CN221547527U - Wireless charging support hollow rotating shaft structure - Google Patents

Abstract

The utility model discloses a hollow rotating shaft structure of a wireless charging bracket in the technical field of charger accessories, which comprises a rotating shaft main body and an angle adjusting piece, wherein the rotating shaft main body is provided with a first shaft which is connected with a first wireless charging part, so that the first wireless charging part turns over in a first plane around the first shaft, the angle adjusting piece is provided with a second shaft which is respectively connected with a second wireless charging part and the rotating shaft main body, so that the rotating shaft main body and the first wireless charging part rotate in a second plane around the second shaft, and the first plane intersects with the second plane; the inside of pivot main part is equipped with the cavity that is used for holding the wire and walks the line, and first wireless charging portion, the wireless charging portion of second are connected respectively at the both ends of wire. The utility model can adjust the multi-angle support between the two wireless charging parts, and the cavity in the rotating shaft main body can ensure that the whole rotating shaft structure can not influence internal wiring in the overturning and rotating processes, thereby ensuring the normal use of the first wireless charging part and the second wireless charging part.

Description

Wireless charging support hollow rotating shaft structure

Technical Field

The utility model relates to the technical field of charger accessories, in particular to a hollow rotating shaft structure of a wireless charging bracket.

Background

The wireless charger is an electric appliance indispensable in life of people, and utilizes a wireless charging technology to charge electronic equipment such as mobile phones and the like, so that the life of people is facilitated. The traditional wireless charger is mostly of a rectangular or cylindrical flat structure, can be only placed on a desktop or held by hand for use, and is required to be equipped with an additional support for use when three-dimensional display is required, so that inconvenience in use is caused.

In order to solve the defect, the existing charger involves a rotating device in its own structure, so that the charging part can be rotatably supported and can be rotatably stored when not in use. For example, patent publication number CN 214255793U discloses a folding rotary three-in-one wireless charging support, which comprises a base and a rotary seat, wherein at least one first wireless charger is arranged in the base, the rotary seat comprises a first rotary body and a second rotary body, a second wireless charger is arranged in the second rotary body, and the first rotary body and the second rotary body are rotationally connected through a first rotary device so as to realize rotary support of the second wireless charger.

However, such a structure can only realize the rotation support of the second rotation body, and when the electronic equipment such as the earphone needs to be charged, the electronic equipment such as the earphone is positioned at the rear side of the second rotation body, so that the second rotation body blocks the electronic equipment such as the earphone, and the use is inconvenient.

Therefore, a structure capable of rotating around the base while the second rotating body is turned over is required, and the rotating process does not affect the wireless charging function of the second rotating body.

Disclosure of utility model

In order to overcome the defects of the prior art, the utility model provides a hollow rotating shaft structure of a wireless charging bracket, which can meet the requirements of overturning and rotating between two different wireless charging parts under the condition of not influencing internal wiring and avoid the influence of the overturned wireless charging parts on the charging of other electronic equipment.

The technical scheme of the utility model is as follows:

The utility model provides a wireless support hollow pivot structure that charges which characterized in that includes:

A rotating shaft body having a first shaft connected with a first wireless charging part such that the first wireless charging part is turned around the first shaft in a first plane;

The angle adjusting piece is provided with a second shaft, and the second shaft is respectively connected with the second wireless charging part and the rotating shaft main body, so that the rotating shaft main body and the first wireless charging part rotate around the second shaft in a second plane;

The first plane intersects the second plane;

The inside of pivot main part is equipped with the cavity that is used for holding the wire and walks the line, the both ends of wire are connected respectively first wireless charging portion the wireless charging portion of second.

According to the above scheme, the utility model is characterized in that the angle adjusting piece is connected with the rotating shaft main body through an angle positioning structure, so that the rotating shaft main body is positioned after the angle adjusting piece rotates.

Further, the angle positioning structure comprises a pushing piece and a spring, wherein the front side of the pushing piece is abutted with the angle adjusting piece, and the rear side of the pushing piece is abutted with the spring, so that the spring is in a compressed state or in a natural state.

