CN115349972A - Integrated oral care device - Google Patents

Abstract

The application provides an integrated form oral care device, relate to oral care technical field, a whole profile for solving present toothbrush handle is great, influence the technical problem of user's gripping travelling comfort, this integrated form oral care device includes vector generation unit, composite member and medium provide the unit, vector generation unit passes through vector transfer rod and is connected with composite member, vector transfer rod integration has the medium transfer passage, through being located the medium transfer passage intercommunication between the two between medium provide the unit and the composite member, the medium provides the unit promptly and provides the medium of getting rid of the foreign matter to composite member through the medium transfer passage, so that composite member can get rid of the foreign matter in the target area. The integrated oral care device provided herein is for use in the care of the oral cavity of a user.

Description

Integrated oral care device

Technical Field

The present application relates to the field of oral care technology, and more particularly, to an integrated oral care device.

Background

With the emphasis on oral care, electric toothbrushes and tooth rinsers are becoming common oral care tools for families.

At present, the electric toothbrush in the market only has the function of brushing teeth, and the tooth flusher also only has the function of flushing teeth, so that when people nurse the oral cavity, the tooth flusher and the electric toothbrush need to be used respectively, and a lot of inconvenience exists. Therefore, the prior art provides a multifunctional electric toothbrush, which comprises a toothbrush handle and a toothbrush head, wherein the toothbrush head is provided with a channel communicated with bristles, and a containing cavity of the toothbrush handle is provided with a material conveying pipe communicated with the channel.

However, in the multifunctional electric toothbrush, the material conveying pipe occupies more space of the accommodating cavity, so that the overall profile of the toothbrush handle is larger, and the gripping comfort of a user is influenced.

Disclosure of Invention

In view of the above problems, the embodiments of the present application provide an integrated oral care device that can integrate a portion of a media delivery tube onto a vector transfer rod, thereby reducing the overall profile of the toothbrush handle and improving user gripping comfort.

In order to achieve the above object, the embodiments of the present application provide the following technical solutions:

an embodiment of the present application provides an integrated oral care device, comprising: a non-uniform housing configured with a biomimetic gripping surface adapted for gripping, the non-uniform housing having a primary extent and oppositely disposed first and second ends, the primary extent extending from the first end of the non-uniform housing to the second end of the non-uniform housing;

a composite member configured to remove foreign matter within a target area, the composite member being proximate to the second end of the unbalanced enclosure and distal to the first end of the unbalanced enclosure;

a medium supply unit configured to supply a medium for accelerating removal of the foreign matter to the composite member;

a vector generation unit added at least partially within the unbalanced housing, the vector generation unit receiving the composite member through a vector transfer bar, the vector transfer bar having a media transport channel, a centerline of the media transport channel being arranged on the primary extension line, the media transport channel being located between the composite member and the media supply unit, and the composite member and the media supply unit being in communication through the media transport channel.

In an alternative embodiment, the vector transmission rod is far away from one end of the composite member, and penetrates into the vector generation unit from the end of the vector generation unit close to the composite member.

In an alternative embodiment, the vector transmission rod is far away from one end of the composite member, penetrates into the vector generation unit from the end part of the vector generation unit close to the composite member, and penetrates out of the vector generation unit from the end part of the vector generation unit far away from the composite member.

In an alternative embodiment, the vector generation unit comprises a power member outputting eccentric vibration force, the power member comprising a drive shaft multiplexed by the vector transmission rod; along the extension direction of the main extension line, the medium conveying channel penetrates through one end, far away from the composite component, of the vector transfer rod and one end, close to the composite component, of the vector transfer rod.

In an alternative embodiment, the media supply unit comprises a media transport mechanism and a media container disposed within the non-uniform housing; the media container is arranged on a side offset from the main extension line; along the extending direction of the main extending line, the medium conveying mechanism and the vector generating unit are separated by a preset distance, and the medium conveying mechanism is positioned on one side of the vector generating unit away from the composite member; the medium conveying mechanism is provided with a medium inflow end and a medium outflow end, the medium outflow end is communicated with the medium conveying channel through a pipeline, and the medium inflow end is communicated with the medium container through a pipeline.

In an alternative embodiment, the medium container comprises an outer wall which is co-body with the bionic gripping surface, and an inner wall which is connected with the outer wall and extends along the main extension line, the inner wall and the outer wall enclose a closed special-shaped cavity extending along the main extension line, and the closed special-shaped cavity stores the medium.

In an alternative embodiment, the bionic gripping surface comprises a first profiling gripping surface and a second profiling gripping surface which are asymmetrically distributed relative to the main extension line, and the first profiling gripping surface and the second profiling gripping surface are spliced to form a closed annular surface.

In an alternative embodiment, the distance of the first contoured gripping surface with respect to the main extension line varies from equal to decreasing from the first end of the unbalanced enclosure to the second end of the unbalanced enclosure in the extension direction of the main extension line.

