVC-gel film. The PDMS and PVC-gel materials have the characteristic of portability, reduce the weight and are convenient for a user to carry compared with a massager adopting a motor massage mode. Meanwhile, the deformation materials are similar to biological muscles, so that the massage effect of a human hand can be approximate or equal under the control of a proper electric field and the change thereof during massage.

The electro-deformable layer 211a has two sides in the thickness direction, the two sides are respectively provided with the electrodes 212a, and the electro-deformable layer 211a is configured to generate deformation when an electric field is applied, and the deformation can be either extension deformation or contraction deformation. Specifically, the electro-deformable layer 211a can generate an electrostrictive effect under the action of an electric field formed by the two electrodes 212a on both sides thereof, that is, the electro-deformable layer 211a can be deformed when an electric field is applied thereto. The deformation here means that the physical form of the electro-deformable layer 211a is changed when an electric field is applied, for example, contraction or expansion in the thickness direction occurs, with respect to the physical form when no electric field is applied; after the electric field is removed, the electro-deformable layer 211a returns to the original state.

Further, referring to fig. 11-12 in comparison, fig. 12 is a schematic view of the retracted state of the electric actuator unit of fig. 10.

As shown in fig. 11-12, at least one of the electrodes 212a may have an avoiding hole 213a, and the avoiding hole 213a is used for allowing a portion of the electro-deformable layer 211a to enter when the electro-deformable layer 211a contracts, i.e. it may provide a deformation space for the electro-deformable layer 211a, for example, when the electro-deformable layer 211a contracts in the thickness direction under the influence of an electric field, the electro-deformable layer 211a may be partially pressed into the avoiding hole 213 a. In this way, the deformation width of the electro-deformable layer 211a is larger and the actuation formation is relatively increased, compared to the case where the avoiding hole 213a is not provided. The number of the avoiding holes 213a may be set to be plural, so as to provide more avoiding space for the electro-deformable layer 211a, and further increase the deformation amplitude of the electro-deformable layer 211 a. Optionally, for any two adjacent electrodes 212a, only one of the electrodes 212a is provided with the avoiding hole 213 a.

It is understood that in this embodiment, the deformation direction of the electro-deformable layer 211a is the actuating direction S1 of the electrical actuating assembly 200a, i.e. the actuating direction of the flexible actuating assembly of the above embodiments, and is also the thickness direction of the electro-deformable layer 211a, and the two layers of electrodes 212a located at the outermost layer of the electrical actuating assembly 200a are respectively a fixed end and an output end; wherein the fixed end of the non-leading electrical actuator assembly 200a in the actuation transmission sequence of the massage mechanism 720 (not shown) is adapted to be mounted at the output end of the previous electrical actuator assembly 200a of the electrical actuator assembly 200 a; wherein the fixed end of the first electrically actuated component 200a in the actuation transmission sequence of the massage mechanism 720 is adapted to be mounted to the device body 710 (not shown).

It should be noted that, in an embodiment, when one electric actuating unit 210a in the electric actuating assembly 200a is provided, the two outermost layers of electrodes 212a of the electric actuating unit 210a are the two outermost layers of electrodes 212a of the electric actuating assembly 200 a; in another embodiment, a plurality of electrical actuator units 210a in the electrical actuator assembly 200a are stacked, and the two outermost electrodes 212a of the electrical actuator assembly 200a are the two outermost electrodes 212a of different electrical actuator units 210a (i.e. two outermost electrical actuator units 210 a).

Referring to fig. 13-16, in another embodiment of the flexible actuator assembly, the flexible actuator assembly may be selected as an optical actuator assembly 200b, and the optical actuator assembly 200b may include at least one optical actuator unit 210b stacked. As shown in fig. 14, the photo-actuated unit 210b includes a photo shell 211b, a light source 212b and a photo film 213b, a photo hole 201b is formed on the photo shell 211b, the photo film 213b is disposed at the photo hole 201b, the light source 212b is disposed in the photo shell 211b, and the photo film 213b is configured to deform when irradiated by the light source 212b, so that the photo-actuated assembly 200b has an actuating direction S2.