Furthermore, the front end part of the pushing piece is an arc-shaped bulge, a plurality of concave teeth are arranged on the periphery of the angle adjusting piece, and when the rotating shaft main body rotates, the pushing piece is abutted with the concave teeth at different positions.

According to the scheme, the wireless charging device is characterized in that the side face of the rotating shaft main body is provided with the angle limiting groove, the second wireless charging part is provided with the angle limiting piece, and the angle limiting piece stretches into the angle limiting groove, so that the rotating shaft main body rotates to a set angle and is limited by the angle limiting piece.

The utility model according to the above scheme is characterized in that the surface of the rotating shaft main body is provided with a rotating shaft sealing plate, and the rotating shaft sealing plate covers the upper side of the angle adjusting piece.

According to the above scheme, the utility model is characterized in that the angle adjusting piece is located in the rotating shaft main body, and the angle adjusting piece penetrates through the rotating shaft main body to be connected with the locking plate main body and is connected with the second wireless charging part through the locking plate main body.

Further, the locking plate main body is fixedly connected with the angle adjusting piece, and the locking plate main body is in limiting connection with the second wireless charging part.

Still further, be equipped with the draw-in groove on the jam plate main part, the jam plate main part is through the draw-in groove with the spacing connection of second wireless charging portion.

The utility model according to the above scheme is characterized in that the rotating shaft main body is provided with a rotating shaft rotating part, and the first wireless charging part is sleeved on the rotating shaft rotating part and rotates around a first shaft where the rotating shaft rotating part is located.

According to the scheme, the first wireless charging part can turn around the first shaft of the rotating shaft main body in the first plane, and meanwhile, the first wireless charging part can rotate in the second plane along with the second shaft of the rotating shaft main body around the angle adjusting piece, so that multi-angle support between the first wireless charging part and the second wireless charging part is realized, and the state of the second wireless charging part can be adjusted according to different use requirements of users; meanwhile, the cavity for accommodating the wiring is arranged in the rotating shaft main body, so that the internal wiring cannot be influenced in the overturning and rotating processes of the whole rotating shaft structure, and the normal use of the first wireless charging part and the second wireless charging part is ensured.

In addition, the turnover or rotation of the second wireless charging part in two planes can be realized through the rotating shaft main body and the angle adjusting piece, a complex intermediate medium is not needed, the whole rotating shaft structure is simplified, and the miniaturization of the wireless charger is facilitated.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of another view of the present utility model;

FIG. 3 is an exploded view of the structure of the present utility model;

FIG. 4 is a schematic view of the present utility model with the shaft seal plate removed;

Fig. 5 is a schematic structural diagram of a spindle body and an angle adjusting gear disc according to the present utility model.

In the drawings, the respective reference numerals are:

10. A rotating shaft main body; 11. a rotating shaft rotating part; 12. a guide groove; 13. a spindle center hole; 14. an angle limiting groove; 15. pushing the limiting part;

20. A rotating shaft sealing plate;

30. An angle adjusting gear disc; 31. concave teeth; 32. a gear disk center hole; 33. a gear disc positioning column; 34. a gear plate fastening hole;

40. A lock plate body; 41. a clamping groove; 42. a lock plate middle hole; 43. a locking plate fastening hole; 44. a lock plate positioning hole;

51. a first wire end a; 52. a first wire end B;

61. a second wire end a; 62. a second wire end B;

70. A screw;

81. A spring pressing plate; 82. a pushing member; 83. and (3) a spring.

Detailed Description

The utility model is further described below with reference to the drawings and embodiments:

As shown in fig. 1 to 5, in order to overcome the defect that the existing reversible wireless charger support can only turn over, but cannot realize more state display and influence the use of a user, the utility model provides a hollow rotating shaft structure of a wireless charging support, which can not influence internal wiring and ensure the normal use of each wireless charging part while realizing the turn over and rotation between two different wireless charging parts.