In an alternative embodiment, the composite member includes a support head latchably connected to an end of the vector transfer lever away from the vector generation unit, a medium guide passage communicating with the medium conveyance passage is provided inside the support head, and a center line of the medium guide passage is arranged on the main extension line; the supporting head is provided with a bristle planting surface, a plurality of bundles of bristles are planted on the bristle planting surface at intervals, and the depth of the bristles planted on the bristle planting surface is not more than the distance from the bristle planting surface to the main extension line; the bristle planting surface is provided with a splashing hole communicated with the medium guide channel.

In an alternative embodiment, the inner bore of the media guide channel is adapted to the outer diameter of the vector transfer rod; the medium guide channel is provided with a bonding surface parallel to the main extension line, one end, far away from the vector generation unit, of the vector transmission rod is inserted into the medium guide channel for a certain distance, and the part, located in the medium guide channel, of the vector transmission rod is provided with a milling plane attached to the bonding surface.

Compared with the related art, the integrated oral care device provided by the embodiment of the application has the following advantages:

the integrated oral care device provided by the embodiment of the application comprises a vector generation unit, a composite component and a medium supply unit, wherein the vector generation unit is connected with the composite component through a vector transmission rod, the vector transmission rod is integrated with a medium conveying channel, the medium supply unit is communicated with the composite component through the medium conveying channel between the vector generation unit and the composite component, namely the medium supply unit supplies a medium for removing foreign matters to the composite component through the medium conveying channel, so that the composite component can remove the foreign matters in a target area.

With the holding cavity of relevant art middle teeth brush holder be provided with the conveying pipeline with the passageway intercommunication of toothbrush head, and the conveying pipeline is located one side scheme of holding cavity and compares, the integrated setting of medium transfer passage is on vector transfer pole in this application embodiment, and vector transfer pole not only is used for providing the vector to composite member promptly, and the medium provides the unit moreover and can also provide the required medium of getting rid of the foreign matter to composite member through vector transfer pole. With the arrangement, a feed delivery pipe does not need to be additionally arranged in the shell between the vector providing unit and the composite component, so that the outline size of the shell between the vector providing unit and the composite component can be reduced, the overall outline of the shell is reduced, and the grasping comfort of a user is improved.

In addition to the technical problems, technical features constituting technical solutions, and advantages brought by the technical features of the technical solutions described above, other technical problems, technical features included in technical solutions, and advantages brought by the technical features that can be solved by the integrated oral care device provided by the embodiments of the present disclosure will be described in further detail in the detailed description.

Drawings

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

Fig. 1 is a schematic view of the overall structure of an integrated oral care device provided by an embodiment of the present application;

fig. 2 is a schematic diagram of an arrangement of a vector generation unit and a medium supply unit in a housing according to an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a composite component provided in an embodiment of the present application;

fig. 4 is a schematic diagram illustrating a connection between a vector generation unit and a vector transmission rod according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a vector transmission rod penetrating through a vector generation unit according to an embodiment of the present application;

FIG. 6 is a schematic structural diagram of a media transport mechanism according to an embodiment of the present application;

FIG. 7 is an exploded view of the various components mounted on the modular bracket as provided by the exemplary embodiments of the present application;

fig. 8 is a schematic structural diagram of a tail cover according to an embodiment of the present application.

Description of reference numerals:

10-a housing;

101-a first end; 102-a second end; 103-main extension line; 104-a first contoured gripping surface; 105-a second contoured gripping surface; 106-inner wall; 107-blocking cover;

20-a composite member;

21-a support head; 22-a media guidance channel; 23-bristles; 24-a splash hole;

30-a media supply unit;

31-a media transport mechanism;

311-a medium inflow end; 312-media outflow end;

32-a media container; 33-a feed delivery pipe; 34-a connector; 35-a profiled seal;

40-a vector generation unit;

50-vector transfer bar;

51-a media transport path; 52-milling a plane;

61-a power supply module;

62-a charging module;

70-a tail cap; 71-tail channel;

80-a control panel;

90-a composite support;

91-a waterproof member; 92-a support; 93-a first cushion; 94-second shock pad.

Detailed Description

Just as the background art, among the multi-functional electric toothbrush among the correlation technique, the whole profile of its toothbrush handle is great, influence the problem of user's gripping travelling comfort, through the inventor research discovery, the reason why this kind of problem appears lies in, multi-functional electric toothbrush includes toothbrush handle and toothbrush head, its toothbrush head is provided with the passageway with the brush hair intercommunication, the holding cavity of toothbrush handle is provided with the conveying pipeline with the passageway intercommunication, and the conveying pipeline is located one side of holding cavity, the space that leads to the holding cavity is great, thereby the whole profile increase of toothbrush handle, influence user's gripping travelling comfort.

In view of the above technical problems, the present application provides an integrated oral care device, including a vector generation unit, a composite member and a medium providing unit, wherein the vector generation unit is connected to the composite member through a vector transmission rod, the vector transmission rod is integrated with a medium transmission channel, the medium providing unit is communicated with the composite member through the medium transmission channel therebetween, that is, the medium providing unit provides a medium for removing foreign matters to the composite member through the medium transmission channel, so that the composite member can remove the foreign matters in a target area. With such an arrangement, there is no need to additionally provide a feed pipe in the housing between the medium supply unit and the composite member, so that the overall size of the housing between the composite member and the medium supply unit can be reduced, thereby reducing the overall profile of the housing and improving the gripping comfort of the user.

