CN215741385U - Massage unit for massage instrument and wearable massage instrument with massage unit - Google Patents

Abstract

The utility model discloses a massage unit for a massage apparatus and a wearable massage apparatus having the same, the massage unit comprising: the unit shell comprises a conductive shell, the vibration component is arranged in the unit shell and comprises a vibration assembly and a buffer component, the conductive component is suitable for being electrically connected with an electric pulse generating device in a machine body of the massager, the conductive component is welded to the inner surface of the conductive shell to form a welding point, so that the electric pulse generating device is electrically connected with the conductive shell through the conductive component, and the buffer component is isolated between the vibration assembly and the welding point. According to the massage unit for the massage instrument, the welding points are arranged in the conductive shell, so that the welding points are prevented from being exposed outside the unit shell and being easily damaged, and the problems that the welding points are exposed to influence the assembly of the conductive shell and other parts outside the conductive shell and the like can be avoided. In addition, the buffer piece is arranged between the welding point and the vibration assembly, so that the vibration influence of the vibration assembly on the welding point can be reduced.

Description

Massage unit for massage instrument and wearable massage instrument with massage unit

Technical Field

The utility model relates to the technical field of massage instruments, in particular to a massage unit for a massage instrument and a wearable massage instrument with the massage unit.

Background

Some massagers in the prior art are provided with a plurality of massage units, but only set up the vibration subassembly in the shell of massage unit usually to realize the vibration massage function, the function is more single, and if will add other functions, for example the electric stimulation massage function, the reliability of electric connection is a difficult problem, for example, the electric connection point easily receives the vibration influence of the vibration subassembly in the electrically conductive shell, causes the electric pulse generating device not good with the electrically conductive shell's of massage unit electric connection stability, influences the effect of electric stimulation massage function.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. To this end, the present invention proposes a massage unit for a massage machine, which can improve the reliability of electrical connection by disposing a solder joint in a conductive case.

The utility model also provides a wearable massage instrument with the massage unit.

A massage unit for a massage machine according to an embodiment of a first aspect of the present invention includes a body having an electric pulse generating device therein, the massage unit including: a unit housing adapted to be coupled to the body, the unit housing including a conductive shell; the vibration component is arranged in the unit shell and comprises a vibration assembly and a buffer piece; and the conductive piece is suitable for being electrically connected with the electric pulse generating device, the conductive piece is welded on the inner surface of the conductive shell to form a welding point, so that the electric pulse generating device is electrically connected with the conductive shell through the conductive piece, and the buffer piece is isolated between the vibration assembly and the welding point.

The massage unit for the massage instrument provided by the embodiment of the utility model at least has the double functions of vibration massage and electric stimulation massage, is rich in functions, and the electric pulse generating device is arranged on the machine body and is electrically connected with the conductive shell through the conductive piece, so that the volume of the massage unit with more functions can be better ensured to be small, and the problems that the welding point is exposed outside the unit shell and is easy to damage and poor in connection can be avoided as the welding point is positioned in the conductive shell, and the problems that the welding point affects the assembly of other parts outside the conductive shell and the like can be avoided. In addition, through set up the bolster between welding point and vibration subassembly to can avoid the vibration subassembly to directly transmit the vibration to the welding point, in order to avoid causing the problem of bad connection or damage because the vibration of vibration subassembly to the welding point, and then guarantee that the electric connection between electrically conductive piece and the electrically conductive shell is comparatively reliable and stable, improve the reliability and the stability of electro photoluminescence massage function.

In some embodiments of the present invention, the conductive case includes an end cover portion located at an end of the unit case facing away from the machine body, and a peripheral wall portion connected to a side of the end cover portion facing the machine body and surrounding the vibration member, the conductive member being welded to an inner surface of the peripheral wall portion.

In some embodiments of the present invention, a side of the peripheral wall portion facing away from the end cover portion defines a mounting opening, and the vibration member is adapted to be fitted into the conductive shell through the mounting opening.

In some embodiments of the present invention, the peripheral wall portion includes a plurality of sub-wall sections arranged at intervals in a circumferential direction, a spacing groove penetrating to the mounting opening is formed between adjacent two of the sub-wall sections, and the conductive member is welded to an inner surface of the sub-wall sections.

In some embodiments of the present invention, the conductive case includes an end cover portion located at an end of the unit case facing away from the machine body, and a peripheral wall portion connected to a side of the end cover portion facing the machine body and surrounding the vibration member, the conductive member being welded to an inner surface of the end cover portion.

In some embodiments of the utility model, there is a fit clearance between the vibration member and the end cap portion, the fit clearance being adapted to accommodate the weld.

In some embodiments of the utility model, the weld is located in a central region of the end cap portion.

In some embodiments of the present invention, two ends of the conductive member are a welding end and an electrical connection end, respectively, the welding end is located in the conductive shell and welded to the conductive shell to form the welding point, one side end of the unit shell facing the machine body has a through hole, and the electrical connection end penetrates out of the unit shell through the through hole to be suitable for connecting an electrical pulse generating device.

In some embodiments of the present invention, the conductive component includes a welding section, a bending section, and a pulling section, the welding section is located between the vibration component and the conductive shell, the bending section is stopped and limited on a side of the vibration component facing the machine body, one end of the bending section is connected to the welding section, the other end of the bending section is connected to the pulling section, one end of the welding section away from the bending section is welded to an inner surface of the conductive shell to form the welding point, and one end of the pulling section away from the bending section extends toward the machine body to be suitable for connecting an electrical pulse generating device.

In some embodiments of the present invention, the buffer member includes a flexible sleeve disposed within the unit housing, the vibration assembly is disposed within the flexible sleeve, and the flexible sleeve is interference fit between the unit housing and the vibration assembly.

In some embodiments of the present invention, the flexible sleeve covers the welding point and is pressed and deformed by the welding point, or a first avoidance area for avoiding the welding point is arranged on the outer surface of the flexible sleeve.

In some embodiments of the present invention, the inner peripheral wall of the unit housing has a first positioning structure, the flexible sleeve includes a peripheral buffering portion disposed between the inner peripheral wall of the unit housing and the vibration assembly, the peripheral buffering portion has a second positioning structure in positioning fit with the first positioning structure, and the first positioning structure and the second positioning structure are in positioning fit to limit the flexible sleeve from rotating relative to the unit housing.

In some embodiments of the utility model, one of the first positioning structure and the second positioning structure comprises a first positioning groove, the other comprises a first protrusion which is matched with the first positioning groove in a positioning mode, the conductive shell defines a mounting opening, the first positioning groove penetrates through the mounting opening, and the vibration part is suitable for being mounted into the conductive shell through the mounting opening.

In some embodiments of the present invention, the conductive shell includes an end cover portion and a peripheral wall portion, the end cover portion is located at one end of the unit housing facing away from the machine body, the peripheral wall portion is connected to a side of the end cover portion facing the machine body and surrounds the vibration member, a side of the peripheral wall portion facing away from the end cover portion defines the mounting opening, the peripheral wall portion includes a plurality of sub-wall sections arranged at intervals in a circumferential direction, a spacing groove penetrating to the mounting opening is formed between two adjacent sub-wall sections, at least one of the spacing grooves serves as the first positioning groove, and the first protrusion is provided on the peripheral buffer portion.

In some embodiments of the present invention, the unit case further includes a connection case for connecting the body, the peripheral wall portion is inserted into the connection case, the spacing groove includes a second positioning groove, a second protrusion is formed on an inner surface of the connection case, the second protrusion is fitted into the second positioning groove, and the vibration member is adapted to be fitted into the conductive case and/or the connection case before the connection case is assembled with the conductive case.

In some embodiments of the utility model, the conductive shell comprises an end cap portion at an end of the unit housing facing away from the body, the massage unit further comprising: and the heating part comprises a heating part positioned between the vibration part and the end cover part, and the heating part can transfer heat to the end cover part.

In some embodiments of the present invention, the heat generating portion is a metal sheet, or the heat generating component is a heat generating film, the heat generating film includes a main body section and an extension section, the main body section is used as the heat generating portion and is located between the vibration component and the end cover portion, one end of the extension section is connected to the main body section, and the other end of the extension section extends to a side of the vibration component away from the end cover portion.

In some embodiments of the utility model, a side of the heat generating portion facing away from the end cover portion is provided with a temperature detector.

In some embodiments of the present invention, the vibration component includes a flexible sleeve, the flexible sleeve is disposed in the unit housing, the vibration component is disposed in the flexible sleeve, the flexible sleeve is in interference fit between the unit housing and the vibration component and isolated between the vibration component and the welding point, the flexible sleeve is compressed and presses the heating portion to contact with the end cover portion by elastic force to transfer heat, the flexible sleeve includes a top buffer portion between the vibration component and the end cover portion, and the top buffer portion has a second avoiding region for avoiding the temperature detector.

In some embodiments of the present invention, the second avoidance region is an avoidance blind groove recessed toward a direction away from the heat generating portion, and a bottom wall of the avoidance blind groove is used for blocking heat transfer between the vibration assembly and the temperature detector.

In some embodiments of the utility model, a flexible pad is provided between the heat generating portion and the vibrating member, the flexible pad being clamped between the heat generating portion and the vibrating member.

In some embodiments of the present invention, the conductive shell includes an end cover portion at an end of the unit housing facing away from the machine body, a side of the conductive shell facing away from the end cover portion defines a mounting opening, the vibration member is adapted to be interference-fitted to the conductive shell by the mounting opening, the unit housing further includes a connection shell adapted to be connected to the machine body, and the connection shell is connected to the conductive shell to close the mounting opening.

In some embodiments of the utility model, the connection housing comprises a stop portion which stops at a side of the vibration member facing away from the end cap portion.

In some embodiments of the utility model, the stopper is located outside the conductive shell.

In some embodiments of the present invention, the connection shell includes a mounting section and a connection section, the mounting section is connected to the conductive shell, the connection section is adapted to be connected between the machine body and the mounting section, the connection section and the mounting section are both hollow cylindrical, and a cross-sectional area of the connection section is smaller than a cross-sectional area of the mounting section, so that a step surface is formed at a connection portion of the mounting section and the connection section, and the step surface serves as the stopper to stop against the vibration component.

In some embodiments of the utility model, the stopper extends into the conductive shell.