The hollow rotating shaft structure of the wireless charging bracket comprises a rotating shaft main body 10 and an angle adjusting piece, wherein a first wireless charging part is arranged on the rotating shaft main body 10 and can be turned over along the rotating shaft main body 10; the rotating shaft main body 10 is connected with the angle adjusting piece, and the angle adjusting piece is installed on the second wireless charging portion, so that the rotating shaft main body 10 drives the first wireless charging portion to rotate on the surface of the second wireless charging portion. Meanwhile, the rotating shaft main body 10 and the angle adjusting piece are internally provided with wiring channels so as to be connected with the first wireless charging part and the second wireless charging part through wires.

1. Spindle body

The rotation shaft main body 10 has a first shaft, which is connected to the first wireless charging portion such that the first wireless charging portion is flipped around the first shaft in a first plane (here, the first plane is a plane perpendicular to the first shaft). Specifically, the rotating shaft main body 10 is provided with a rotating shaft rotating portion 11 (the axis of the rotating shaft rotating portion 11 is a first axis), and the first wireless charging portion is sleeved on the rotating shaft rotating portion 11 and rotates around the first axis where the rotating shaft rotating portion 11 is located.

As shown in fig. 3, in order that the internal wire is not affected during the rotation of the first wireless charging portion, a cavity for accommodating the wire is provided in the spindle body 10 in the present utility model, and two ends of the wire are respectively connected to the first wireless charging portion and the second wireless charging portion. Preferably, the guide groove 12 is arranged in the cavity, and the wires are positioned in the guide groove 12, so that the wires in the cavity can be orderly arranged.

As shown in fig. 1 and 2, a spindle center hole 13 communicating with the cavity is provided on the spindle main body 10, and the lead wire passes through the spindle center hole 13. Specifically, the wires include a first wire and a second wire. The first wire has a first wire end a51, a first wire end B52: the first lead end B52 stretches into the second wireless charging part, the first lead end A51 stretches into the cavity of the rotating shaft main body 10 from the rotating shaft middle hole 13 and extends along the guide groove 12, and the rotating shaft rotating part 11 stretches out and stretches into the first wireless charging part so as to realize the connection of the first lead with the second wireless charging part; the second wire has a second wire end a61, a second wire end B62: the second wire end B62 extends into the second wireless charging portion, the first wire end a61 extends into the cavity of the spindle body 10 from the spindle center hole 13 and extends along the other guide groove 12, and extends out into the first wireless charging portion from the spindle rotating portion 11, so as to realize connection of the second wire to the first wireless charging portion and the second wireless charging portion.

Preferably, the surface of the rotating shaft main body 10 is provided with a rotating shaft sealing plate 20, the rotating shaft sealing plate 20 covers the upper side of the angle adjusting piece, and the cavity of the rotating shaft main body 10 can be shielded through the rotating shaft sealing plate 20, so that the protection of structural components in the rotating shaft main body 10 is facilitated, and the assembly of the inner structure of the rotating shaft main body 10 is facilitated.

As shown in fig. 5, in a preferred embodiment, the side surface of the rotating shaft main body 10 is provided with an angle limiting groove 14, and the second wireless charging part is provided with an angle limiting piece, and the angle limiting piece extends into the angle limiting groove 14, so that the rotating shaft main body 10 is limited by the angle limiting piece after rotating to a set angle. Through the mutual cooperation of the angle limiting groove 14 and the angle limiting piece, the rotation angle of the rotating shaft main body 10 can be limited, and the damage of an internal circuit caused by excessive rotation in one direction is avoided.

2. Angle adjusting piece

As shown in fig. 4 to 5, the angle adjuster has a second shaft, which is connected to the second wireless charging portion and the rotary shaft main body 10, respectively, such that the rotary shaft main body 10 and the first wireless charging portion rotate around the second shaft in a second plane (the second plane here is a plane perpendicular to the second shaft). In the utility model, the first plane and the second plane are intersected and are planes which are not parallel to each other, so that the multi-angle selection of the first wireless charging part can be realized. Preferably, the first axis is at a spatially perpendicular angle to the second axis, i.e. the first plane is perpendicular to the second plane. For example, when the second wireless charging portion is placed horizontally, the first axis is a horizontal axis, and the second axis is a vertical axis.