In order to make the aforementioned objects, features and advantages of the embodiments of the present application more comprehensible, embodiments of the present application are described in detail below with reference to the accompanying drawings. It is to be understood that the described embodiments are merely a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

As shown in fig. 1 to 3, the integrated oral care device provided by the embodiment of the present application includes a housing 10, a composite member 20, a medium providing unit 30, and a vector generating unit 40, wherein the housing 10 has a receiving cavity, the medium providing unit 30 and the vector generating unit 40 are disposed in the receiving cavity, and a portion of the vector generating unit 40 is located outside the housing 10 and connected to the composite member 20 located outside the housing 10.

For convenience of description of the configuration of the case 10 provided in the embodiment of the present application, a direction indicated by an arrow in fig. 1 may be defined as a first direction, and a dotted line L is a main extension line 103 of the case 10.

Specifically, the housing 10 has an unbalanced housing with a bionic gripping surface suitable for gripping, that is, the outer peripheral surface of the housing 10 is a bionic gripping surface suitable for gripping by a user, and the housing 10 is an asymmetric housing 10 with respect to the main extension line 103.

For example, the bionic gripping surface comprises a first profiling gripping surface 104 and a second profiling gripping surface 105, the first profiling gripping surface 104 and the second profiling gripping surface 105 are distributed asymmetrically relative to the main extension line 103, and the first profiling gripping surface 104 and the second profiling gripping surface 105 are spliced with each other to form a closed annular surface. That is, the first and second gripping surfaces 104 and 105 are asymmetric with respect to the main extension line 103, and the distance between the first gripping surface 104 and the main extension line 103 and the distance between the second gripping surface 105 and the main extension line 103 are different, and they form a complete torus structure.

The first direction shown in fig. 1 is the same as the extending direction of the main extending line 103, and along the first direction, the casing 10 includes a first end 101 and a second end 102 which are oppositely disposed, the first end 101 can be defined as the bottom end of the casing 10, the second end 102 can be located as the top end of the casing 10, and the main extending line 103 extends from the first end 101 of the casing 10 to the second end 102 of the casing 10, or the main extending line 103 extends from the second end 102 of the casing 10 to the first end 101 of the casing 10.

The composite member 20 is configured for removing foreign matter within the target area, the composite member 20 being disposed proximate to the second end 102 of the housing 10 and distal to the first end 101 of the housing 10, i.e., the composite member 20 is disposed on top of the housing 10 and above the housing 10.

The composite member 20 is disposed along the main extension line 103 and connected to the vector generating unit 40 to receive the vector from the vector generating unit 40 to move the composite member 20 relative to the target area, including but not limited to vibrating the composite member 20 relative to the target area to remove foreign matter from the target area. For example, the integrated oral device is a power toothbrush, the composite member 20 is a head of the power toothbrush, and the composite member 20 is used for caring for the oral cavity of the user and removing foreign substances from the teeth.

In the vector generation unit 40 provided in the embodiment of the present application, the partial vector generation unit 40 is located inside the housing 10, the partial vector generation unit 40 is located outside the housing 10, and the vector generation unit 40 located outside the housing 10 is used for connecting with the composite member 20 to provide a vector to the composite member 20.

Illustratively, the vector generation unit 40 includes a vector transmission rod 50 and a power member, the vector transmission rod 50 is of a circular rod-shaped structure as a whole, and an axis of the vector transmission rod 50 is arranged on the main extension line 103. One end of the vector transmission rod 50 penetrates through the top end of the shell 10 and is connected with the composite member 20, namely, the vector generation unit 40 positioned outside the shell 10 is used for being connected with the composite member 20; the other end of the vector transfer lever 50 is connected to a power member, and a vector generated by the power member can be transmitted to the composite member 20 through the vector transfer lever 50.

Further, the vector transmission rod 50 in the embodiment of the present application is used not only to transmit the vector from the power member to the composite member 20 to move the composite member 20; the vector transfer bar 50 also serves to provide a medium to the composite member 20 for accelerating the removal of foreign materials, such as the composite member 20 being the head of a power toothbrush, and the vector transfer bar 50 also serves to provide toothpaste or rinsing fluid, etc. to the composite member 20.

The vector transfer lever 50 has a medium conveyance path 51, and the center line of the medium conveyance path 51 is arranged on the main extension line 103. Illustratively, the vector transfer rod 50 is provided with an intermediate cavity to form the medium conveying passage 51, one end of the vector transfer rod 50 is an outlet end and communicates with the composite member 20, and the other end of the vector transfer rod 50 is an inlet end for receiving the medium supplied from the medium supplying unit 30.

The medium conveying passage 51 is located between the composite member 20 and the medium supplying unit 30, and the composite member 20 and the medium supplying unit 30 communicate with each other through the medium conveying passage 51, that is, the medium conveying passage 51 is a part of the medium passage between the composite member 20 and the medium supplying unit 30. It should be noted that in some embodiments, the media transport path 51 is the only media path between the composite member 20 and the media supply unit 30. Preferably, the composite member 20 and the medium supplying unit 30 may communicate only through the medium transferring passage 51.