In some embodiments of the utility model, the connecting shell includes an outer ring segment and an inner ring segment, the inner ring segment is disposed in the outer ring segment, and an insertion groove is defined between the inner ring segment and the outer ring segment, the conductive shell further includes a peripheral wall portion, the peripheral wall portion is connected to one side of the end cover portion facing the machine body and surrounds the vibration component, the peripheral wall portion is inserted in the insertion groove, and the inner ring segment serves as the stopper portion to stop against the vibration component.

In some embodiments of the present invention, the connection shell includes a hard mounting section, the hard mounting section is a hollow cylinder, the conductive shell further includes a peripheral wall portion, the peripheral wall portion is connected to one side of the end cover portion facing the machine body and surrounds the vibration component, and the peripheral wall portion is in plug-in fit and clamping connection with the hard mounting section.

In some embodiments of the present invention, the peripheral wall portion is inserted into the hard mounting section, a buckle is formed on an inner cylindrical surface of the hard mounting section, a clamping hole is formed on the peripheral wall portion, and the buckle is clamped with the clamping hole.

In some embodiments of the present invention, the peripheral wall portion is inserted into the hard mounting section in an interference manner, and the peripheral wall portion includes a plurality of sub-wall sections arranged at intervals along the circumferential direction, a spacing groove is formed between two adjacent sub-wall sections, and the fastening hole is formed on the sub-wall sections.

In some embodiments of the present invention, the spacer slot extends through to the mounting opening and includes a second positioning slot, and the hard mounting segment has a second protrusion formed on an inner surface thereof, the second protrusion fitting into the second positioning slot.

In some embodiments of the present invention, the connection shell includes a flexible mounting section defining a fitting groove, and the conductive shell further includes a peripheral wall portion connected to a side of the end cover portion facing the body and surrounding the vibration member, the peripheral wall portion being fitted into and bonded to the fitting groove.

In some embodiments of the present invention, the peripheral wall portion includes an outer wall section and an inner wall section which are connected in sequence in a direction away from the end cover portion, the outer wall section has a cross-sectional area larger than that of the inner wall section, the inner wall section is inserted into the insertion groove, the outer wall section is located outside the insertion groove, and an outer peripheral surface of the outer wall section is flush with an outer peripheral surface of the flexible mounting section.

In some embodiments of the present invention, the connection shell includes a mounting section and a connection section, the mounting section is connected to the conductive shell, the connection section is adapted to be connected between the machine body and the mounting section, the connection section is hard and is adapted to be a separate piece from the machine body, or the connection section is made of a flexible material and is adapted to be a single piece with the mounting plate of the machine body.

In some embodiments of the utility model, the connecting shell is a non-conductive material.

In some embodiments of the utility model, the conductive shell is a metal shell.

The wearable massage apparatus according to the embodiment of the second aspect of the utility model comprises a body and a plurality of massage units for the massage apparatus according to the embodiment of the first aspect of the utility model, wherein the massage units are connected with the body, and the body is internally provided with an electric pulse generating device.

According to the wearable massage apparatus of the utility model, by arranging the massage unit for the massage apparatus of the embodiment of the first aspect, the massage apparatus at least has the dual functions of vibration massage and electrical stimulation massage, and has rich functions, and the electric pulse generating device is arranged in the body and is electrically connected with the conductive shell through the conductive piece, so that the massage unit with more functions can be ensured to have smaller volume, and the welding point is positioned in the conductive shell, so that the problems that the welding point is exposed outside the unit shell and is easily damaged and the connection is poor can be avoided, and the problems that the welding point affects the assembly of other parts outside the conductive shell and the like can be avoided. In addition, through set up the bolster between welding point and vibration subassembly to can avoid the vibration subassembly to directly transmit the vibration to the welding point, in order to avoid causing the problem of bad connection or damage because the vibration of vibration subassembly to the welding point, and then guarantee that the electric connection between electrically conductive piece and the electrically conductive shell is comparatively reliable and stable, improve the reliability and the stability of electro photoluminescence massage function.

In some embodiments of the utility model, the wearable massager is a neck massager, an eye massager or a waist massager.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

FIG. 1 is a perspective view of a massage apparatus according to one embodiment of the present invention;

FIG. 2 is a front view of one of the massage units shown in FIG. 1;

fig. 3 is an exploded view of the massage unit shown in fig. 2;

FIG. 4 is a schematic diagram of the welding of a conductive shell to a conductive member according to one embodiment of the present invention;

FIG. 5 is a cross-sectional view of the conductive shell and conductive member shown in FIG. 4;

FIG. 6 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 7 is a schematic diagram of the welding of a conductive shell to a conductive member according to another embodiment of the present invention;

fig. 8 is a cross-sectional view of the conductive shell and conductive member shown in fig. 7;

fig. 9 is a sectional view of the conductive shell and the conductive member shown in fig. 8 applied to a massage unit;

FIG. 10 is a perspective view of a flexible sleeve according to one embodiment of the present invention;

FIG. 11 is a cross-sectional view taken along line C-C of FIG. 9;

FIG. 12 is a cross-sectional view taken along line B-B of FIG. 2;

FIG. 13 is a perspective view of a coupling housing according to one embodiment of the utility model;

FIG. 14 is a front view of the coupling housing shown in FIG. 13;

FIG. 15 is a cross-sectional view taken along line D-D of FIG. 14;

fig. 16 is a perspective view of a massage apparatus according to another embodiment of the present invention;

fig. 17 is a schematic view of the connection of the massage unit shown in fig. 16 to the mounting plate;

FIG. 18 is a cross-sectional view taken along line E-E of FIG. 17;

fig. 19 is a perspective view of the conductive shell shown in fig. 18;

FIG. 20 is a cross-sectional view of the attachment housing shown in FIG. 18 to a mounting plate;

fig. 21 is an enlarged view of portion F shown in fig. 18;

fig. 22 is a perspective view of a heat generating member according to an embodiment of the present invention;

fig. 23 is a perspective view of another angle of the heat generating member shown in fig. 22.

Reference numerals:

a massage apparatus 1000;

a massage unit 100; a body 200; a mounting plate 201;

a unit case 1; a conductive shell 11;

an end cap portion 111;

a peripheral wall portion 112; a sub-wall segment 1121; a card hole 11210;

the partition grooves 1122; a first positioning groove 11221; a second positioning groove 11222;

an outer wall section 1123; an inner wall section 1124; a mounting opening 114;

the connecting shell 12; a stopper portion 1201; a mounting section 1202;

a rigid mounting section 121; a fastener 1211; a second projection 1212;

a connecting section 122; a step surface 123;

a flexible mounting section 124; a mating slot 1241; an outer ring section 1242; an inner ring section 1243;

a perforation 125;

a vibration member 2; a vibrating assembly 21; a buffer member 22; a flexible sleeve 221; a spacer 222;

a first avoidance area 2211; a peripheral buffer portion 2212; the first projection 2213;

a top buffer 2214; a second avoidance area 2215; a bottom wall 2216 of the avoidance blind slot;

a conductive member 3; a weld 30; a welding section 31; a bending section 32; a pull wire segment 33;

a heat generating member 4; a heat generating portion 40; a main body section 41; an extension 42; a connection end 421; a heater 43;

a temperature detector 5; a flexible pad 6; and a third escape area 61.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

The following disclosure provides many different embodiments, or examples, for implementing different features of the utility model. To simplify the disclosure of the present invention, the components and arrangements of specific examples are described below. Of course, they are merely examples and are not intended to limit the present invention. Furthermore, the present invention may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. In addition, the present invention provides examples of various specific processes and materials, but one of ordinary skill in the art may recognize the applicability of other processes and/or the use of other materials.

Next, with reference to the drawings, a massage unit 100 for a massage apparatus 1000 according to an embodiment of the first aspect of the present invention is described. It should be noted that the specific type of the massage apparatus 1000 applied to the massage unit 100 is not limited, and may be, for example, an eye massage apparatus 1000, a neck massage apparatus 1000, a waist massage apparatus 1000, a handheld massage apparatus 1000, and the like.

As shown in fig. 1, the massage apparatus 1000 includes a body 200 and at least one massage unit 100, and in conjunction with fig. 2 and 3, the massage unit 100 includes: the unit comprises a unit shell 1 and a vibration part 2, wherein the unit shell 1 is suitable for being connected with the machine body 200, the vibration part 2 is arranged in the unit shell 1 and comprises a vibration component 21, and therefore when the vibration component 21 works, the vibration massage can be carried out on the human body through the contact of the unit shell 1 and the human body. It should be noted that "connection" in "the unit case 1 is adapted to be connected to the machine body 200" is to be understood in a broad sense, and may be a separate member and assembled to be connected, or may be an integral member. For example, when being a separate piece and assembled to be connected, the unit case 1 is assembled to be connected with a corresponding portion of the body 200. For example, when the unit housing 1 is formed as a single piece, at least a portion of the unit housing and a corresponding portion of the machine body 200 may be formed as a single piece, and may be formed by injection molding of a single material, or by secondary injection molding, for example, as long as the two pieces are not detachable.

The body 200 has an electric pulse generating device therein, and with reference to fig. 3 and 4, the massage unit 100 further includes a conductive member 3, the unit housing 1 includes a conductive shell 11, the conductive member 3 is welded to the conductive shell 11 to form an electrical connection, the conductive member 3 is adapted to be electrically connected to the electric pulse generating device, so that the electric pulse generating device is electrically connected to the conductive shell 11 through the conductive member 3, and thus when the electric pulse generating device works, the electric pulse generating device can be electrically conducted to the human body through the conductive shell 11, so as to perform an electric stimulation massage on the human body. Accordingly, the electric pulse generating device having a large volume is installed in the body 200, not integrated in the massage unit 100, so that the volume of the massage unit 100 can be simply and effectively reduced, and a larger number of massage units 100 can be installed in the same installation area of the body 200, thereby improving a massage effect. It should be noted that the conductive shell 11 is not limited to be electrically conducted with the human body, for example, the conductive shell 11 may be directly contacted with the human body to realize direct electrical conduction between the conductive shell 11 and the human body, or a conductive layer, such as a conductive gel, may be disposed on the conductive shell 11, and the conductive shell 11 may be directly contacted with the human body through the conductive layer to realize indirect electrical conduction between the conductive shell 11 and the human body.