Preferably, the angle adjuster is an annular angle adjusting gear disc 30.

In this embodiment, the angle adjusting member is located in the rotating shaft main body 10, and the angle adjusting member passes through the rotating shaft main body 10 and then is connected with the locking plate main body 40, and is connected with the second wireless charging portion through the locking plate main body 40. In other embodiments, the angle adjusting member may be located outside the spindle body 10, so as to enable the spindle body 10 to rotate. Specifically, in order to implement the wiring of the wire, an adjusting member middle hole (i.e., a gear disc middle hole 32) is provided in the middle of the angle adjusting member (i.e., the angle adjusting gear disc 30), and the gear disc middle hole 32 is located in the rotating shaft middle hole 13, so that the angle adjusting gear disc 30 is coaxial with the rotating shaft main body 10, and the shaft is a second shaft. Correspondingly, the lock plate main body 40 is provided with a lock plate middle hole 42, and the lock plate middle hole 42 corresponds to the rotating shaft middle hole 13 and the gear disc middle hole 32 so that the lead wire passes through the lock plate middle hole 42.

In the process of realizing the rotation of the spindle body 10, the angle adjusting member is fixed relative to the second wireless charging portion. Specifically, the locking plate main body 40 is fixedly connected with the angle adjusting member, and the locking plate main body 40 is in limit connection with the second wireless charging portion, so that the angle adjusting member is connected with the second wireless charging portion through the locking plate main body 40, and the angle adjusting member is easier to install. In other embodiments, the angle adjusting member may be directly fixed to the second wireless charging portion, or connected through other structures, which is not specifically limited herein.

As shown in fig. 1 to 3, in the connection structure of the locking plate main body 40 and the second wireless charging portion: the locking plate main body 40 is provided with the clamping groove 41, the locking plate main body 40 is in limiting connection with the second wireless charging part through the clamping groove 41, meanwhile, the locking plate main body 40 is fastened with the angle adjusting part, after the locking plate main body 40 is installed on the second wireless charging part, the locking plate main body 40 is in limiting connection with the second wireless charging part, and further the angle adjusting part is fixed relative to the second wireless charging part.

In the connection structure of the locking plate main body 40 and the second wireless charging portion: the lock plate main body 40 is provided with a lock plate positioning hole 44, the angle adjusting piece (namely the angle adjusting gear disc 30) is provided with an adjusting piece positioning column (namely a gear disc positioning column 33), and the gear disc positioning column 33 stretches into the lock plate positioning hole 44, so that the angle adjusting gear disc 30 is in limit connection with the lock plate main body 40; the lock plate main body 40 is provided with a lock plate fastening hole 43, the angle adjustment gear plate 30 is provided with an adjusting piece fastening hole (i.e. a gear plate fastening hole 34), and a fastener (such as a screw 70) passes through the lock plate fastening hole 43 and then is connected with the gear plate fastening hole 34, so that the lock plate main body 40 is fixed with the angle adjustment gear plate 30.

As shown in fig. 3 and 4, the angle adjusting member is connected to the spindle body 10 through an angle positioning structure, so that the spindle body 10 is positioned after the angle adjusting member rotates. Specifically, the angle positioning structure includes a pushing member 82 and a spring 83, wherein the front side of the pushing member 82 abuts against the angle adjusting member, and the rear side abuts against the spring 83, so that the spring 83 is in a compressed state or the spring 83 is in a natural state. The front end of the pushing element 82 is an arc-shaped bulge, the periphery of the angle adjusting element is provided with a plurality of concave teeth 31, and when the rotating shaft main body 10 rotates, the pushing element 82 is abutted with the concave teeth 31 at different positions.

Preferably, a sliding space for accommodating the pushing member 82 and the spring 83 is provided in the spindle body 10, so that the pushing member 82 slides back and forth along the sliding space. The front end of the sliding space is provided with a protruding pushing limiting part 15, and the pushing rod is limited by the pushing limiting part 15 to slide forwards, so that the pushing rod is prevented from sliding out. In addition, the angle positioning structure further comprises a spring pushing plate 81, the spring pushing plate 81 is covered on the upper sides of the pushing piece 82 and the spring 83, the spring 83 and the pushing rod are protected through the spring pushing plate 81, and stability of the angle positioning structure is guaranteed.