Although fig. 14 in the present embodiment only shows that the photo-holes 201b are formed on one side of the photo-shell 211b, it is understood that in other embodiments (not shown), the photo-holes may be formed on two opposite sides of the photo-shell, and the photo-film may be disposed corresponding to the photo-holes.

Specifically, as shown in fig. 15, the light source 212b can emit light with a predetermined wavelength to deform the light-induced film 213b, so that the light-induced component 200b is deformed to be extended to switch to the extended state. When the photo film 213b is not irradiated by the light source 212b, the photo film 213b may be shrunk and deformed to be switched to the retracted state.

The actuating direction S2 of the photo-actuated element 200b is a deformation direction of the photo-actuated unit 210b, i.e. a thickness direction of the photo-actuated unit 210b, i.e. an axial direction of the photo-hole 201 b.

It is understood that the portion of the non-photo-film 213b of the photo-actuated unit 210b located at the outermost layer of the photo-actuated assembly 200b may be a fixed end; the photo film 213b at the outermost layer of the photo-actuated element 200b may be the output end of the photo-actuated element 200 b. Wherein the fixed end of the non-leading one of the light actuated assemblies 200b in the actuation transmission sequence of the massage mechanism 720 is used for being mounted at the output end of the previous one of the light actuated assemblies 200 b; wherein the fixed end of the first light activated component 200b in the actuation transmission sequence of the massage mechanism 720 is adapted to be mounted to the device body 710 (not shown).

It should be noted that, in the drawings of the first to sixth embodiments of the massage mechanism 720, the flexible actuating components are all the electric actuating components 200a described above, and for facilitating understanding of the structure of the massage mechanism 720 when the flexible actuating components are the light actuating components 200b, the following description is made by way of example, as described above, the first actuating components 110, the second actuating components 120, and the third actuating components 140 can be regarded as the light actuating components 200 b.

Referring to fig. 16, in the seventh embodiment of the massage mechanism, the massage mechanism 400 includes a first actuating element 410 and a second actuating element 420, both of which are the above-mentioned optical actuating element 200 b.

Since the photo-actuated assembly 200b has the photo-shell 211b, which can serve as a mounting end, the first connector 130 of the above-mentioned embodiments may not be used between the first actuating assembly 410 and the second actuating assembly 420.

Specifically, as shown in fig. 16, the sidewall of the photo-shell 211b of the second actuating assembly 420 may be mounted on the photo-film 213b of the first actuating assembly 410.

In this embodiment, since the photo film 213b is bent and deformed during stretching and deformation, in order to improve the working stability of the massage mechanism 400, a first connecting member 430 having a structure different from that described above may be disposed on the photo film 213b of the first actuating member 410, where the first connecting member 430 has a fifth mounting surface F and a sixth mounting surface G, and the fifth mounting surface F and the sixth mounting surface G are two opposite sides of the first connecting member 430; the fifth mounting surface F is connected to the output end of the first actuating assembly 410, and one side of the second actuating assembly 420 located on the actuating centerline is mounted to the sixth mounting surface G, so that the second actuating assembly 420 is located on the actuating track of the first actuating assembly 410. In this way, the entire size of the massage mechanism 400 can be made small.

For example, the first connector 430 may be selected to have a plate shape.

Referring to fig. 17 and 18, in the eighth embodiment of the massage mechanism, the massage mechanism 400 includes a first actuating element 410, a second actuating element 420 and a third actuating element 440, which are all the aforementioned light actuating elements 200 b.

Compared with the seventh embodiment, the massage mechanism 400 further includes a second connector 450 mounted at the output end of the third actuating assembly 440, the second connector 450 has a seventh mounting surface J and an eighth mounting surface K, and the seventh mounting surface J and the eighth mounting surface K are two opposite side surfaces of the second connector 450; the seventh mounting surface J is connected to the output end of the third actuating assembly 440, and one side of the first actuating assembly 410, which is located on the actuation centerline of the first actuating assembly, is mounted on the eighth mounting surface K, so that the first actuating assembly 410 is located on the actuation trajectory of the third actuating assembly 440.