Referring to fig. 4 to 5 and fig. 7 to 8, the conductive member 3 is welded to the inner surface of the conductive shell 11, that is, the conductive member 3 is welded to the conductive shell 11 to form a welding point 30, and the welding point 30 is located on the inner surface of the conductive shell 11. In short, the electric pulse generating device in the housing 200 is welded to the inner surface of the conductive shell 11 through the conductive member 3 to form the welding point 30. Therefore, the problems that the welding point 30 is exposed outside the unit shell 1 and is easy to be damaged and the connection is poor can be avoided, so that the electric connection reliability of the conductive shell 11 and the electric pulse generating device is ensured, and the effectiveness and the reliability of the electric stimulation massage are ensured. Moreover, since the welding point 30 is located inside the conductive shell 11, the welding point 30 does not affect the assembly connection of other parts (such as a connecting shell 12 described later) outside the conductive shell 11 and the conductive shell 11.

Referring to fig. 6 and 9, the vibration member 2 further includes a buffer 22, and the buffer 22 is isolated between the vibration assembly 21 and the pad 30. That is to say, at least part of the buffer member 22 is located between the vibration component 21 and the welding point 30, so that the vibration component 21 can be prevented from directly transmitting vibration to the welding point 30, the problem of poor connection or damage to the welding point 30 due to the vibration of the vibration component 21 can be avoided, the electric connection between the conductive member 3 and the conductive shell 11 can be ensured to be stable and reliable, and the reliability and stability of the electric stimulation massage function can be improved.

In summary, the massage unit 100 according to the embodiment of the present invention at least has the dual functions of vibration massage and electrical stimulation massage, and has a rich function, and the electrical pulse generator is disposed in the body 200 and electrically connected to the conductive shell 11 through the conductive member 3, so as to better ensure that the volume of the massage unit 100 with a large number of functions is small, and since the welding point 30 is located in the conductive shell 11, the problems that the welding point 30 is exposed outside the unit housing 1 and is easily damaged and the connection is poor can be avoided, and the problems that the assembly of other parts outside the conductive shell 11 and the conductive shell 11 is affected can be avoided. In addition, through set up bolster 22 between welding point 30 and vibration subassembly 21 to can avoid vibration subassembly 21 directly to transmit the vibration to welding point 30, in order to avoid causing the problem of bad connection or damage to welding point 30 because the vibration of vibration subassembly 21, and then guarantee that the electric connection between electrically conductive 3 and the conductive shell 11 is comparatively reliable and stable, improve the reliability and the stability of electro photoluminescence massage function.

It should be noted that the specific position where the conductive member 3 is welded to the inner surface of the conductive shell 11 is not limited, for example, two specific embodiments will be described later, but the present invention is not limited to these two embodiments.

First embodiment, as shown in fig. 4 and 5, the conductive shell 11 includes an end cover portion 111 and a peripheral wall portion 112, the end cover portion 111 is located at an end of the unit case 1 facing away from the machine body 200, the peripheral wall portion 112 is connected to a side of the end cover portion 111 facing the machine body 200 and surrounds the vibration member 2, and the conductive member 3 is welded to an inner surface of the peripheral wall portion 112. This eliminates the need to weld a narrow space near the end cover 111 inside the conductive shell 11, facilitates welding at the peripheral wall 112, facilitates handling, and ensures welding quality. Moreover, since the welding point 30 is located on the inner surface of the peripheral wall portion 112, the fitting connection of other parts (such as a connecting shell 12 described later) outside the conductive shell 11 and the conductive shell 11 is not affected by the projection of the welding point 30 on the peripheral wall portion 112.

Further, as shown in fig. 4 to 6, a side of the peripheral wall portion 112 facing away from the end cover portion 111 defines a mounting opening 114, and the vibration member 2 is adapted to be mounted into the conductive shell 11 through the mounting opening 114. So that the structure of the conductive case 11 can be simplified and the installation of the vibration part 2 can be facilitated. Further, when the conductive member 3 is welded to the inner surface of the peripheral wall portion 112, it is possible to ensure that the welding position is relatively close to the mounting opening 114, and it is understood that, in order to ensure the mounting of the vibration member 2, the open area at the mounting opening 114 is relatively large, and therefore, the welding point 30 is provided on the inner surface of the peripheral wall portion 112 defining the mounting opening 114, which can further ensure the welding space, facilitate the welding operation, and facilitate the improvement of the welding quality. Of course, the present invention is not limited thereto, and the side of the peripheral wall 112 away from the end cover portion 111 may not define the mounting opening 114, and in this case, for example, a mounting notch may be provided on the peripheral wall 112, that is, a mounting notch may be provided on a side surface of the conductive shell 11, so that the vibration component 2 is mounted in the conductive shell 11 through the mounting notch on the side surface, which is not described herein again.

For example, in the specific example shown in fig. 4, the peripheral wall portion 112 includes a plurality of sub-wall sections 1121 arranged at intervals in the circumferential direction, a spacing groove 1122 penetrating to the mounting opening 114 is formed between two adjacent sub-wall sections 1121, and the conductive member 3 is welded to the inner surface of the sub-wall section 1121. Thus, since the peripheral wall portion 112 includes the plurality of sub-wall portions 1121 provided at intervals in the circumferential direction, the peripheral wall portion 112 is easily deformed, so that the mounting of the vibration member 2 into the conductive case 11 is facilitated, and the mounting of the conductive case 11 and other parts (for example, a later-described connection case 12) outside the conductive case 11 and the like is also facilitated by the feature that the peripheral wall portion 112 is easily deformed. In addition, the conductive member 3 is welded to the inner surface of the sub-wall section 1121, so that the characteristic that the sub-wall section 1121 is easy to deform can be utilized, the problem that the welding point 30 and the vibration component 2 are mutually extruded is solved, vibration transmitted from the vibration component 2 to the welding point 30 is reduced, and the problem that the welding point 30 is damaged is avoided. Of course, the present invention is not limited thereto, and a structure for avoiding the welding point 30 may be provided on the buffer 22, which is not described herein.

Second embodiment, as shown in fig. 7 and 8, the conductive shell 11 includes an end cover portion 111 and a peripheral wall portion 112, the end cover portion 111 is located at an end of the unit case 1 facing away from the machine body 200, the peripheral wall portion 112 is connected to a side of the end cover portion 111 facing the machine body 200 and surrounds the vibration member 2, and the conductive member 3 is welded to an inner surface of the end cover portion 111. Therefore, since the welding point 30 is located on the inner surface of the end cap portion 111, the problem that the welding point 30 protrudes from the inner side of the peripheral wall portion 112 to affect the installation of the vibration member 2 into the conductive shell 11 is avoided, and when the vibration member 2 and the peripheral wall portion 112 are in interference fit, the problem that the welding point 30 and the vibration member 2 are pressed against each other can be effectively avoided, so that the vibration transmitted from the vibration member 2 to the welding point 30 is reduced, and the problem that the welding point 30 is damaged is avoided.

Moreover, the welding point 30 is arranged on the inner surface of the end cover part 111, so that the vibration component 2 is easy to avoid the welding point 30, the vibration transmission of the vibration component 2 to the welding point 30 is reduced, and the problem of damage to the welding point 30 is avoided. For example, in some cases, as shown in fig. 9, a fit clearance exists between the vibration component 2 and the end cover portion 111, and the fit clearance is suitable for accommodating the welding point 30, so that the vibration component 2 can avoid the welding point 30, the vibration transmission of the vibration component 2 to the welding point 30 is reduced, and the problem of damage to the welding point 30 is avoided. For example, in some specific examples, the vibration member 2 may be configured to have an interference fit with the peripheral wall portion 112 to ensure that a certain gap is left between the vibration member 2 and the end cover portion 111 for receiving and avoiding the welding point 30. Of course, the present invention is not limited thereto, and a structure for avoiding the welding point 30 may be provided on the buffer 22, which is not described herein.

In the specific example shown in fig. 7 and 8, the welding point 30 is located in the central region of the end cap section 111. Note that, the center region refers to: an auxiliary ring having the same contour shape as the end cap 111 and reduced by 0.5 times in an equal ratio is formed on the end cap 111, and the inner region of the auxiliary ring is the center region. Thus, by providing the welding point 30 in the central region of the end cap portion 111, the position of the welding point 30 is made easy for the welding operation. Of course, the present invention is not limited to this, and in other embodiments of the present invention, the welding point 30 may be disposed in the peripheral region of the end cover portion 111, that is, the region of the end cover portion 111 located outside the auxiliary ring.

It should be noted that the specific structural form of the conductive member 3 is not limited as long as it can be suitable for welding with the conductive shell 11 and connecting with the electric pulse generating device, for example, some specific embodiments will be given below, but the present invention is not limited to the following embodiments.

In some embodiments of the present invention, as shown in fig. 6 and 9, two ends of the conductive component 3 are a welding end and an electrical connection end, respectively, the welding end is located in the conductive shell 11 and welded to the conductive shell 11 to form the welding point 30, one side end of the unit housing 1 facing the machine body 200 has a through hole 125, and the electrical connection end penetrates out of the unit housing 1 through the through hole 125 to be suitable for connecting the electrical pulse generating device. Thus, it is not necessary to connect the conductive member 3 to a lead wire for connecting an electric pulse generating device in a narrow space inside the unit case 1, thereby improving operability. Moreover, since the conductive member 3 penetrates through the through hole 125 at the end of the unit case 1 facing the body 200, the distance between the conductive member 3 and the body 200 can be shortened, the conductive member 3 can be conveniently connected to the electric pulse generating device in the body 200, the appearance neatness can be improved, and the problems of electric leakage, damage and the like caused by the leakage of the conductive member 3 can be avoided.

With reference to fig. 4-9, in some specific examples, the conductive component 3 includes a welding segment 31, a bending segment 32, and a pulling segment 33, the welding segment 31 is located between the vibration component 2 and the conductive shell 11, the bending segment 32 is stopped and limited on a side of the vibration component 2 facing the machine body 200, one end of the bending segment 32 is connected to the welding segment 31, the other end of the bending segment 32 is connected to the pulling segment 33, one end of the welding segment 31 far away from the bending segment 32 can be the welding end and is welded to the inner surface of the conductive shell 11 to form the welding point 30, and one end of the pulling segment 33 far away from the bending segment 32 extends toward the machine body 200 to be suitable for connecting the electric pulse generating device. It should be noted that the "stop" described herein is not limited to a direct or indirect contact stop, and may also be a non-contact stop, for example, in which case the vibration member 2 may be stopped after moving a certain distance in a direction away from the end cover portion 111.

