CN106931288B

CN106931288B - Bracket assembly and electronic equipment

Info

Publication number: CN106931288B
Application number: CN201710325484.0A
Authority: CN
Inventors: 罗洋
Original assignee: Hefei Lianbao Information Technology Co Ltd
Current assignee: Hefei Lianbao Information Technology Co Ltd
Priority date: 2017-05-10
Filing date: 2017-05-10
Publication date: 2023-11-28
Anticipated expiration: 2037-05-10
Also published as: CN106931288A

Abstract

The invention discloses a bracket component and electronic equipment, the bracket component comprises: a support frame; a guide shaft; a movable body movable along the guide shaft; a bracket which can rotate relative to the moving body; a pretensioner for holding the moving body in contact with the bracket; a guide plate fixed to the carrier and having a guide surface, the movable body being capable of abutting at least partially against the guide surface; the movable body and the support are respectively provided with wavy end teeth which can be meshed with each other, so that when the support is rotated to enable the two wavy end teeth to be switched from the meshed state to the staggered state or from the staggered state to the meshed state, the movable body slides along the guide surface and pushes against the guide surface to force the support to drive the electronic equipment to rotate. According to the invention, the rotation of the bracket is converted into the movement of the moving body through the meshing of the two wavy end teeth and the staggered teeth, and the moving body slides on the guide surface of the support frame and pushes against the guide surface to convert the movement into the rotation of the support frame, so that the bracket and the support frame are linked.

Description

Bracket assembly and electronic equipment

Technical Field

The present disclosure relates to the field of computer technologies, and in particular, to a bracket assembly and an electronic device.

Background

The bracket component for supporting the electronic equipment such as the display end of the tablet personal computer or the two-in-one notebook computer in the prior art at least comprises a support frame, a bracket and a mounting component for mounting the bracket on the support frame; the support frame is used for being installed at the position, close to two apex angles, of the lower side plate of the electronic equipment, and the support frame is installed on the support frame through the installation assembly. In this way, the stand can be opened by rotating the stand to support the electronic device.

The opening or closing action of the bracket in the prior art is slower and the procedure is more complex.

Disclosure of Invention

In view of the foregoing technical problems in the prior art, embodiments of the present invention provide a bracket assembly.

In order to solve the technical problems, the technical scheme adopted by the embodiment of the invention is as follows:

a stand assembly for supporting an electronic device, the stand assembly comprising:

a carrier for fixing to the electronic device;

the guide shaft is pivoted on the bearing frame;

a moving body which is sleeved on the guide shaft and can move along the guide shaft;

the bracket is sleeved on the guide shaft and can rotate relative to the moving body;

a pretensioner for holding the moving body in contact with the bracket; and

the guide plate is fixed on the bearing frame;

wherein, a guide surface is formed on the guide plate, and the moving body can be at least partially abutted with the guide surface;

the movable body and the support are respectively provided with wavy end teeth which can be meshed with each other, so that when the support is rotated to enable the two wavy end teeth to be switched from a meshed state to a staggered state or from the staggered state to the meshed state, the movable body slides along the guide surface and pushes against the guide surface to force the carrier to drive the electronic equipment to rotate.

Preferably, the guide surface is inclined upwards from one end close to the bracket to one end far away from the bracket, so that when the two wavy end teeth are switched from the meshed state to the staggered state to drive the moving body, the movement of the moving body forces the bearing frame to drive the electronic equipment to rotate.

Preferably, the carrier has a mounting surface for coupling with the electronic device, and the wavy end teeth of the moving body and the wavy end teeth of the bracket are in an engaged state when the bracket is parallel to the mounting surface.

Preferably, the bracket comprises a rotating body sleeved on the guide shaft and a supporting rod fixed on the rotating body, and when the bracket rotates at 0-180 degrees relative to the mounting surface, the supporting rod at least sequentially has a first rotation angle for enabling the two wavy teeth to be in a staggered state and a second rotation angle for enabling the two wavy teeth to be in a meshed state; the carrier has a first rotation state in which the mounting surface thereof is parallel to the guide shaft, and a second rotation state in which the guide surface is brought into contact with the movable body when the strut is at the first rotation angle, and when the strut is rotated from the second rotation angle to the first rotation angle, the movable body is moved in a direction away from the bracket to urge the carrier to rotate from the second rotation state to the first rotation state by contact with the guide surface.