For example, the vector transfer bar 50 is provided with an intermediate cavity, the center line of which is arranged along the main extension line 103. Along the extending direction of the main extending line 103, the intermediate cavity may not extend through the entire vector transfer rod 50, and one end of the intermediate cavity near the composite member 20 may extend to the end surface of the vector transfer rod 50 and communicate with the outside; the end of the intermediate chamber close to the medium providing unit 30 does not extend to the end surface of the vector transfer rod 50, and the sidewall at this end may be provided with a through hole communicating with the intermediate chamber and communicating with the medium providing unit 30 through the through hole.

Alternatively, in the extending direction of the main extension line 103, the intermediate cavity may extend through the entire vector transfer rod 50, i.e., the outlet end of the medium conveying channel 51 is formed at the top end face of the vector transfer rod 50; the inlet end of the medium conveyance passage 51 is formed on the bottom end face of the vector transfer lever 50. The present embodiment is not limited to this, and preferably, the intermediate cavity forming the medium conveying passage 51 may extend through the entire vector transmission rod 50.

In the embodiment of the present application, the medium feeding path 51 is integrally provided on the vector transfer bar 50, and the medium feeding path 51 is a medium path between the complex member 20 and the medium supplying unit 30. Compared with the prior art, the accommodating cavity of the toothbrush handle is provided with a material conveying pipe communicated with the channel of the toothbrush head, and the material conveying pipe is positioned at one side of the accommodating cavity, in the embodiment of the application, the medium providing unit 30 provides the medium required for removing the foreign matters to the composite member 20 through the vector transmission rod 50 without additionally arranging the material conveying pipe in the shell 10 between the vector generating unit 40 and the composite member 20, so that the outline size of the shell 10 between the composite member 20 and the vector generating unit 40 can be reduced, the overall outline of the shell 10 is reduced, and the grasping comfort of a user is improved.

On the basis of the above-described embodiment, the end of the vector transmission rod 50 away from the composite member 20 in the embodiment of the present application may extend into the vector generation unit 40 and be connected to the power member of the vector generation unit 40. The vector transfer rod 50 may penetrate from an end of the vector generation unit 40 near the composite member 20 and be connected with a power member located in the vector generation unit 40.

Further, the power member in the vector generation unit 40 in the embodiment of the present application is capable of outputting eccentric power, and includes a driving shaft connected with the vector transmission rod 50 penetrating the vector generation unit 40 to transmit the eccentric power to the vector transmission rod 50, thereby vibrating the composite member 20 with respect to the target area.

For example, the vector generating unit 40 provided in the embodiment of the present application may be a micro reciprocal oscillator, and the power component thereof includes a driving shaft, a stator and a rotor, wherein the stator includes a permanent magnet fixedly disposed, the driving shaft is inserted into the rotor, and the driving shaft is sleeved with an iron core block, the iron core block is located in the permanent magnet, and the iron core block is wound with a coil winding.

When the coil winding is energized in the positive direction, the coil winding of the core block forms a magnetic field, and the rotor swings counterclockwise by a certain angle under the interaction of the magnetic field of the permanent magnet. On the contrary, when the coil winding is reversely electrified, the direction of the magnetic field formed by the coil winding of the iron core block is opposite to that of the previous magnetic field, and the rotor reversely swings for a certain angle under the interaction of the magnetic field and the magnetic field of the permanent magnet. When the coil is energized alternately in the positive direction and the reverse direction at a certain beat, the rotor can do reciprocating back and forth swing according to the frequency; in the non-energized state, the core block is always positioned at the middle position between the south pole and the north pole of the permanent magnet under the balance of the attraction force between the core block and the north pole.

As shown in fig. 4 and 5, in the embodiment of the present application, the vector transmission rod 50 is far from one end of the composite member 20, penetrates into the vector generation unit 40 from the end of the vector generation unit 40 close to the composite member 20, and can penetrate out of the vector generation unit 40 from the end of the vector generation unit 40 far from the composite member 20.

Illustratively, the axis of the vector transmission rod 50 is located on the main extension line 103, and the axis of the driving shaft of the power member is arranged offset from the main extension line 103, for example, the driving shaft of the power member may be located on one side of the vector transmission rod 50, with a power adapter disposed therebetween, and the transmission of power is achieved through the power adapter.

One end of the vector transmission rod 50 can penetrate in from the top end of the vector generation unit 40 and penetrate out from the bottom end of the vector generation unit 40, and the middle cavity of the vector transmission rod 50 is arranged to penetrate along the main extension line 103 and respectively extends to two end faces of the vector transmission rod 50, and the inlet end of the medium conveying channel 51 is communicated with the medium providing unit 30 positioned below the vector generation unit 40. With this arrangement, the medium can be further transferred between the medium supply unit 30 and the composite member 20 through the vector transfer bar 50, and the dimension of the outline of the portion of the housing 10 located between the medium supply unit 30 and the composite member 20 can be further reduced.

On the basis of the above embodiment, one end of the vector transfer rod 50 may penetrate through the top end of the vector generation unit 40 and penetrate out of the bottom end of the vector generation unit 40. The axis of the vector transmission rod 50 and the axis of the drive shaft of the power member are both located on the main extension line 103. I.e., the vector transmission rod 50, may serve as a drive shaft of the power member, i.e., the vector generation unit 40 includes the vector transmission rod 50 multiplexed as the drive shaft.