Therefore, the shapes of the welding section 31 and the bending section 32 can better adapt to the appearance of the vibration component 2, the vibration component 2 can be better attached or tightly attached, and the occupied space of the conductive piece 3 in the unit shell 1 can be saved, so that the massage unit 100 is more compact and small in structure. Moreover, the bending section 32 can be used to limit or even press the vibration component 2, so as to limit the vibration component 2 from moving relative to the conductive shell 11 in a direction away from the end cap portion 111 to a certain extent, thereby improving the installation stability and operational reliability of the vibration component 2. It is understood that when the conductive member 3 is welded to the inner surface of the end cover portion 111, an end of the welding section 31 remote from the bending section 32 may extend to the inner surface of the end cover portion 111, and when the conductive member 3 is welded to the inner surface of the peripheral wall portion 112, an end of the welding section 31 remote from the bending section 32 may extend to the inner surface of the peripheral wall portion 112.

Moreover, by providing the pull segment 33, the distance between the conductive member 3 and the body 200 can be shortened, thereby facilitating the connection between the conductive member 3 and the electric pulse generating device in the body 200. Optionally, since the end of the wire segment 33 extending toward the body 200 may be the electrical connection end and penetrates out of the unit housing 1 through the through hole 125, the distance between the conductive element 3 and the body 200 may be more effectively shortened, the conductive element 3 may be conveniently connected to the electrical pulse generating device in the body 200, and the appearance cleanness may be improved to avoid the problems of leakage, damage and the like caused by the leakage of the conductive element 3. Of course, without being limited thereto, the end of the wire segment 33 extending toward the body 200 may be located inside the unit case 1.

It should be noted that the specific form of the buffer member 22 is not limited, for example, some specific embodiments will be given later, but the present invention is not limited to the following embodiments.

In some embodiments of the present invention, as shown in fig. 2 and 6, the buffer member 22 includes a flexible sleeve 221, the flexible sleeve 221 is disposed in the unit case 1, and the vibration assembly 21 is disposed in the flexible sleeve 221 and presses the flexible sleeve 221 together with the unit case 1. That is, the flexible cover 221 has elasticity, when the massage unit 100 except the flexible cover 221 is not installed in the unit housing 1, the space in the unit housing 1 is not sufficient for installing the flexible cover 221 in an uncompressed state, when the vibration assembly 21 is installed in the flexible cover 221 and the flexible cover 221 is installed in the unit housing 1, the flexible cover 221 is interference-fitted between the unit housing 1 and the vibration assembly 21, and the flexible cover 221 is compressed by the co-pressing of the vibration assembly 21 and the unit housing 1 and accumulates elastic force to improve the installation stability and reliability of the vibration assembly 21 in the unit housing 1.

Therefore, when the vibration component 21 vibrates, the vibration component 21 can stably and reliably drive the unit housing 1 to vibrate through the flexible sleeve 221, so that the unit housing 1 can form a reliable and effective vibration massage effect on a human body, namely, the reliability and the stability of the vibration massage function are improved. And, because the flexible cover 221 is the flexible material spare, not only conveniently install flexible cover 221 in unit shell 1 to and conveniently install vibration subassembly 21 in the flexible cover 221, can realize the cushioning effect moreover, separation vibration subassembly 21 directly transmits the vibration to welding point 30, avoids welding point 30 to receive the vibration damage or connect badly, guarantees that the electric connection between electrically conductive 3 and the electrically conductive shell 11 is comparatively reliable and stable, improves the reliability and the stability of electric stimulation massage function.

In some embodiments of the present invention, as shown in fig. 6, the flexible sheath 221 may cover the welding point 30 and be pressed and deformed by the welding point 30. Therefore, the flexible sleeve 221 can avoid the welding point 30 through deformation to avoid the problem that the welding point 30 is badly connected or damaged due to rigid extrusion of the welding point 30, so that the electric connection between the conductive piece 3 and the conductive shell 11 is stable and reliable, and the reliability and the stability of the electric stimulation massage function are improved.

Alternatively, in other embodiments of the utility model, as shown in fig. 9, the outer surface of the flexible sleeve 221 has a first avoidance area 2211 thereon for avoiding the weld 30. Therefore, the flexible sleeve 221 can avoid the welding point 30 through the first avoiding region 2211 to avoid extruding the welding point 30 and cause the problem of poor connection or damage of the welding point 30, so that the electric connection between the conductive piece 3 and the conductive shell 11 is ensured to be stable and reliable, and the reliability and the stability of the electric stimulation massage function are improved. Alternatively, the first avoidance region 2211 can be a blind slot or a through slot.

In some embodiments of the present invention, the inner peripheral wall of the unit housing 1 has a first positioning structure, the flexible sleeve 221 includes a peripheral buffering portion 2212 disposed between the inner peripheral wall of the unit housing 1 and the vibration assembly 21, the peripheral buffering portion 2212 has a second positioning structure in positioning fit with the first positioning structure, and the first positioning structure and the second positioning structure are in positioning fit to limit the rotation of the flexible sleeve 221 relative to the unit housing 1. Accordingly, the positioning of the first positioning structure and the second positioning structure can be matched to each other, whereby the positioning reliability of the peripheral buffering portion 2212 and the unit case 1 can be improved, and the mounting stability of the vibration member 2 can be further improved.

Alternatively, as shown in fig. 10 and 11, one of the first positioning structure and the second positioning structure comprises a first positioning groove 11221, the other comprises a first protrusion 2213 matched with the first positioning groove 11221 in a positioning way, the conductive shell 11 defines a mounting opening 114, the first positioning groove 11221 penetrates through the mounting opening 114, and the vibration part 2 is suitable for being mounted in the conductive shell 11 through the mounting opening 114. Therefore, the first positioning structure and the second positioning structure are simple in structure and convenient to process. In addition, during the process of installing the vibration component 2 into the installation opening 114, the first protrusion 2213 is matched with the first positioning groove 11221, so that the matching of the first protrusion 2213 and the first positioning groove 11221 can play a role of guiding and positioning, so that the flexible sleeve 221 can be quickly and accurately assembled in the conductive shell 11.

In some specific examples, as shown in fig. 7, 10 to 11, the conductive shell 11 includes an end cover portion 111 and a peripheral wall portion 112, the end cover portion 111 is located at one end of the unit housing 1 facing away from the machine body 200, the peripheral wall portion 112 is connected to one side of the end cover portion 111 facing the machine body 200 and surrounds the vibration member 2, one side of the peripheral wall portion 112 facing away from the end cover portion 111 defines the mounting opening 114, the peripheral wall portion 112 includes a plurality of sub-wall sections 1121 arranged at intervals in the circumferential direction, a spacing groove 1122 is formed between two adjacent sub-wall sections 1121, at least one spacing groove 1122 serves as a first positioning groove 11221, and a first protrusion 2213 is provided on the peripheral buffer portion 2212. Accordingly, the first positioning groove 11221 and the first projection 2213 are simply formed and easily obtained, and the peripheral wall portion 112 includes a plurality of sub-wall portions 1121 provided at intervals in the circumferential direction, so that the peripheral wall portion 112 is easily deformed, thereby facilitating the mounting of the vibration member 2 into the conductive case 11, and also facilitating the mounting of the conductive case 11 and other parts (such as a connecting case 12 described later) or the like outside the conductive case 11 by utilizing the characteristic that the peripheral wall portion 112 is easily deformed.

In some embodiments of the present invention, as shown in fig. 2, the unit case 1 further includes a connection case 12 for connecting the body 200, the peripheral wall portion 112 is inserted into the connection case 12, and the vibration member 2 is adapted to be fitted into the conductive case 11 and/or the connection case 12 before the connection case 12 is assembled with the conductive case 11. Thus, by providing the unit case 1 including the conductive shell 11 and the connection shell 12 which are plug-fit, and the vibration member 2 is adapted to be fitted into the conductive shell 11 and/or the connection shell 12 before the connection shell 12 is assembled with the conductive shell 11, it is possible to improve the ease of assembly of the vibration member 2. In addition, it should be noted that "connection" in "the connection housing 12 is adapted to be connected to the machine body 200" is to be understood in a broad sense, and may be a separate member and assembled to be connected, or may be an integral member. For example, when being a separate piece and assembled together, the coupling housing 12 is assembled with the corresponding portion of the body 200. For example, when the connecting shell 12 is a single piece, at least a portion of the connecting shell and a corresponding portion of the housing 200 are a single piece, and may be formed by injection molding of a single material, or by secondary injection molding, for example, as long as the connecting shell is not detachable.

Further, when the peripheral wall portion 112 includes a plurality of sub-wall sections 1121 arranged at intervals in the circumferential direction, and a separation groove 1122 penetrating to the mounting opening 114 is formed between two adjacent sub-wall sections 1121, the peripheral wall portion 112 is easily deformed, and the peripheral wall portion 112 is conveniently inserted into the connecting shell 12. Optionally, the peripheral wall portion 112 and the connecting shell 12 are in interference fit, so that the connection reliability of the connecting shell 12 and the conductive shell 11 can be improved, and the connection difficulty can be reduced.

Alternatively, as shown in fig. 7, 11 and 13, the spacing groove 1122 includes a second positioning groove 11222, so that the second positioning groove 11222 also extends to the mounting opening 114, and a second protrusion 1212 is formed on the inner surface of the connection housing 12, and the second protrusion 1212 is fitted into the second positioning groove 11222. Therefore, in the process of inserting the peripheral wall part 112 into the connecting shell 12, the second protrusion 1212 and the second positioning groove 11222 are matched in a following manner, so that the matching of the second protrusion 1212 and the second positioning groove 11222 can play a role of guiding and positioning, so that the peripheral wall part 112 can be quickly and accurately assembled in the connecting shell 12, the positioning reliability of the conductive shell 11 and the connecting shell 12 is improved, and the installation stability of the connecting shell 12 and the conductive shell 11 is further improved.