Preferably, when the carrier is in the first rotation state and the strut is switched to the first rotation angle, the moving body moves in a direction away from the bracket and restricts the carrier from rotating by contacting the guide surface.

Preferably, the support comprises a mounting part for combining with the electronic equipment and two extending arms which extend from the mounting part and are arranged in parallel, and the guide shaft is pivoted on the two extending arms.

Preferably, the guide plates comprise two guide plates, the two guide plates are respectively fixed on the two extending arms, and the guide surfaces are formed on the side edges of the guide plates; the moving body comprises a sleeve body sleeved on the guide shaft and two extending parts which radially extend from the sleeve body to the two guide plates so as to be in contact with the guide surfaces.

Preferably, the guide shaft is made of plastic material or rubber material, and the center of the guide shaft is provided with a wiring hole so that when the carrier is arranged on the electronic equipment, the antenna of the electronic equipment extends into the wiring hole.

Preferably, positioning columns are respectively arranged on two sides of the guide shaft, one end, away from the support, of the guide shaft and the two positioning columns is fixed through a connecting plate, the connecting plate is arranged in parallel with the moving body, and the other ends of the two positioning columns penetrate through the moving body to limit the moving body to rotate relative to the guide shaft.

Preferably, a U-shaped frame is arranged between the two extending arms, two side plates of the U-shaped frame are pivoted with the two extending arms through pin shafts, and the guide shaft is fixed on a bottom plate of the U-shaped frame so that the guide shaft is pivoted with the two extending arms.

The embodiment of the invention also discloses electronic equipment comprising the bracket assembly.

Compared with the prior art, the bracket component and the electronic equipment provided by the embodiment of the invention have the beneficial effects that: according to the invention, the rotation of the bracket is converted into the movement of the moving body through the meshing of the two wavy end teeth and the staggered teeth, and the moving body slides on the guide surface of the support frame and pushes against the guide surface to convert the movement into the rotation of the support frame, so that the bracket and the support frame are linked, and the opening or closing action of the bracket is accelerated.

Drawings

Fig. 1 is a schematic structural diagram of a bracket assembly according to an embodiment of the present invention.

Fig. 2 is a schematic structural view of a strut in a bracket assembly according to an embodiment of the present invention in a parallel state with a mounting surface.

Fig. 3 is a schematic structural view of a strut in a bracket assembly according to an embodiment of the present invention at a first rotation angle.

Fig. 4 is a schematic structural view of a strut in a bracket assembly according to an embodiment of the present invention when the strut is at a second rotation angle.

Fig. 5 is a schematic structural view of a support rod in a support assembly according to an embodiment of the present invention in a second rotation angle, and a support frame in a second rotation state.

Fig. 6 is a schematic structural diagram of a bracket assembly according to another embodiment of the present invention.

In the figure:

10-a support frame; 11-arm extension; 20-guiding shaft; 30-moving body; 40-a rotor; 50-supporting rod; 60-wavy end teeth; 70-a guide plate; 71-a guide surface; 80-U-shaped frame; 90-springs; 100-mounting an assembly; 110-connecting plates; 111-positioning columns.

Detailed Description

The present invention will be described in detail below with reference to the drawings and detailed description to enable those skilled in the art to better understand the technical scheme of the present invention.

As shown in fig. 1 to 6, an embodiment of the present invention discloses a stand assembly for supporting an electronic device, such as a tablet computer, a display end of a two-in-one notebook computer, and the like. The bracket assembly includes a carrier 10, a guide shaft 20, a moving body 30, a bracket, a pretensioner, and a guide plate 70. The carrier 10 is used for being fixed on the electronic device, for example, fixed at a position of a rear shell of the electronic device near a lower side (the lower side is contacted with or near a supporting plane where the electronic device is to be placed), the carrier 10 can be plate-shaped, and the carrier 10 is detachably connected with the electronic device through a fastener; the guide shaft 20 is pivoted to the carrier 10 and can rotate relative to the carrier 10 (or electronic equipment) and then maintain the rotation angle; the moving body 30 is sleeved on the guide shaft 20 and can move along the axial direction of the guide shaft 20; the support is also sleeved on the guide shaft 20 and can rotate relative to the moving body 30, the support comprises a rotating body 40 sleeved on the guide shaft 20 and a supporting rod 50 fixedly arranged on the rotating body 40, and the supporting rod 50 forms a certain angle with the electronic equipment through rotation so as to be used for supporting the electronic equipment; the pretensioner is used for keeping the moving body 30 in contact with the rotating body 40, the spring 90 can be used as the pretensioner, the spring 90 is sleeved on the guide shaft 20 and used for pushing the moving body 30 towards the direction of the rotating body 40 so as to keep the moving body 30 in contact with the rotating body 40 all the time; the guide plate 70 is fixed to the carrier 10.