Referring to fig. 19, in a ninth embodiment of the massage mechanism, the massage mechanism 300 may include a first actuating element 310, a second actuating element 320 and an output converter 330, the output converter 330 is installed at an output end of the second actuating element 320, wherein the output converter 330 includes a power output portion 331 and an output connection portion 332, and specific structures and effects thereof may refer to the above embodiments and fig. 19, and are not described herein again.

Referring to fig. 20, in the tenth embodiment of the massage mechanism, the massage mechanism 500 includes a first actuating element 510 and a second actuating element 520, which are both photo-actuated elements 200b, in this embodiment, the first actuating element 510 and the second actuating element 520 can be connected by the plate-shaped first connecting element 130 (see the fourth embodiment).

In this embodiment, the massage mechanism 500 may further include an output converter 540, the output converter 540 is mounted at the output end of the second actuating assembly 520, and the output converter 540 includes a power output portion 541 located at one side of the second actuating assembly 520, and the specific structure and effect thereof can refer to the above embodiment and fig. 20, and are not described herein again.

Referring to fig. 21-22, in the eleventh embodiment of the massage mechanism, the massage mechanism 500 may include a first actuating element 510, a second actuating element 520, and a third actuating element 550, which are all the aforementioned light actuating elements 200 b. This embodiment is different from the eighth embodiment in the structure of the first link 530 and the second link 560.

In the eighth embodiment, referring to fig. 17-18, the light-induced film 213b of the second actuating assembly 420 can be disposed near the edge of the light-induced film 213b of the first actuating assembly 410 to facilitate power output of the light-induced film 213b of the second actuating assembly 420. In the eleventh embodiment, referring to fig. 21 to 22, since the first actuating element 510 and the second actuating element 520 are connected by the first connecting element 530 having an L-shaped plate shape, there is no limitation, so that the installation flexibility can be increased.

Referring to fig. 23-25, in one embodiment of the flexible actuator assembly, the flexible actuator assembly is an air actuator assembly 200c that includes at least one air actuator bladder 210c arranged in a stack, the air actuator bladder 210c configured to deform when inflated and/or deflated to provide the air actuator assembly 200c with an actuation direction S3.

In particular applications, the pneumatic actuator 210c may be a conventional bladder or a custom bladder as follows.

Specifically, as shown in fig. 24, the air-actuated bladder 210c may include an air-containing shell 211c and a flexible bladder membrane 212c, the air-containing shell 211c being formed with an air-containing cavity 202c, an air-guide opening 201c, and a mounting opening 203 c; the mounting port 203c is communicated with the air containing cavity 202c, the flexible bag film 212c is covered on the air containing shell 211c corresponding to the mounting port 203c, and the air guide port 201c is communicated with the air containing cavity 202c so as to be used for inflating the air containing cavity 202c or deflating the air containing cavity 202 c; the flexible bag 212c is subjected to an expansion deformation based on inflation of the gas containing chamber 202c to switch to an extended state, and is subjected to a contraction deformation based on deflation of the gas containing chamber 202c to switch to a retracted state. Although fig. 24 in this embodiment shows the mounting opening 203c formed on only one side of the air-containing chamber 202c, it is understood that in other embodiments (not shown), mounting openings may be formed on both opposite sides of the air-containing chamber and flexible bladders may be mounted thereon.

It will be appreciated that the direction of deformation of the gas actuated bladder 210c is the direction of actuation of the flexible actuator described above.

It is understood that the portion of the non-flexible bladder membrane of the air actuated bladder 210c that is located at the outermost layer of the air actuated assembly 200c may be a fixed end; the flexible bladder 212c located at the outermost layer of the air actuation assembly 200c may be the output end of the air actuation assembly 200 c. Wherein the fixed end of the non-leading pneumatic actuator assembly 200c in the actuation transmission sequence of the massage mechanism 720 is adapted to be mounted at the output end of the preceding pneumatic actuator assembly 200c of the pneumatic actuator assembly 200 c; wherein the fixed end of the leading pneumatic actuator assembly 200c in the actuation transmission sequence of the massage mechanism 720 is adapted to be mounted to the device body 710.