Illustratively, the vector transfer rod 50 may be a stainless steel rod body, which may include at least one segment, and adjacent segments may be connected together by welding or bonding. The vector transfer rod 50 is provided with a through hole penetrating along the direction of the main extension line 103, the inner wall of the through hole is smooth to form a smooth middle cavity, a medium outlet is formed at the top end of the vector transfer rod 50, and a medium inlet is formed at the bottom end of the vector transfer rod 50.

The medium outlet of the vector transfer rod 50 is communicated with the composite member 20, and the medium inlet of the vector transfer rod 50 is communicated with the medium providing unit 30, so that the medium provided by the medium providing unit 30 can be conveyed to the composite member 20 through the medium inlet, the medium conveying passage 51 and the medium outlet, so that the composite member 20 accelerates the removal of foreign matter in the target region.

With this arrangement, the embodiment of the present application multiplexes the vector transmission lever 50 as the drive shaft of the vector generation unit 40, and the vector transmission lever 50 penetrates the entire vector generation unit 40 in the direction of the main extension line 103 to communicate between the medium supply unit 30 and the composite member 20 through the medium conveyance passage 51 formed in the vector transmission lever 50, and the overall size of the portion of the housing 10 between the medium supply unit 30 and the composite member 20 can be further reduced.

As shown in fig. 6, and with reference to fig. 1 and 2, a medium supply unit 30 provided in the embodiment of the present application includes a medium conveying mechanism 31 and a medium container 32, where the medium conveying mechanism 31 and the medium container 32 are both disposed in the housing 10, and the medium conveying mechanism 31 is located on one side of the medium container 32.

Specifically, the medium conveying mechanism 31 and the vector generating unit 40 are arranged in the housing 10 at intervals along the direction of the main extension line 103, the medium conveying mechanism 31 is positioned on the side of the vector generating unit 40 away from the composite member 20, and the medium conveying mechanism 31 and the vector generating unit 40 are kept at a preset interval.

In other words, the medium conveyance mechanism 31 is located below the vector generation unit 40, the medium conveyance mechanism 31 includes a medium outflow end 312 and a medium inflow end 311, and the medium outflow end 312 communicates with the medium conveyance passage 51 of the vector transfer lever 50 through a pipe. The medium inflow end 311 communicates with the medium container 32 through a pipeline, so that the medium stored in the medium container 32 is conveyed into the medium conveying passage 51 through the medium inflow end 311 and the medium outflow end 312 by the medium conveying mechanism 31.

For example, the medium conveying mechanism 31 in the embodiment of the present application may be a pumping mechanism, including but not limited to a water pump, and the pumping mechanism is communicated with the bottom of the medium container 32 through a delivery pipe 33, and the delivery pipe 33 may be arranged along the extension direction of the main extension line 103 and between the medium conveying mechanism 31 and the medium container 32.

One end of the material conveying pipe 33 is communicated with the medium inflow end 311 of the medium conveying mechanism 31, the other end of the material conveying pipe 33 is communicated with the bottom of the medium container 32, when the composite member 20 needs to be conveyed, the medium conveying mechanism 31 starts to work, and the medium in the medium container 32 can be sucked into the medium conveying channel 51 under the suction action of the medium conveying mechanism 31 and is conveyed to the composite member 20 through the medium conveying channel 51.

On the basis of the above-described embodiment, the medium container 32 in the embodiment of the present application is offset to one side of the main extension line 103, and the medium container 32 is formed in the housing 10. The housing 10 includes an outer wall and an inner wall 106, wherein the outer wall is a peripheral sidewall of the housing 10 that is co-integrated with the biomimetic gripping surface, i.e., the biomimetic gripping surface is an outer surface of the outer wall.

The inner wall 106 is an inner wall plate disposed on the housing 10, the inner wall 106 is disposed along the extending direction of the main extending line 103, the upper end of the inner wall 106 extends to the second end 102 of the housing 10 and is connected with the inner side wall of the second end 102 of the housing 10 in a sealing manner, the bottom end of the inner wall 106 extends to the first end 101 of the housing 10 and is connected with the bottom wall of the first end 101 of the housing 10 in a sealing manner, so that a closed special-shaped cavity disposed along the main extending line 103 is defined between the inner wall 106 and the outer wall, and the special-shaped cavity is used for storing media.

For example, the inner wall 106 is located between the main extension line 103 and the first copying holding surface 104, that is, the inner wall 106 is disposed close to the first copying holding surface 104, and divides the inner cavity of the housing 10 into a first cavity and a second cavity (the second cavity is the above-mentioned special-shaped cavity), where the first cavity can be used for accommodating the medium conveying mechanism 31 and the vector generating unit 40, and the second cavity is used for storing the medium. In the extending direction of the main extension line 103, two ends of the second cavity extend to the first end 101 and the second end 102 of the housing 10, respectively, as shown in fig. 2, and the second cavity may be located at one side of the medium conveying mechanism 31 and the vector generating unit 40. Therefore, the volume of the special-shaped cavity can be increased to store more media.