As shown in fig. 2, a guide surface 71 is formed on the guide plate 70, the movable body 30 can be at least partially abutted against the guide surface 71, wavy end teeth 60 which can be engaged with each other are provided on the movable body 30 and the rotary body 40, respectively, and when the strut 50 drives the rotary body 40 to rotate, the wavy end teeth 60 are switched between the engaged state and the staggered state. When the wavy end teeth 60 are switched from the engaged state to the staggered state, the rotating body 40 drives the moving body 30 to move in a direction away from the rotating body 40, and when the wavy end teeth 60 are switched from the staggered state to the engaged state, the moving body 30 moves in a direction toward the rotating body 40 under the action of the pretensioner. In this way, when the wavy end teeth 60 are switched from the engaged state to the staggered state, the moving body 30 can move in a direction away from the rotating body 40 and simultaneously drive the carrier 10 and the electronic device to rotate by sliding on the guide surface 71 and pushing against the guide surface 71. When the wavy end teeth 60 are switched from the staggered teeth state to the engaged state, the moving body 30 can slide on the guiding surface 71 and push against the guiding surface 71 to drive the carrier 10 to drive the electronic device to rotate while moving towards the rotating body 40.

As can be seen from the above description, the embodiment of the present invention converts the rotation of the rotator 40 into the movement of the mover 30 by the engagement and staggered teeth of the two wavy end teeth 60, and converts the movement into the rotation of the carrier 10 by the mover 30 sliding on the guide surface 71 of the carrier 10 and pushing against the guide surface 71, so that the strut 50 and the carrier 10 are linked, in other words, when the strut 50 rotates in one degree of freedom with respect to the guide shaft 20, it also rotates in another degree of freedom with respect to the carrier 10.

The bracket assembly capable of realizing the linkage of the support rod 50 and the support frame 10 has more advantages in terms of supporting the electronic equipment, for example, the inclination angle of the support frame 10 relative to the supporting plane can be determined according to the opening angle of the support rod 50 on the supporting plane relative to the side edge of the electronic equipment, that is, the opening angle of the support rod 50 and the inclination angle of the support frame 10 can have a corresponding relationship; for another example, when the support bar 50 rotates in the direction of the electronic device in the supporting plane, the support bar 50 simultaneously rotates in the direction perpendicular to the supporting plane so that the bracket assembly is quickly folded at the side of the electronic device.

When the stand assembly is in a state of being folded on the electronic device, the support rod 50 needs to be kept in a parallel state with the plane where the electronic device is located, in order to keep the support rod 50 in the state when the support rod 50 is folded on the electronic device, in a preferred embodiment of the present invention, as shown in fig. 2, a plate surface of the carrier 10 is attached to a position of a rear shell of the electronic device near a lower side, the plate surface is a mounting surface of the carrier 10, and the engagement state relationship between the support rod 50 and the wavy end teeth 60 is as follows: when the strut 50 is parallel to the mounting face, the two undulating end teeth 60 are in engagement. In this way, when the lever 50 is rotated to be parallel to the mounting surface, the rotation of the rotator 40 is restricted to some extent due to the meshing rotation formed between the two wavy end teeth 60, so that the lever 50 can be maintained in a state parallel to the electronic device.

In the stand for supporting the electronic device, the user desires that after the stand 50 has reached the purpose of supporting the electronic device by rotating, the stand 50 has at least one opening angle so that the stand 50 can be maintained at the opening angle while also rotating the electronic device in a direction perpendicular to the supporting plane to adjust the inclination angle of the electronic device, and when the stand 50 is horizontally rotated in the supporting plane to approach the electronic device, the stand 50 is simultaneously rotated in the vertical plane to approach the electronic device, thereby finally enabling the stand assembly to be rapidly folded to the electronic device.

It should be noted that: when the bracket assembly is in the folded state, the supporting rod 50, the guide shaft 20 and the bearing frame 10 are all in a parallel state, that is, the included angle between the bearing frame 10 and the guide shaft 20 and the angle between the bearing frame 10 and the bracket are all 0 degrees.