Moreover, if the peripheral wall portion 112 and the connecting shell 12 are still in clamping fit, the second protrusion 1212 and the second positioning groove 11222 are used for positioning in a fit manner, so that the clamping alignment of the peripheral wall portion 112 and the connecting shell 12 is accurate, the clamping can be smoothly realized, and the assembling difficulty is reduced. Alternatively, the first positioning groove 11221 and the second positioning groove 11222 may be different spacing grooves 1122, so as to ensure that the functions of the first positioning groove 11221 and the second positioning groove 11222 do not interfere with each other or affect each other, and can effectively perform their functions.

In some embodiments of the present invention, as shown in fig. 3 and 6, the conductive shell 11 includes an end cover portion 111 at an end of the unit housing 1 facing away from the machine body 200, and the massage unit 100 further includes: the heat generating member 4 includes a heat generating portion 40 located between the vibration member 2 and the end cover portion 111, and the heat generating portion 40 can transfer heat to the end cover portion 111. That is, at least part of the heating member is disposed between the vibration member 2 and the end cover part 111 of the conductive case 11 to transfer heat to the end cover part 111, so that the end cover part 111 can perform a hot compress massage on the human body, thereby enriching the function of the massage unit 100.

Alternatively, the vibration member 2 can directly or indirectly press the heat generating portion 40 against the end cover portion 111, so that the heat generating portion 40 can be always kept in contact with the end cover portion 111 of the conductive shell 11 when the vibration unit 21 vibrates, thereby improving reliability and effectiveness of the hot compress function. Further, when the welding points 30 are provided on the inner surface of the peripheral wall portion 112 of the conductive shell 11, the welding points 30 do not affect the conforming contact between the heat generating portion 40 and the end cover portion 111, so that the heat transfer efficiency is higher.

For example, in the specific example shown in fig. 3 and 6, the vibration member 2 may include a flexible sleeve 221, the flexible sleeve 221 is disposed in the unit housing 1, the vibration assembly 21 is disposed in the flexible sleeve 221, the flexible sleeve 221 is interference-fitted between the unit housing 1 and the vibration assembly 21 and isolated between the vibration assembly 21 and the welding point 30, the flexible sleeve 221 is compressed by the unit housing 1 and the vibration assembly 21 and presses the heat generating portion 40 to contact the end cover portion 111 by elastic force to transfer heat, so that the heat generating portion 40 can be always kept attached to the end cover portion 111 of the conductive shell 11 when the vibration assembly 21 vibrates, and the reliability and effectiveness of the hot compress function can be improved.

In some embodiments of the present invention, as shown in fig. 3 and 6, the heat generating member 4 is a heat generating film, the heat generating film includes a main body section 41 and an extension section 42, the main body section 41 is used as the heat generating portion 40 to be located between the vibration member 2 and the end cover portion 111, one end of the extension section 42 is connected to the main body section 41, and the other end is a connection end 421 and extends to a side of the vibration member 2 away from the end cover portion 111. Thus, the heat generating portion 40 can be ensured to be sheet-shaped and thin, thereby improving the compactness and compactness of the massage unit 100. Through setting up extension segment 42, avoid directly adopting main part section 41 to be connected with the circuit, can make heating element 4 wind the one side that deviates from end cover portion 111 of vibration part 2 and be connected with the circuit through extension segment 42, operating space is great, easily the operation.

Alternatively, in conjunction with fig. 22, the extension section 42 may be integrally formed with the main body section 41, so that the assembly connection is omitted and the reliability of the connection can be improved. Optionally, the width W2 of the extension section 42 is smaller than the width W1 of the main body section 41, so that the main body section 41 can generate a larger amount of heat, and the extension section 42 generates a smaller amount of heat, thereby saving energy waste. Optionally, the heating film has a heating wire 43, the heating wire 43 on the main body section 41 may be arranged in a zigzag extending manner, for example, along a spiral line, an arc line, etc., and the heating wire 43 on the extension section 42 may be arranged in an extending manner along the extending length direction of the extension section 42, so as to further ensure that the heating value of the main body section 41 is larger, and the heating value of the extension section 42 is smaller, thereby saving energy waste. Of course, the present invention is not limited thereto, and in other embodiments of the present invention, the heat generating member 40 may be a metal sheet, so that the heat generating member 4 has a simple structure and low cost.

In some embodiments of the utility model, as shown in fig. 6 and 23, the side of the heat generating portion 40 facing away from the end cover portion 111 is provided with a temperature detector 5. That is, the side of the heat generating part 40 facing the vibration member 2 is provided with a temperature detector 5, such as a temperature sensor, so that the temperature of the heat generating part 40 can be detected or even fed back, thereby ensuring that the hot compress function can be reliably and effectively realized. Alternatively, the temperature detector 5 may be an NTC temperature sensor, so that the detection is convenient and reliable.

In connection with the example shown in fig. 3 and 6, when the vibration member 2 includes the flexible sleeve 221, the flexible sleeve 221 may include a top buffering portion 2214 between the vibration assembly 21 and the end cover portion 111, and the top buffering portion 2214 has a second avoidance area 2215 thereon for avoiding the temperature detector 5. Therefore, the temperature detector 5 can be avoided by the second avoiding area 2215, the temperature detector 5 can be protected, the space can be saved, and the miniaturization and the compactness are facilitated.

In some embodiments of the present invention, as shown in fig. 6, the second avoidance area 2215 is an avoidance blind groove recessed toward a direction away from the heat generating portion 40, and a bottom wall 2216 of the avoidance blind groove is used for blocking heat transfer between the vibration assembly 21 and the temperature detector 5. Accordingly, the bottom wall 2216 of the blind recess can be used as a heat insulation structure to prevent heat generated by the vibrating member 21 from being transmitted to the temperature detector 5 and affecting the detection sensitivity of the temperature detector 5.

For example, as shown in fig. 3, a spacer 222 may be provided between the top buffer 2214 and the vibration assembly 21, and the spacer 222 may be provided to block heat transfer between the vibration assembly 21 and the temperature detector 5, so that even if the second escape area 2215 is a through groove, heat can be blocked. Alternatively, the spacer 222 may be a cushion to buffer the vibration transmitted from the vibration component 21 to the heat generating portion 40. Still alternatively, the spacer 222 may be provided as an adhesive sheet for bonding the vibration assembly 21 and the flexible cover 221, thereby improving the reliability of the connection between the vibration assembly 21 and the flexible cover 221.

In some embodiments of the present invention, as shown in fig. 3, 6 and 23, the flexible pad 6 is disposed between the heat generating portion 40 and the vibrating component 2, and the flexible pad 6 is clamped between the heat generating portion 40 and the vibrating component 2, so that the flexible pad 6 can press the heat generating portion 40 to be in close contact with the end cover portion 111, thereby improving the heat transfer effect of the heat generating portion 40 to the end cover portion 111.

That is to say, the flexible pad 6 is disposed on the side of the heat generating portion 40 facing the vibrating component 2, the flexible pad 6 can be adhered to at least one of the heat generating portion 40 and the vibrating component 2, and when the heat generating portion is mounted, the flexible pad 6 is in an interference fit state, that is, the flexible pad 6 is pressed, so that the heat generating portion 40 can be more closely attached to the end cover portion 111 of the conductive shell 11, and the heat conducting effect is better. For example, in some specific examples, the flexible pad 6 is a foam, a silicone pad, or the like, and both sides of the foam may have an adhesive layer, which is adhered and fixed to the heat generating portion 40 and the flexible sleeve 221 respectively.

Optionally, the flexible mat 6 is provided with a third avoidance area 61 for avoiding the temperature detector 5, so that mutual interference between the flexible mat 6 and the temperature detector 5 can be avoided, and the installation reliability of the flexible mat 6 is ensured. Optionally, the third avoidance area 61 is a blind groove or a through groove, when the third avoidance area 61 is a through groove, and when the second avoidance area 2215 is an avoidance blind groove, after the flexible pad 6 is bonded and fixed with the flexible sleeve 221, the second avoidance area 2215 on the flexible sleeve 221 and the third avoidance area 61 on the flexible pad 6 enclose a closed space together to accommodate the temperature detector 5, so that a waterproof effect can be achieved, and water is prevented from entering the avoidance area and causing the damage of the temperature detector 5.

In some embodiments of the present invention, as shown in fig. 4 and 6, the conductive shell 11 includes an end cover portion 111 located at an end of the unit case 1 facing away from the machine body 200, a side of the conductive shell 11 facing away from the end cover portion 111 defines a mounting opening 114, the vibration member 2 is adapted to be interference-fitted to the conductive shell 11 by the mounting opening 114, the unit case 1 further includes a connection shell 12, the connection shell 12 is adapted to be connected to the machine body 200, and the connection shell 12 is connected to the conductive shell 11 to close the mounting opening 114, so that the vibration member 2 is located in a space defined by the conductive shell 11 and the connection shell 12 together. Therefore, the vibration part 2 can be assembled with the conductive shell 11 and then with the connecting shell 12, thereby improving the convenience of assembly.

In some embodiments of the utility model, as shown in fig. 4 and 6, the connecting shell 12 comprises a stop portion 1201 that stops at a side of the vibration member 2 facing away from the end cover portion 111. Thus, the stopper portion 1201 can be used to limit and support the vibration member 2 to a certain extent, thereby improving the mounting stability and operational reliability of the vibration member 2. It should be noted that the "stop" described herein is not limited to a direct or indirect contact stop, and may also be a non-contact stop, for example, in which case the vibration member 2 may be stopped after moving a certain distance in a direction away from the end cover portion 111.

The relative position and configuration of the stopper portion 1201 and the conductive case 11 are not limited. For example, in some alternative embodiments, as shown in fig. 6, the stopping portion 1201 may be located outside the conductive shell 11, so that the stopping portion 1201 may be prevented from occupying the space inside the conductive shell 11, so that the conductive shell 11 may be miniaturized. For example, in the specific example shown in fig. 6, the connecting shell 12 may include a mounting section 1202 and a connecting section 122, the mounting section 1202 is connected to the conductive shell 11, the connecting section 122 is adapted to be connected between the machine body 200 and the mounting section 1202, the connecting section 122 and the mounting section 1202 are both hollow cylindrical, and the cross-sectional area S3 of the connecting section 122 is smaller than the cross-sectional area S4 of the mounting section 1202, so that the connecting portion of the mounting section 1202 and the connecting section 122 forms a step surface 123, and the step surface 123 serves as a stopping portion 1201 to stop against the vibration component 2. Therefore, the step surface 123 can be used for limiting and supporting the vibration part 2 to a certain extent, the mounting stability and the working reliability of the vibration part 2 are improved, and the connecting shell 12 is simple in structure and convenient to process and demold. Moreover, the stopper portion 1201 can be easily and effectively ensured to be located outside the conductive shell 11. Of course, the utility model is not limited to this, and the connecting shell 12 may be formed in other forms, for example, the connecting shell 12 may be a cylinder with a non-variable cross section, and the cylinder has an annular rib inside, and the annular rib is located outside the conductive shell 11 and stops the vibration member 2.