In this embodiment, the attachment of the fixed end of one actuator assembly to the output end of another actuator assembly or to the device body 710 may be a non-removable fixed connection such as by gluing; in another embodiment, the attachment of the fixed end of an actuation assembly to the output end of another actuation assembly or to the device body 710 may be a removable connection, such as by a fastener connection, or by a snap connection. Wherein the fastener can be a screw, a bolt, a nut, and the like.

Referring to fig. 26, in the twelfth embodiment of the massage mechanism, the massage mechanism 600 includes a first actuating element 610, a second actuating element 620 and a third actuating element 640, which are all pneumatic actuating elements 200 c.

The following description will be made of a specific structure of the massage mechanism 720 when the massage device 700 is a wearable massage device (e.g., a neck massage apparatus) and the actuating component of the massage mechanism 720 is a voice coil motor.

As shown in fig. 27-29, the device body 710 includes an outer shell 711 and a flexible inner shell 712 connected to the outer shell 711, the outer shell 711 and the flexible inner shell 712 enclose to form a mounting cavity, the massage mechanism 720 is mounted in the mounting cavity, the first actuating component 110 is mounted in the outer shell 711, and the massage member 721 penetrates through the flexible inner shell 712.

The flexible inner shell 712 is used for being attached to a human body when being worn on the human body, and the flexible inner shell 712 may be a flexible shell such as a silicone inner shell or a rubber inner shell. Thus, the wearing comfort can be improved.

Wherein the massage mechanism 720 is partially mounted within the mounting cavity and the second actuator assembly 120 thereof partially extends through the flexible inner housing 712.

Further, as shown in fig. 27-29, an annular elastic retractable portion 7121 is formed on the flexible inner housing 712, the massage component 721 extends through the elastic retractable portion 7121, and an inner edge of the elastic retractable portion 7121 is connected to the massage component 721 or the second actuating assembly 120. Wherein, in the example of fig. 27-29, the inner edge of the resilient flexible portion 7121 is attached to the second actuating assembly 120.

In this way, the ring-shaped elastic retractable portion 7121 may be deformed according to the actuation or movement of the second actuating assembly 120, thereby improving the convenience of use.

Specifically, the elastic stretchable component 7121 may be selected from an elastic wrinkle component, an annular elastic sheet having good stretchability, and the like.

Of course, in other embodiments, a position-avoiding through hole may be formed on the flexible inner shell 712, and the massage component 721 or the second actuating assembly 120 may be movably disposed in the position-avoiding through hole, or the like, so that the massage component 721 is inserted into the flexible inner shell 712.

Further, as shown in fig. 27 to 29, a plurality of massage mechanisms 720 are spaced apart from each other on the device body 710, and there are at least two massage mechanisms 720 having different first actuating directions of the first actuating components 110. Thus, on the one hand, the variety of the massage can be increased, and on the other hand, the space occupied by the plurality of massage mechanisms 720 can be reduced.

Further, the massage mechanism 720 further comprises a sensor (not shown) mounted on the massage component 721, and the sensor is used for detecting the massage parameter of the massage component 721. Wherein, the massage parameters include the distance between the massage part 721 and the massage part, the pressing force and/or the kneading force of the massage part 721 during massage, and the like.

In this way, the actuating positions of the first actuating component 110 and the second actuating component 120 at/before the beginning of the massage can be adjusted according to the massage parameters detected by the sensor (e.g., according to the massage parameters, the first actuating component 110 and/or the second actuating component 120 can be adjusted to actuate first to attach the massage element 721 to the massage position, and then the first actuating component 110 and/or the second actuating component 120 can be activated to actuate the massage), so as to improve the adaptability of the massage device to different users.