In addition to the above embodiment, since the housing 10 is an unbalanced housing 10 and the first and second copying-gripping surfaces 104 and 105 are asymmetric with respect to the principal extension line 103, the distances between the first and second copying-gripping surfaces 104 and 105 and the principal extension line 103 are different. Further, the distance between each gripping surface and the main extension line 103 changes from equal to gradually decreasing from the beginning in the direction from the first end 101 to the second end 102 of the housing 10.

In the embodiment of the present application, since the distance between the first copying-holding surface 104 and the main extension line 103 varies significantly, the first copying-holding surface 104 will be described as an example. The first contoured gripping surface 104 at the first end 101 and the middle portion of the housing 10 is equidistant from the primary extension line 103, and the portion of the first contoured gripping surface 104 at the second end 102 of the housing 10 is progressively spaced from the primary extension line 103 by a decreasing distance, i.e., the outer diameter of the contour of the second end 102 of the housing 10 is progressively smaller, to provide the overall shape of the housing 10 that is more convenient for a user to grasp.

With continued reference to fig. 3, the composite member 20 of the present embodiment is detachably mounted on an end of the vector transmission rod 50 away from the vector generating unit 40, so that the composite member 20 and the vector transmission rod 50 can be easily disassembled and assembled when the composite member 20 needs to be replaced after long-term use.

For example, the integrated oral care device can be used to treat the mouth of a user as a power toothbrush or a dental irrigator, i.e., the integrated oral care device can both brush and rinse the teeth, and thus the composite member 20 can be a toothbrush head or a nozzle that is mounted to the vector transfer bar 50 when the user is required to brush the teeth and to the vector transfer bar 50 when the user is required to rinse the teeth. With this arrangement, a toothbrush/dental irrigator combination system can be achieved with a housing 10 having a contoured gripping surface, a set of vector generating units 40 and a media supply unit 30 to achieve both brushing and rinsing functions.

On the basis of the above embodiment, the composite member 20 provided in the embodiment of the present application may be a toothbrush head including a support head 21 and a plurality of bundles of bristles 23, the support head 21 being provided with a medium guide passage 22, and the medium guide passage 22 may communicate with a medium feeding passage 51 of a vector transfer bar 50, and may guide a medium from the medium feeding passage 51 into the support head 21.

The supporting head 21 has a bristle planting face provided with a plurality of planting holes, and a plurality of bundles of bristles 23 are respectively embedded in the plurality of planting holes, i.e., each planting hole has a bundle of bristles 23. Further, the depth of the planted bristles 23 in the planted holes is smaller than the distance from the planted faces of the bristles to the main extension line 103. That is, the brush bristles 23 are embedded in the bottom of the planting holes, which do not extend to the main extension line 103, so as to prevent the brush bristles 23 from extending into the medium guiding channel 22 and affecting the flow path of the medium in the medium guiding channel 22.

The supporting head 21 is further provided with a plurality of splashing holes 24, the plurality of splashing holes 24 are located on the bristle planting surface, and the splashing holes 24 can be arranged perpendicular to the bristle planting surface, or the splashing holes 24 are arranged obliquely relative to the bristle planting surface, which is not limited in this embodiment.

For example, the splash holes 24 may be located in the gaps between adjacent bristles 23 and extend in a direction perpendicular to the bristle planting plane. One end of the splash hole 24 can extend into the media guide channel 22 and communicate with the media guide channel 22 such that media located in the media guide channel 22 can flow through the splash hole 24 to the target area.

On the basis of the above embodiment, the composite member 20 and the end of the vector transmission lever 50 remote from the vector generation unit 40 may be connected by a latch. Specifically, one end of the vector transfer lever 50, which is away from the vector generation unit 40, may be inserted into the medium guide passage 22, and the center line of the medium guide passage 22 may be arranged along the main extension line 103, so that the composite member 20 mounted to the vector transfer lever 50 can be positioned on the same line as the vector transfer lever 50, which may improve vector efficiency of the vector transfer lever 50 to the composite member 20, and avoid vector loss.

Illustratively, the inner bore of the media guide channel 22 mates with the outer diameter of the vector transfer rod 50 to ensure that the vector transfer rod 50 can be inserted into the media guide channel 22. The medium guide path 22 has a bonding surface for positioning the vector transfer bar 50, and the bonding surface is parallel to the main extension line 103. The end of the vector transfer lever 50 has a milled surface 52 that conforms to the bonding surface, and when the vector transfer lever 50 is inserted into the media guide 22, the support head 21 is rotated so that the milled surface 52 of the vector transfer lever 50 mates with the bonding surface to complete the positioning of the vector transfer lever 50 with the composite member 20.

It should be noted that, the bonding surface is at a certain distance from the port of the medium guide passage 22 to ensure that the vector transmission rod 50 has a certain insertion depth in the medium guide passage 22, that is, one end of the vector transmission rod 50 away from the vector generation unit 40 is inserted into the medium guide passage 22 at a certain distance, so as to improve the reliability of connection and sealing between the two.