For example, in some other alternative embodiments, as shown in fig. 18 and 21, the stopping portion 1201 may also extend into the conductive shell 11, thereby improving the compactness, making the stopping portion 1201 more accessible to the vibration member 2, and implementing a limit stop for the vibration member 2. For example, in the specific example shown in fig. 6, the connecting shell 12 includes an outer ring segment 1242 and an inner ring segment 1243, the inner ring segment 1243 is disposed in the outer ring segment 1242 and defines a plug-fit groove 1241 with the outer ring segment 1242, the conductive shell 11 further includes a peripheral wall portion 112, the peripheral wall portion 112 is connected to a side of the end cover portion 111 facing the machine body 200 and surrounds the vibration member 2, the peripheral wall portion 112 is plug-fit in the plug-fit groove 1241, and the inner ring segment 1243 serves as a stopper portion 1201 to stop against the vibration member 2. From this, can utilize itself to participate in and inject the interior ring section 1243 of joining in marriage groove 1241 and form spacing and support to vibrating part 2 to a certain extent to simplify and connect 12 structures of shell, need not additionally to process other structures, just can improve vibrating part 2's installation stability and operational reliability. Moreover, the stopper portion 1201 can be easily and effectively ensured to be located in the conductive case 11. Of course, the utility model is not limited to this, and the connecting shell 12 may be formed in other forms, for example, the connecting shell 12 may be a cylinder with a non-variable cross section, and the cylinder has an annular rib inside, and the annular rib extends into the conductive shell 11 and stops the vibration component 2.

In some embodiments of the present invention, as shown in fig. 6, the connection shell 12 includes a hard mounting segment 121, the hard mounting segment 121 is a hollow cylinder (may be, but not limited to, a hollow cylinder), the conductive shell 11 further includes a peripheral wall portion 112, the peripheral wall portion 112 is connected to a side of the end cover portion 111 facing the machine body 200 and surrounds the vibration component 2, and the peripheral wall portion 112 is inserted into and engaged with the hard mounting segment 121. Therefore, the assembly is convenient, and the connection is reliable. In addition, it should be noted that the peripheral wall portion 112 may be inserted into the hard mounting section 121, and in this case, the welding point 30 may be disposed on any one of the peripheral wall portion 112 and the end cover portion 111, but the present invention is not limited thereto, and the peripheral wall portion 112 may also be inserted outside the hard mounting section 121, and in this case, the welding point 30 may be disposed on any one of the peripheral wall portion 112 and the end cover portion 111, and when the welding point 30 is disposed on the end cover portion 111, interference of the insertion of the welding point 30 to the hard mounting section 121 may be avoided, and when the welding point 30 is disposed on the peripheral wall portion 112, the position of the welding point 30 needs to be designed reasonably, and interference of the insertion to the hard mounting section 121 is avoided.

Alternatively, as shown in fig. 4, 11-13, the peripheral wall 112 is inserted into the hard mounting segment 121, a buckle 1211 is formed on the inner cylindrical surface of the hard mounting segment 121, a clamping hole 11210 is formed on the peripheral wall 112, and the buckle 1211 is clamped with the clamping hole 11210. Therefore, the peripheral wall part 112 and the hard mounting section 121 can be inserted and clamped, so that the connecting shell 12 and the conductive shell 11 can be reliably connected, and the clamping is simple and reliable in implementation mode and convenient to process and produce.

Alternatively, the peripheral wall portion 112 is inserted into the hard mounting section 121 with interference, and the peripheral wall portion 112 includes a plurality of sub-wall sections 1121 arranged at intervals along the circumferential direction, a spacing groove 1122 is formed between two adjacent sub-wall sections 1121, and the fastening hole 11210 is formed on the sub-wall section 1121. Thus, since the peripheral wall portion 112 includes the plurality of sub-wall sections 1121 arranged at intervals in the circumferential direction, the peripheral wall portion 112 is easily deformed, interference insertion of the peripheral wall portion 112 with the hard mounting section 121 is facilitated, and the snap holes 11210 are provided on the sub-wall sections 1121, so that the snap engagement of the snaps 1211 and the snap holes 11210 can be favorably realized in the insertion process, thereby improving the assembly efficiency and the assembly convenience, and further, the connection reliability and the connection stability of the vibration member 2 with the unit case 1 can be improved by the interference fit of the peripheral wall portion 112 with the vibration member 2.

Alternatively, as shown in fig. 7, 11 and 13, the spacing slot 1122 penetrates the mounting opening 114 and includes a second positioning slot 11222, so that the second positioning slot 11222 also penetrates the mounting opening 114, a second protrusion 1212 is formed on the inner surface of the hard mounting segment 121, and the second positioning slot 11222 is engaged by the second protrusion 1212, so that during the insertion of the hard mounting segment 121 into the peripheral wall portion 112, the second protrusion 1212 is engaged with the second positioning slot 11222, so that the engagement of the second protrusion 1212 with the second positioning slot 11222 can function as a guiding positioning, so that the peripheral wall portion 112 can be quickly and accurately fitted into the hard mounting segment 121, and the positioning reliability of the conductive shell 11 with the connection shell 12 is improved, and the mounting stability of the connection shell 12 with the conductive shell 11 is further improved.

In some embodiments of the present invention, as shown in fig. 12, the peripheral wall part 112 includes an outer wall section 1123 and an inner wall section 1124 connected in this order in a direction away from the end cover part 111, the cross-sectional area S1 of the outer wall section 1123 is larger than the cross-sectional area S2 of the inner wall section 1124, the inner wall section 1124 is interference-fitted inside the hard mounting section 121, the outer wall section 1123 is located outside the hard mounting section 121 and the outer peripheral surface of the outer wall section 1123 is flush with the outer peripheral surface of the hard mounting section 121. Therefore, the cross section change of the outer wall section 1123 and the inner wall section 1124 can be utilized to play a role of inserting and limiting, and the appearance surface of the joint of the connecting shell 12 and the conductive shell 11 can be ensured to be smooth, so that the sealing performance of the inserting and matching position of the connecting shell 12 and the conductive shell 11 is improved. Optionally, the inner wall section 1124 is comprised of a plurality of sub-wall sections 1121.

In some embodiments of the present invention, as shown in fig. 6, the unit housing 1 includes a conductive shell 11 and a connection shell 12, the connection shell 12 includes a hard mounting segment 121 and a connection segment 122, the hard mounting segment 121 and the connection segment 122 are both hollow cylinders (may be, but not limited to, hollow cylinders), a cross-sectional area of the hard mounting segment 121 is greater than a cross-sectional area of the connection segment 122, the hard mounting segment 121 is connected to an end of the connection segment 122 facing away from the machine body 200, a step surface 123 is formed between the hard mounting segment 121 and the connection segment 122, the vibration component 2 is installed in the conductive shell 11 and is in interference fit with a peripheral wall 112 of the conductive shell 11, the peripheral wall 112 of the conductive shell 11 is inserted into the hard mounting segment 121 and is in snap fit with the hard mounting segment 121, the step surface 123 presses the vibration component 2 to prevent the conductive vibration component 2 from shifting relative to the conductive shell 11 in a direction away from the end cap portion 111, so that the installation of the vibration component 2 is more secure, the end of connecting section 122 facing away from rigid mounting section 121 has a through hole 125, one end of conductive element 3 extends into unit housing 1 and is welded to conductive shell 11, and the other end of conductive element 3 extends out of unit housing 1 through hole 125.

Of course, the present invention is not limited thereto, and the conductive shell 11 and the connecting shell 12 may not be plugged, for example, in some other embodiments of the present invention, the conductive shell 11 and the connecting shell 12 may be connected by bonding, for example, in the specific examples shown in fig. 16 to 21, the connecting shell 12 is bonded with the conductive shell 11. Therefore, the connection is convenient and reliable.

As shown in fig. 18 to 21, the connection shell 12 includes a flexible mounting section 124, the flexible mounting section 124 defines a fitting groove 1241, the conductive shell 11 further includes a peripheral wall portion 112, the peripheral wall portion 112 is connected to a side of the end cover portion 111 facing the machine body 200 and surrounds the vibration component 2, and the peripheral wall portion 112 is fitted into and adhered to the fitting groove 1241. Therefore, through the matching of the peripheral wall part 112 and the inserting and matching groove 1241, the connection shell 12 and the conductive shell 11 can be relatively limited, so that the reliability of bonding connection can be improved, glue can be injected through the inserting and matching groove 1241, the operation is easy, and the connection is reliable.

In some embodiments of the present invention, as shown in fig. 18, the peripheral wall part 112 includes an outer wall section 1123 and an inner wall section 1124 connected in series in a direction away from the end cover part 111, the outer wall section 1123 has a larger cross-sectional area than the inner wall section 1124, the inner wall section 1124 is fitted into the fitting groove 1241, the outer wall section 1123 is located outside the fitting groove 1241 and the outer peripheral surface of the outer wall section 1123 is flush with the outer peripheral surface of the flexible mounting section 124. Therefore, the cross section change of the outer wall section 1123 and the inner wall section 1124 can be utilized to play a role of inserting and limiting, and the appearance surface of the joint of the connecting shell 12 and the conductive shell 11 can be ensured to be smooth, so that the sealing performance of the inserting and matching position of the connecting shell 12 and the conductive shell 11 is improved.