The above embodiments are merely examples and are not intended to limit the scope of the present disclosure, and all modifications, equivalents, and flow charts using the contents of the specification and drawings are included in the scope of the present disclosure.

Claims (22)

1. A massage device characterized in that the massage device comprises a device body and a massage mechanism mounted on the device body, the massage mechanism comprising:

a first actuation assembly mounted to the device body, the first actuation assembly having a first actuation direction;

a second actuating assembly mounted to an output of the first actuating assembly, the second actuating assembly having a second actuating direction different from the first actuating direction; an included angle between the second actuating direction and the first actuating direction is greater than or equal to 10 degrees and less than or equal to 170 degrees; and

a massage member mounted to an output of the second actuating assembly.

2. The massage apparatus of claim 1, wherein the massage mechanism further comprises a first connector having a first mounting surface and a second mounting surface, the first mounting surface being at an angle greater than 10 degrees to the second mounting surface, the first mounting surface being connected to the output of the first actuating assembly, the second actuating assembly being mounted to the second mounting surface such that the first actuating direction is different from the second actuating direction.

3. The massaging device of claim 2, wherein the first connecting member is a first connecting block, and the first mounting surface and the second mounting surface are adjacent two side surfaces of the first connecting block respectively.

4. The massage apparatus as recited in claim 3, wherein a mounting groove is provided on the second mounting surface, and the second actuator assembly is mounted to a bottom of the mounting groove.

5. The massage apparatus of claim 2 wherein the first link includes intersecting first and second link plates, the first link plate having a side facing the first actuator assembly that is the first mounting surface, the second link plate being on a side of the first actuator assembly, the second link plate having a side facing away from the actuation centerline of the first actuator assembly that is the second mounting surface.

6. The massaging device of claim 5, wherein the first linkage plate and the second linkage plate are rotatably connected such that an angle between the second actuating direction and the first actuating direction is adjustable.

7. The massage apparatus of claim 1, wherein the second actuator assembly is located on an actuation path of the first actuator assembly, the massage mechanism further comprises an output transducer mounted to an output end of the second actuator assembly, and the output transducer comprises a power output portion located on a side of the second actuator assembly remote from the first actuator assembly, the massage member being mounted to the power output portion.

8. The massage apparatus of claim 7, wherein the massage mechanism further comprises a first linkage including a first linkage plate and a second linkage plate coupled to each other, the first linkage plate being mounted to the output end of the first actuator assembly, the second linkage plate extending toward a side of the first linkage plate remote from the first actuator assembly, the second actuator assembly being mounted to the second linkage plate such that the second actuator assembly is located on the actuation path of the first actuator assembly.

9. The massage apparatus of claim 8, wherein the massage mechanism further comprises a third actuator assembly and a second connector, the second connector comprising a third connecting plate and a fourth connecting plate connected to each other, the third connecting plate being mounted to an output of the third actuator assembly, the fourth connecting plate extending toward a side of the third connecting plate facing the third actuator assembly, the first actuator assembly being mounted to a side of the fourth connecting plate facing away from the third actuator assembly, the third actuator assembly being mounted to the apparatus body.

10. The massaging device of any one of claims 1-8, wherein the angle between the second actuation direction and the first actuation direction is greater than or equal to 60 degrees and less than or equal to 120 degrees.

11. The massaging device of any one of claims 1-8, wherein the first actuating assembly is a flexible actuating assembly for being actuated by deformation to have a first actuating direction; and/or the presence of a gas in the gas,

the second actuating assembly is a flexible actuating assembly and is used for being actuated through deformation to have a second actuating direction.