As shown in fig. 7, the integrated oral care device provided in the present embodiment further includes a power module 61, a charging module 62 and a control panel 80, wherein the power module 61 and the charging module 62 are sequentially disposed at an interval at an end of the media delivery mechanism 31 away from the composite member 20 along the direction of the main extension line 103, that is, the power module 61 and the charging module 62 are sequentially disposed below the media delivery mechanism 31. Preferably, the power supply module 61 and the charging module 62 are arranged along the extending direction of the main extension line 103.

Wherein the control panel 80 has a plurality of control buttons which control different working states of the integrated care device, respectively. For example, the plurality of control buttons include a switch button for switching the power on and off, and a button for selecting a different brushing mode or washing mode.

The control panel 80 is disposed adjacent to the second contoured gripping surface 105 of the housing 10, and the second contoured gripping surface 105 is provided with a through hole for exposing the control button, so that when the control panel 80 is installed in the housing 10, the control button can protrude from the through hole to facilitate the operation of the button by a user.

The power supply module 61, the charging module 62, the vector generation unit 40, and the medium conveyance mechanism 31 are mounted in the housing 10 for convenience. The integrated oral care device provided by the embodiment of the application further comprises a combined support 90 and a tail cover 70 arranged at the bottom end of the combined support 90, the combined support 90 has a plurality of mounting sites, the vector generation unit 40, the medium delivery mechanism 31 and the power module 61 can be sequentially pre-mounted on the combined support 90 along the extension direction of the main extension line 103, the charging module 62 is mounted on the tail cover 70, and the tail cover 70 is detachably mounted at the bottom of the combined support 90. So set up, can promote oral care device's integrated level, promote its packaging efficiency.

On the basis of the above embodiments, the first end 101 of the housing 10 provided in the embodiments of the present application is provided with the blocking cover 107, the blocking cover 107 is used for sealing the first end 101 of the housing 10, and a cavity is formed between the blocking cover 107 and the tail cover 70, and the cavity is communicated with the medium container 32 on one side of the housing 10.

As shown in fig. 8, the tail cap 70 is provided with a tail passage 71 communicating with the first chamber, and the tail passage 71 communicates with the medium inflow end 311 of the medium transport mechanism 31 via the conveyance pipe 33. Further, the first copying-holding surface 104 forming the medium container 32 is provided with a medium replenishment port communicating with the medium container 32, and the medium is replenished into the medium container 32 through the medium replenishment port.

With continued reference to fig. 7, a waterproof member 91, a support member 92, a first shock absorbing pad 93 and a second shock absorbing pad 94 are disposed in the assembly bracket 90, and along the extending direction of the main extension line 103, the waterproof member 91 and the support member 92 are sequentially sleeved on the vector transmission rod 50, and the waterproof member 91 seals the space between the outlet of the second end 102 of the housing 10 and the vector transmission rod 50 to prevent the liquid from entering the interior of the housing 10.

The first and second shock-absorbing pads 93 and 94 are sequentially sleeved on the vector generation unit 40, and the support 92 is disposed between the first shock-absorbing pad 93 and the sealing member to support the waterproof member 91. The first and second shock-absorbing pads 93 and 94 are respectively in contact with and abut against the inner wall of the combining bracket 90 to prevent the transmission of the vibration vector from the vector generating unit 40 to the housing 10, so as to improve the user's gripping comfort.

On the basis of the above embodiments, in the embodiments of the present application, the connecting member 34 is disposed between the medium conveying mechanism 31 and the vector transfer lever 50, the profiled sealing member 35 is disposed between the connecting member 34 and the medium outflow end 312 of the medium conveying mechanism 31, and the profiled sealing member 35 is also disposed between the connecting member 34 and the medium conveying channel 51 of the vector transfer lever 50, so that the medium outflow end 312 of the medium conveying mechanism 31 and the medium conveying channel 51 can be connected in a sealing manner.

Further, the connecting member 34 has a pipe for connecting the medium feeding mechanism 31 and the vector transmission lever 50. The connecting piece 34 comprises two channels which are positioned on different axes, wherein one channel is communicated with the medium outlet end 312 of the medium conveying mechanism 31, the other channel is communicated with the medium conveying channel 51 of the vector transfer rod 50, and the two channels are communicated together at the middle position, namely, the whole connecting piece 34 is provided with a pipeline in an inverted Z shape, so that certain alignment error between the medium outlet end 312 of the medium conveying mechanism 31 and the medium conveying channel 51 can be allowed, and the manufacturing difficulty is reduced.

In the present specification, each embodiment or implementation mode is described in a progressive manner, and the emphasis of each embodiment is on the difference from other embodiments, and the same and similar parts between the embodiments may be referred to each other.

It should be noted that references in the specification to "one embodiment," "an example embodiment," "some embodiments," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.

In general, terms should be understood at least in part by their use in context. For example, the term "one or more" as used herein may be used to describe any feature, structure, or characteristic in the singular or may be used to describe a combination of features, structures, or characteristics in the plural, depending, at least in part, on the context. Similarly, terms such as "a" or "the" may also be understood to convey a singular use or to convey a plural use, depending at least in part on the context.