As shown in fig. 18, the flexible mounting section 124 may include an outer ring section 1242 and an inner ring section 1243, the inner ring section 1243 is located in an inner ring space of the outer ring section 1242, the inner ring section 1243 is disposed in the outer ring section 1242 and defines a plug-fit slot 1241 with the outer ring section 1242, and the inner ring section 1243 is stopped at a side of the vibration member 2 facing away from the end cover portion 111. Therefore, the inner ring section 1243 can be used to limit and support the vibration component 2, so as to improve the installation stability and the working reliability of the vibration component 2, and the insertion groove 1241 can be simply and effectively constructed. Optionally, when the welding point 30 is disposed on the inner surface of the inner wall segment 1124, the inner ring segment 1243 has an avoiding opening for avoiding the conductive component 3, so as to avoid the welding point 30, and ensure the conductive component 3 to extend smoothly, reduce the bending of the conductive component 3, and improve the reliability and the service life of the conductive component 3.

In some embodiments of the present invention, the connection housing 12 includes a mounting section 1202 and a connection section 122, the mounting section 1202 is connected to the conductive housing 11, and the connection section 122 is adapted to be connected between the body 200 and the mounting section 1202. For example, the mounting segment 1202 may be the rigid mounting segment 121 or the flexible mounting segment 124, which will not be described herein.

Alternatively, the connection section 122 is hard and is adapted to be a separate piece from the machine body 200, whereby the movement of the connection section 122 relative to the machine body 200 is easily achieved to ensure that the massage unit 100 can reliably achieve the vibration massage function. For example, the connecting section 122 can be attached to a mounting surface of the inner housing of the housing 200, for example, by clamping the inner housing of the housing 200 together with the connecting section 122 by a clip. Furthermore, when the mounting section 1202 is the rigid mounting section 121 described above, in some alternative examples, the rigid mounting section 121 may be integral with the rigid connecting section 122 to simplify machining, or may be a separate piece.

Or alternatively, the connection section 122 is made of a flexible material and is adapted to be integrated with the mounting plate 201 of the machine body 200, so that the assembly steps can be reduced, and the flexibility of the connection section 122 can be utilized to ensure that the massage unit 100 can reliably realize the vibration massage function. In addition, a corrugated structure may be further provided at the junction of the coupling case 12 and the mounting plate 201, thereby performing a vibration damping function and facilitating vibration of the massage unit 100.

In addition, when the mounting section 1202 is the above-mentioned rigid mounting section 121, in some alternative examples, the rigid mounting section 121 and the flexible connecting section 122 may be a single piece or may be separate pieces. When the mounting section 1202 is the flexible mounting section 124, the flexible mounting section 124 and the flexible connecting section 122 may be a single piece or separate pieces.

In some embodiments, as shown in fig. 20, the connection housing 12 may be made of a flexible material and the mounting plate 201 adapted to the machine body 200 may be a single piece, so that the assembly steps may be reduced, and the flexibility of the connection section 122 may be utilized to ensure that the massage unit 100 can reliably perform the vibration massage function. For example, the connecting shell 12 and the mounting plate 201 can both be made of soft silica gel, so that the deformation is better, and the damping effect is better. When the connecting shell 12 is made of soft silica gel, the conductive shell 11 and the connecting shell 12 can be bonded and fixed, and reliable connection can be realized.

In some embodiments of the present invention, the connecting shell 12 is made of a non-conductive material, so as to improve the safety of use, and on the other hand, the connecting shell 12 can be made of a non-conductive material suitable for being connected with the machine body 200, for example, a material such as plastic or silicon gel is used to process the connecting shell 12, so as to meet the requirement of connecting the connecting shell 12 with the machine body 200.

In some embodiments of the present invention, the conductive shell 11 is a metal shell, that is, the conductive shell 11 is made of metal material, so as to facilitate processing of the conductive shell 11, and ensure a large conductive area, and ensure that the conductive shell 11 can electrically stimulate and massage the human body no matter where the welding point 30 is located. Of course, the present invention is not limited thereto, and the conductive shell 11 may be partially made of a metal material, and the welding points 30 may be provided on the metal material, so that the metal material may be in contact with the human body to perform the electrical stimulation massage.

Next, a wearable massage apparatus according to an embodiment of the second aspect of the present invention is described.

As shown in fig. 1 and 16, the wearable massage apparatus according to the embodiment of the present invention may include a body 200 and a plurality of massage units 100 connected to the body 200 for massage apparatus 1000 according to the first aspect of the present invention, wherein the body 200 has an electric pulse generating device therein, and the conductive member 3 is electrically connected to the electric pulse generating device. The wearing type massager is not limited in specific type, and can be an eye massager, a neck massager, a waist massager or the like. Other configurations of the wearable massage apparatus according to embodiments of the present invention are known to those of ordinary skill in the art after the type of the wearable massage apparatus is determined, and will not be described in detail herein.

Therefore, the wearable massage apparatus according to the embodiment of the present invention at least has the dual functions of vibration massage and electrical stimulation massage, and has rich functions, and the electrical pulse generator is disposed in the body 200 and electrically connected to the conductive shell 11 through the conductive member 3, so as to better ensure that the volume of the massage unit 100 with more functions is smaller, and since the welding point 30 is located in the conductive shell 11, the problems that the welding point 30 is exposed outside the unit housing 1 and is easily damaged and the connection is poor can be avoided, and the problems that the assembly of other parts outside the conductive shell 11 and the conductive shell 11 is affected, etc. can be avoided. In addition, through set up bolster 22 between welding point 30 and vibration subassembly 21 to can avoid vibration subassembly 21 directly to transmit the vibration to welding point 30, in order to avoid causing the problem of bad connection or damage to welding point 30 because the vibration of vibration subassembly 21, and then guarantee that the electric connection between electrically conductive 3 and the conductive shell 11 is comparatively reliable and stable, improve the reliability and the stability of electro photoluminescence massage function.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (38)

1. A massage unit (100) for a massage apparatus (1000), the massage apparatus (1000) comprising a body (200), the body (200) having electrical pulse generating means therein, the massage unit (100) comprising:

a unit housing (1), said unit housing (1) being adapted to be connected with said machine body (200), said unit housing (1) comprising an electrically conductive shell (11);

a vibration member (2), the vibration member (2) being provided in the unit case (1), and including a vibration assembly (21) and a damper (22);

electrically conductive piece (3), electrically conductive piece (3) be suitable for with electric pulse generating device electricity is connected, electrically conductive piece (3) weld to the internal surface of electrically conductive shell (11) is in order to form welding point (30), so that electric pulse generating device pass through electrically conductive piece (3) with electrically conductive shell (11) electricity is connected, bolster (22) keep apart vibration subassembly (21) with between welding point (30).

2. The massage unit (100) for a massage apparatus (1000) according to claim 1, wherein the conductive shell (11) comprises an end cap portion (111) and a peripheral wall portion (112), the end cap portion (111) being located at an end of the unit housing (1) facing away from the machine body (200), the peripheral wall portion (112) being connected to a side of the end cap portion (111) facing the machine body (200) and surrounding the vibration member (2), the conductive member (3) being welded to an inner surface of the peripheral wall portion (112).

3. The massaging unit (100) for a massaging apparatus (1000) as claimed in claim 2, characterized in that a side of the peripheral wall portion (112) facing away from the end cap portion (111) defines a mounting opening (114), the vibration member (2) being adapted to be mounted into the electrically conductive housing (11) by the mounting opening (114).

4. The massage unit (100) for a massage apparatus (1000) according to claim 3, wherein the peripheral wall portion (112) includes a plurality of sub-wall sections (1121) arranged at intervals in the circumferential direction, a spacing groove (1122) penetrating to the mounting opening (114) is formed between adjacent two of the sub-wall sections (1121), and the conductive member (3) is welded to an inner surface of the sub-wall sections (1121).

5. The massage unit (100) for a massage apparatus (1000) according to claim 1, wherein the conductive shell (11) comprises an end cover portion (111) and a peripheral wall portion (112), the end cover portion (111) being located at an end of the unit housing (1) facing away from the machine body (200), the peripheral wall portion (112) being connected to a side of the end cover portion (111) facing the machine body (200) and surrounding the vibration member (2), the conductive member (3) being welded to an inner surface of the end cover portion (111).

6. The massaging unit (100) for a massage apparatus (1000) according to claim 5, wherein there is a fitting clearance between the vibrating part (2) and the end cap portion (111), the fitting clearance being adapted to accommodate the welding point (30).

7. The massage unit (100) for a massage apparatus (1000) of claim 5, wherein the weld (30) is located in a central region of the end cap portion (111).

8. The massaging unit (100) for a massaging apparatus (1000) according to claim 1, wherein the two ends of the conductive member (3) are a welding end and an electrical connection end respectively, the welding end is located in the conductive shell (11) and welded to the conductive shell (11) to form the welding point (30), one side end of the unit housing (1) facing the machine body (200) is provided with a through hole (125), and the electrical connection end is penetrated out of the unit housing (1) through the through hole (125) to be suitable for connecting an electric pulse generating device.

9. The massage unit (100) for a massage apparatus (1000) according to claim 1, wherein the conductive member (3) comprises a welding section (31), a bending section (32), and a pulling section (33), the welding section (31) is located between the vibration component (2) and the conductive shell (11), the bending section (32) is stopped and limited on a side of the vibration component (2) facing the machine body (200), one end of the bending section (32) is connected to the welding section (31), the other end of the bending section (32) is connected to the pulling section (33), one end of the welding section (31) far away from the bending section (32) is welded to an inner surface of the conductive shell (11) to form the welding point (30), and one end of the pulling section (33) far away from the bending section (32) extends toward the machine body (200), suitable for being connected with an electric pulse generating device.

10. The massage unit (100) for a massage apparatus (1000) of claim 1, wherein the buffer (22) comprises a flexible sleeve (221), the flexible sleeve (221) being disposed within the unit housing (1), the vibration assembly (21) being disposed within the flexible sleeve (221), the flexible sleeve (221) being interference fit between the unit housing (1) and the vibration assembly (21).

11. The massage unit (100) for a massage apparatus (1000) according to claim 10, wherein the flexible sleeve (221) covers the welding point (30) and is deformed by the welding point (30) by pressing, or wherein a first avoidance region (2211) for avoiding the welding point (30) is provided on an outer surface of the flexible sleeve (221).

12. The massage unit (100) for a massage apparatus (1000) of claim 10, wherein the inner peripheral wall of the unit housing (1) has a first positioning structure thereon, the flexible sleeve (221) comprises a peripheral buffering portion (2212) disposed between the inner peripheral wall of the unit housing (1) and the vibration assembly (21), the peripheral buffering portion (2212) has a second positioning structure thereon in positioning engagement with the first positioning structure, and the first positioning structure and the second positioning structure are in positioning engagement to restrict the flexible sleeve (221) from rotating relative to the unit housing (1).