12. The massage apparatus according to claim 11, wherein the flexible actuating assembly is an electric actuating assembly, the electric actuating assembly comprises at least one electric actuating unit arranged in a stacked manner, the electric actuating unit comprises an electro-deformable layer and electrodes arranged in a stacked manner, the electro-deformable layer is provided with a plurality of layers, two sides of each electro-deformable layer are provided with one electrode, and the same electrode is shared between two adjacent electro-deformable layers; the electrodeformation layer is used for generating deformation when an electric field is applied so as to enable the electric actuating component to have an actuating direction, and two adjacent electrodes are used for forming the electric field; alternatively, the first and second electrodes may be,

the flexible actuating assembly is a photoinduced assembly, the photoinduced assembly comprises at least one photoinduced actuating unit which is arranged in a stacked mode, the photoinduced actuating unit comprises a photoinduced shell, a light source and a photoinduced film, a photoinduced hole is formed in the photoinduced shell, the photoinduced film is arranged at the photoinduced hole, the light source is arranged in the photoinduced shell, and the photoinduced film is used for deforming when being irradiated by the light source so as to enable the photoinduced assembly to have an actuating direction; alternatively, the first and second electrodes may be,

the flexible actuating assembly is an air actuating assembly which comprises at least one air actuating bag arranged in a stacked mode, and the air actuating bag is used for deforming when being inflated so that the air actuating assembly has an actuating direction.

13. The massaging device of any one of claims 1-8, wherein the skin proximal side of the device body has a receiving channel, and the first actuating member is mounted to a bottom or side wall of the receiving channel.

14. The massaging device of any one of claims 1-8, wherein the massaging device is a portable massaging device.

15. The massaging device of claim 14, wherein the portable massaging device is a cervical massaging device, or a lumbar massaging device, or a wrist strap massaging device, or a massaging cushion, or an eye massaging device.

16. The massage apparatus of any one of claims 1-8, wherein the massage mechanism further comprises a third actuating assembly, the third actuating assembly being mounted to the apparatus body, the first actuating assembly being mounted to an output of the third actuating assembly, the third actuating assembly having a third actuating direction, the first actuating direction, the second actuating direction, and the third actuating direction being different.

17. The massage device of claim 16, wherein at least any two of the first actuation direction, the second actuation direction, and the third actuation direction are perpendicular to each other.

18. The massaging device of any one of claims 1-8, wherein the device body comprises an outer shell and a flexible inner shell connected to the outer shell, the outer shell and the flexible inner shell enclosing a mounting cavity, the massaging mechanism being mounted to the mounting cavity, the first actuating member being mounted to the outer shell, and the massaging member extending through the flexible inner shell.

19. The massaging device of claim 18 wherein the inner flexible housing has an annular resilient flexible portion formed thereon through which the massaging element extends, the inner edge of the resilient flexible portion being connected to the massaging element or the second actuating member.

20. The massaging device of any one of claims 1-8, wherein the massaging mechanisms are spaced apart on the device body in a plurality, there being at least two first actuating groups of the massaging mechanisms having different first actuating directions; and/or

The massage mechanism further comprises a sensor, the sensor is mounted on the massage piece, and the sensor is used for detecting massage parameters of the massage piece; and/or

The massage member is integral with the output end of the second actuating assembly.

21. A massage mechanism, characterized in that the massage mechanism comprises:

a first actuation assembly having a first actuation direction;

a second actuating assembly mounted to an output of the first actuating assembly, the second actuating assembly having a second actuating direction different from the first actuating direction; an included angle between the second actuating direction and the first actuating direction is greater than or equal to 10 degrees and less than or equal to 170 degrees; and

a massage member mounted to an output of the second actuating assembly.

22. The massage mechanism of claim 21 wherein the first actuation assembly is a flexible actuation assembly configured to have a first actuation direction via a shape changing actuation; and/or the second actuating assembly is a flexible actuating assembly, and the second actuating assembly is used for being actuated through deformation to have a second actuating direction; and/or the presence of a gas in the gas,

the actuating device further comprises a third actuating assembly, the first actuating assembly is mounted at the output end of the third actuating assembly, the third actuating assembly has a third actuating direction, and the first actuating direction, the second actuating direction and the third actuating direction are different; and/or

The massage mechanism further comprises a sensor, the sensor is mounted on the massage piece, and the sensor is used for detecting massage parameters of the massage piece; and/or

The massage member is integral with the output end of the second actuating assembly.

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