It should be readily understood that "over 8230" \8230on "," over 82308230; "over 8230;" and "over 8230; \8230; over" in the present disclosure should be interpreted in the broadest manner such that "over 8230;" over 8230 ";" not only means "directly over something", but also includes the meaning of "over something" with intervening features or layers therebetween, and "over 8230;" over 8230 ";" or "over 8230, and" over "not only includes the meaning of" over "or" over "but also may include the meaning of" over "or" over "with no intervening features or layers therebetween (i.e., directly over something).

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application.

Claims (10)

1. An integrated oral care device, comprising:

a non-uniform housing (10) configured to have a biomimetic gripping surface suitable for gripping, the non-uniform housing (10) having a primary extent (103) and first and second ends (101, 102) disposed in opposition, the primary extent (103) extending from the first end (101) of the non-uniform housing (10) to the second end (102) of the non-uniform housing (10);

a composite member (20) configured to remove foreign matter within a target area, the composite member (20) being proximate to a second end (102) of the unbalanced enclosure (10) and distal to a first end (101) of the unbalanced enclosure (10);

a medium supply unit (30) configured to supply a medium that accelerates removal of the foreign matter to the composite member (20);

a vector generation unit (40) added at least partially within the unbalanced housing (10), the vector generation unit (40) receiving the composite member (20) through a vector transfer bar (50), the vector transfer bar (50) having a media transport channel (51), a centerline of the media transport channel (51) being arranged on the main extension line (103), the media transport channel (51) being located between the composite member (20) and the media providing unit (30), and the composite member (20) and the media providing unit (30) being in communication through the media transport channel (51).

2. The integrated oral care device of claim 1, wherein the vector transfer rod (50) penetrates the vector generating unit (40) from an end of the vector generating unit (40) proximate to the composite member (20) away from an end of the composite member (20).

3. The integrated oral care device of claim 2, wherein the vector transfer rod (50) is remote from an end of the composite member (20), passes into the vector generation unit (40) from an end of the vector generation unit (40) proximal to the composite member (20), and passes out of the vector generation unit (40) from an end of the vector generation unit (40) distal to the composite member (20).

4. The integrated oral care device according to claim 3, wherein the vector generation unit (40) comprises a power member outputting eccentric vibratory force, the power member comprising a drive shaft multiplexed by the vector transmission rod (50);

along the extension direction of the main extension line (103), the medium conveying channel (51) penetrates through one end of the vector transfer rod (50) far away from the composite member (20) and one end of the vector transfer rod (50) close to the composite member (20).

5. The integrated oral care device of claim 1, wherein the media supply unit (30) comprises a media delivery mechanism (31) and a media reservoir (32) disposed within the unbalanced housing (10);

the medium container (32) is arranged on a side offset from the main extension line (103);

the medium conveying mechanism (31) is spaced from the vector generating unit (40) by a preset distance along the extension direction of the main extension line (103), and the medium conveying mechanism (31) is positioned on one side, away from the composite member (20), of the vector generating unit (40); the medium supply device (31) has a medium inflow end (311) and a medium outflow end (312), the medium outflow end (312) is connected to the medium supply channel (51) via a line, and the medium inflow end (311) is connected to the medium container (32) via a line.

6. The integrated oral care device according to claim 5, wherein the medium reservoir (32) comprises an outer wall that is co-planar with the biomimetic gripping surface, and an inner wall (106) connected to the outer wall and extending along the main extension line (103), the inner wall (106) and the outer wall enclosing a closed contoured cavity extending along the main extension line (103), the closed contoured cavity storing the medium.

7. The integrated oral care device according to claim 1 or 6, wherein the biomimetic gripping surface comprises a first contoured gripping surface (104) and a second contoured gripping surface (105) asymmetrically distributed with respect to the main extension line (103), the first contoured gripping surface (104) and the second contoured gripping surface (105) being joined to form a closed annulus.

8. The integrated oral care device according to claim 7, characterized in that the distance of the first contoured gripping surface (104) with respect to the main extension line (103) varies from equal to decreasing gradually from a first end (101) of the unbalanced housing (10) to a second end (102) of the unbalanced housing (10) along the extension direction of the main extension line (103).

9. The integrated oral care device according to claim 1, wherein the composite member (20) comprises a support head (21) latchably connected to an end of the vector transfer rod (50) remote from the vector generation unit (40), a medium guide channel (22) communicating with the medium delivery channel (51) being provided inside the support head (21), a center line of the medium guide channel (22) being arranged on the main extension line (103); the supporting head (21) is provided with a bristle planting surface, a plurality of bundles of bristles (23) are planted on the bristle planting surface at intervals, and the depth of the bristles (23) planted on the bristle planting surface is not more than the distance from the bristle planting surface to the main extension line (103);

the bristle bearing surface is provided with a splash hole (24) which communicates with the medium guide channel (22).

10. The integrated oral care device of claim 9, wherein an inner bore diameter of the media guide channel (22) is adapted to an outer diameter of the vector transfer rod (50);

the medium guide channel (22) is provided with a bonding surface parallel to the main extension line (103), one end, away from the vector generating unit (40), of the vector transfer rod (50) is inserted into the medium guide channel (22) for a certain distance, and the part, located in the medium guide channel (22), of the vector transfer rod (50) is provided with a milling plane (52) attached to the bonding surface.

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