According to the utility model, the first wireless charging part turns around the first shaft, so that the adjustment of the supporting angle of the first wireless charging part is realized, the first wireless charging part rotates around the second shaft along with the rotating shaft main body 10, the adjustment of the rotating angle of the supporting plane of the first wireless charging part on the surface of the second wireless charging part is realized, and the first wireless charging part and the second wireless charging part are mutually matched, so that the requirements of different use scenes of a user can be met.

It will be understood that modifications and variations will be apparent to those skilled in the art from the foregoing description, and it is intended that all such modifications and variations be included within the scope of the following claims.

While the utility model has been described above with reference to the accompanying drawings, it will be apparent that the implementation of the utility model is not limited by the above manner, and it is within the scope of the utility model to apply the inventive concept and technical solution to other situations as long as various improvements made by the inventive concept and technical solution are adopted, or without any improvement.

Claims (10)

1. The utility model provides a wireless support hollow pivot structure that charges which characterized in that includes:

A rotating shaft body having a first shaft connected with a first wireless charging part such that the first wireless charging part is turned around the first shaft in a first plane;

The angle adjusting piece is provided with a second shaft, and the second shaft is respectively connected with the second wireless charging part and the rotating shaft main body, so that the rotating shaft main body and the first wireless charging part rotate around the second shaft in a second plane;

The first plane intersects the second plane;

The inside of pivot main part is equipped with the cavity that is used for holding the wire and walks the line, the both ends of wire are connected respectively first wireless charging portion the wireless charging portion of second.

2. The wireless charging stand hollow shaft structure according to claim 1, wherein the angle adjusting member is connected to the shaft body through an angle positioning structure, so that the shaft body is positioned after the angle adjusting member is rotated.

3. The wireless charging stand hollow rotating shaft structure according to claim 2, wherein the angle positioning structure comprises a pushing member and a spring, the front side of the pushing member is abutted against the angle adjusting member, and the rear side of the pushing member is abutted against the spring, so that the spring is in a compressed state or in a natural state.

4. The hollow rotating shaft structure of the wireless charging bracket according to claim 3, wherein the front end part of the pushing piece is an arc-shaped bulge, a plurality of concave teeth are arranged on the periphery of the angle adjusting piece, and the pushing piece is abutted with the concave teeth at different positions when the rotating shaft main body rotates.

5. The wireless charging bracket hollow rotating shaft structure according to claim 1, wherein an angle limiting groove is formed in the side face of the rotating shaft main body, an angle limiting piece is arranged on the second wireless charging portion, and the angle limiting piece stretches into the angle limiting groove, so that the rotating shaft main body is limited by the angle limiting piece after rotating to a set angle.

6. The wireless charging stand hollow rotating shaft structure according to claim 1, wherein a rotating shaft sealing plate is arranged on the surface of the rotating shaft main body, and the rotating shaft sealing plate covers the upper side of the angle adjusting piece.

7. The wireless charging stand hollow rotating shaft structure according to claim 1, wherein the angle adjusting member is located in the rotating shaft main body, and the angle adjusting member is connected with the lock plate main body after passing through the rotating shaft main body, and is connected with the second wireless charging portion through the lock plate main body.

8. The wireless charging stand hollow shaft structure of claim 7, wherein the locking plate body is fixedly connected with the angle adjusting member, and the locking plate body is in limited connection with the second wireless charging portion.

9. The wireless charging bracket hollow rotating shaft structure according to claim 8, wherein a clamping groove is formed in the lock plate main body, and the lock plate main body is in limiting connection with the second wireless charging part through the clamping groove.

10. The wireless charging bracket hollow rotating shaft structure according to claim 1, wherein the rotating shaft main body is provided with a rotating shaft rotating part, and the first wireless charging part is sleeved on the rotating shaft rotating part and rotates around a first shaft where the rotating shaft rotating part is located.