13. The massage unit (100) for a massage apparatus (1000) of claim 12, wherein one of the first positioning structure and the second positioning structure comprises a first positioning groove (11221), the other comprises a first protrusion (2213) in positioning fit with the first positioning groove (11221), the conductive shell (11) defines a mounting opening (114), the first positioning groove (11221) penetrates to the mounting opening (114), and the vibration part (2) is adapted to be mounted into the conductive shell (11) through the mounting opening (114).

14. The massage unit (100) for a massage apparatus (1000) according to claim 13, wherein the conductive shell (11) includes an end cover portion (111) and a peripheral wall portion (112), the end cover portion (111) is located at an end of the unit housing (1) facing away from the machine body (200), the peripheral wall portion (112) is connected to a side of the end cover portion (111) facing the machine body (200) and surrounds the vibration member (2), a side of the peripheral wall portion (112) facing away from the end cover portion (111) defines the mounting opening (114), the peripheral wall portion (112) includes a plurality of sub-wall portions (1121) arranged at intervals in a circumferential direction, a spacing groove (1122) penetrating to the mounting opening (114) is formed between adjacent two of the sub-wall portions (1121), at least one of the spacing grooves (1122) serves as the first positioning groove (1122), the first projection (2213) is provided on the peripheral buffer portion (2212).

15. The massage unit (100) for a massage apparatus (1000) according to claim 14, wherein the unit housing (1) further comprises a connection housing (12) for connecting the machine body (200), the peripheral wall portion (112) is inserted into the connection housing (12), the spacing groove (1122) comprises a second positioning groove (11222), a second protrusion (1212) is formed on an inner surface of the connection housing (12), the second protrusion (1212) is fitted into the second positioning groove (11222), and the vibration member (2) is adapted to be fitted into the conductive housing (11) and/or the connection housing (12) before the connection housing (12) is fitted into the conductive housing (11).

16. Massage unit (100) for a massage apparatus (1000) according to claim 1, wherein the electrically conductive shell (11) comprises an end cap portion (111) at an end of the unit housing (1) facing away from the machine body (200), the massage unit (100) further comprising:

a heat generating member (4), the heat generating member (4) including a heat generating portion (40) located between the vibration member (2) and the end cover portion (111), and the heat generating portion (40) being capable of transferring heat to the end cover portion (111).

17. The massage unit (100) for a massage apparatus (1000) according to claim 16, wherein the heat generating portion (40) is a metal sheet, or wherein the heat generating member (4) is a heat generating film, the heat generating film comprising a main body section (41) and an extension section (42), the main body section (41) being the heat generating portion (40) to be located between the vibration member (2) and the end cover portion (111), one end of the extension section (42) being connected to the main body section (41), the other end extending to a side of the vibration member (2) facing away from the end cover portion (111).

18. Massage unit (100) for a massage apparatus (1000) according to claim 17, wherein a side of the heat generating portion (40) facing away from the end cover portion (111) is provided with a temperature detector (5).

19. The massage unit (100) for a massage apparatus (1000) of claim 18, characterized in that the vibrating member (2) comprises a flexible sleeve (221), the flexible sleeve (221) is arranged in the unit housing (1), the vibration component (21) is arranged in the flexible sleeve (221), the flexible sleeve (221) is in interference fit between the unit shell (1) and the vibration component (21) and is isolated between the vibration component (21) and the welding point (30), the flexible sleeve (221) is compressed and presses the heating part (40) to contact with the end cover part (111) by elasticity for heat transfer, the flexible sleeve (221) comprises a top cushioning portion (2214) between the vibration assembly (21) and the end cap portion (111), the top buffer portion (2214) is provided with a second avoidance area (2215) for avoiding the temperature detector (5).

20. The massage unit (100) for a massage apparatus (1000) according to claim 19, wherein the second avoidance region (2215) is an avoidance blind slot recessed towards a direction away from the heat generating portion (40), and a bottom wall (2216) of the avoidance blind slot is used for blocking heat transfer between the vibration assembly (21) and the temperature detector (5).

21. The massage unit (100) for a massage apparatus (1000) according to claim 16, wherein a flexible pad (6) is provided between the heat generating portion (40) and the vibrating member (2), the flexible pad (6) being clamped between the heat generating portion (40) and the vibrating member (2).

22. The massage unit (100) for a massage apparatus (1000) of claim 1, wherein the electrically conductive shell (11) comprises an end cap portion (111) at an end of the unit housing (1) facing away from the machine body (200), a side of the electrically conductive shell (11) facing away from the end cap portion (111) defines a mounting opening (114), the vibration member (2) is adapted to be interference fitted to the electrically conductive shell (11) by the mounting opening (114), the unit housing (1) further comprises a connecting shell (12), the connecting shell (12) is adapted to be connected with the machine body (200), and the connecting shell (12) is connected with the electrically conductive shell (11) to close the mounting opening (114).

23. Massage unit (100) for a massage apparatus (1000) according to claim 22, wherein the connection housing (12) comprises a stop (1201) that stops at a side of the vibration part (2) facing away from the end cover part (111).

24. The massage unit (100) for a massage apparatus (1000) of claim 23, wherein the stopper (1201) is located outside the conductive shell (11).

25. The massage unit (100) for a massage apparatus (1000) of claim 24, wherein the connecting casing (12) comprises a mounting section (1202) and a connecting section (122), the mounting section (1202) is connected to the conductive casing (11), the connecting section (122) is adapted to be connected between the machine body (200) and the mounting section (1202), the connecting section (122) and the mounting section (1202) are both hollow cylindrical, and the cross-sectional area of the connecting section (122) is smaller than the cross-sectional area of the mounting section (1202) so that the connection of the mounting section (1202) and the connecting section (122) forms a step surface (123), and the step surface (123) serves as the stopper (1201) to stop against the vibration member (2).

26. The massage unit (100) for a massage apparatus (1000) of claim 23, wherein the stopper (1201) protrudes into the conductive housing (11).

27. The massage unit (100) for a massage apparatus (1000) of claim 26, wherein the connecting shell (12) comprises an outer ring segment (1242) and an inner ring segment (1243), the inner ring segment (1243) is disposed in the outer ring segment (1242) and defines a mating slot (1241) with the outer ring segment (1242), the conductive shell (11) further comprises a peripheral wall portion (112), the peripheral wall portion (112) is connected to a side of the end cover portion (111) facing the machine body (200) and surrounds the vibration component (2), the peripheral wall portion (112) is mated with the mating slot (1241), and the inner ring segment (1243) serves as the stop portion (1201) to stop against the vibration component (2).

28. The massage unit (100) for a massage apparatus (1000) according to claim 22, wherein the connecting shell (12) comprises a rigid mounting section (121), the rigid mounting section (121) is a hollow cylinder, the conductive shell (11) further comprises a peripheral wall portion (112), the peripheral wall portion (112) is connected to one side of the end cover portion (111) facing the machine body (200) and surrounds the vibration member (2), and the peripheral wall portion (112) is in plug fit and clamping connection with the rigid mounting section (121).

29. The massage unit (100) for a massage apparatus (1000) of claim 28, wherein the peripheral wall portion (112) is inserted into the rigid mounting section (121), a snap (1211) is formed on an inner cylindrical surface of the rigid mounting section (121), a snap hole (11210) is formed on the peripheral wall portion (112), and the snap (1211) is snapped into the snap hole (11210).

30. The massage unit (100) for a massage apparatus (1000) according to claim 29, wherein the peripheral wall portion (112) is inserted into the rigid mounting section (121) with interference, and the peripheral wall portion (112) includes a plurality of sub-wall sections (1121) arranged at intervals along the circumferential direction, a spacing groove (1122) is formed between two adjacent sub-wall sections (1121), and the fastening hole (11210) is formed on the sub-wall sections (1121).

31. The massage unit (100) for a massage apparatus (1000) of claim 30, wherein the spacer slot (1122) extends through to the mounting port (114) and includes a second detent (11222), the hard mounting segment (121) having a second protrusion (1212) formed on an inner surface thereof, the second protrusion (1212) being fitted in the second detent (11222).

32. The massaging unit (100) for a massaging apparatus (1000) according to claim 22, wherein the connecting shell (12) comprises a flexible mounting section (124), the flexible mounting section (124) defining a fitting groove (1241), the conductive shell (11) further comprises a peripheral wall portion (112), the peripheral wall portion (112) is connected to a side of the end cover portion (111) facing the machine body (200) and surrounds the vibrating member (2), and the peripheral wall portion (112) is fitted and adhered to the fitting groove (1241).

33. The massage unit (100) for a massage apparatus (1000) according to claim 32, wherein the peripheral wall portion (112) includes an outer wall section (1123) and an inner wall section (1124) connected in series in a direction away from the end cover portion (111), the outer wall section (1123) has a cross-sectional area larger than that of the inner wall section (1124), the inner wall section (1124) is fitted into the fitting groove (1241), the outer wall section (1123) is located outside the fitting groove (1241) and an outer circumferential surface of the outer wall section (1123) is flush with an outer circumferential surface of the flexible mounting section (124).

34. The massaging unit (100) for a massager (1000) according to claim 22, wherein the connecting housing (12) comprises a mounting section (1202) and a connecting section (122), the mounting section (1202) is connected with the conductive housing (11), the connecting section (122) is adapted to be connected between the machine body (200) and the mounting section (1202), the connecting section (122) is rigid and adapted to be a separate piece with the machine body (200), or the connecting section (122) is flexible and adapted to be a single piece with the mounting plate (201) of the machine body (200).

35. The massaging unit (100) for a massaging apparatus (1000) according to claim 22, wherein the connecting housing (12) is of a non-conductive material.

36. The massaging unit (100) for a massage apparatus (1000) according to any one of claims 1-35, wherein the electrically conductive shell (11) is a metal shell.

37. Wearable massage apparatus, characterized in that it comprises a body (200) and a plurality of massage units (100) according to any of claims 1-36 for the massage apparatus (1000), the massage units (100) being connected to the body (200), the body (200) having electrical pulse generating means inside.

38. The wearable massager of claim 37, wherein the wearable massager is a neck massager, an eye massager or a waist massager.

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