To meet the above requirements of the user, in a preferred embodiment of the present invention, when the strut 50 is rotated at 0 ° to 180 ° relative to the mounting surface, the strut 50 has at least a first rotation angle for causing the two wave-shaped teeth to be in a staggered state and a second rotation angle for causing the wave-shaped teeth to be in an engaged state in sequence. In this manner, when the strut 50 is rotated to the second rotational angle, the stent can remain at that rotational angle due to the engagement of the undulating end teeth 60. And the guide surface 71 is inclined upward in a direction away from the rotating body 40, and the positional relationship of the guide surface 71 and the moving body 30 is configured such that: when the carrier 10 is parallel to the guide shaft 20 and the moving body 30 is closest to the rotating body 40. The moving body 30 and the guide surface 71 have a rotation gap for rotating the carrier 10 so that the carrier 10 can adjust an inclination angle with respect to the support plane; when the movable body 30 is farthest from the rotary body 40, the movable body 30 is in contact with the guide surface 71. Thus, as shown in fig. 4, when the strut 50 in the bracket assembly in the folded state needs to be opened to the second rotation angle, the moving body 30 is located at the position closest to the rotating body 40 due to the switching of the wavy end teeth 60 to the engaged state, and at this time, the moving body 30 has a rotation gap with the guiding surface 71, so that the inclination angle of the electronic device can be adjusted within the range defined by the two limit rotation states (i.e., the first rotation state and the second rotation state) of the carrier 10. When the bracket assembly is required to be folded, the supporting rod 50 is rotated from the second rotation angle to a state parallel to the electronic equipment, the supporting rod 50 is inevitably subjected to the first rotation angle during the rotation of the supporting rod 50, as shown in fig. 3 and 4, the wavy end teeth 60 are switched from the meshed body to the staggered tooth state during the rotation of the supporting rod 50 from the second rotation angle to the first rotation angle, the movable body 30 is moved from the position closest to the rotating body 40 to the position farthest from the rotating body 40, during the movement of the movable body 30, the movable body 30 is contacted with the guide surface 71 to force the carrier 10 to rotate to a state parallel to the guide shaft 20, and the movable body 30 is moved to the position closest to the rotating body 40 during the movement of the movable body 30, so that the carrier 10 is not driven to rotate again due to the fact that the carrier is not contacted with the guide surface 71, and finally the supporting rod 50, the guide shaft 20 and the carrier 10 are in the folded state.

As can be seen from the above, since the guide surface 71 is provided as an inclined upward surface, when the supporting bar 50 is brought toward the electronic device in the supporting plane, the socket 10 is simultaneously rotated in a direction parallel to the guide shaft 20, thereby achieving rapid folding of the bracket assembly.

Another advantage of embodiments of the present invention is that: as shown in fig. 3, when the strut 50 is rotated to the first rotation angle, since the wavy end teeth 60 are in the staggered state, the movable body 30 is in contact with the guide surface 71, so that the rotation of the carrier 10 is restricted, and the carrier 10 is maintained in a state perpendicular to the supporting plane, that is, the carrier 10 is in a state parallel to the guide shaft 20.

The bracket component with the structure is applied to the display end of the two-in-one notebook computer, and can enable the display end to have two modes relative to the supporting plane.

For example, four teeth are provided on the wave-shaped end teeth, such that the first angle of rotation of the strut 50 is preferably 45 ° and the second angle of rotation is 90 °. Thus, when the supporting rod 50 rotates to 45 degrees, the supporting frame 10 is kept in a state perpendicular to the supporting plane, and is in a flat plate mode, and when the supporting rod 50 rotates to 90 degrees, the supporting frame 10 can rotate at a certain angle, so that the display end is inclined to form a notebook computer mode.

Referring to fig. 6, in a preferred embodiment of the present invention, the support frame 10 includes a mounting portion for coupling with an electronic device, and two extending arms 11 extending from the mounting portion and disposed in parallel, and the guide shaft 20 is pivotally connected to the two extending arms 11 through a pin, and the guide shaft 20 has a function of rotating and maintaining a rotation angle state through a damping mounting assembly 100 sleeved on the pin.

In a preferred embodiment of the present invention, the guide plate 70 includes two guide plates 70 respectively disposed on the two extending arms 11, the two guide plates 70 are sleeved on the pins and respectively disposed on one side of the extending arms 11, and the guide plates 70 are prevented from rotating relative to the extending arms 11 by pins penetrating the extending arms 11, and the guide surfaces 71 are formed on the sides of the guide plates 70; the moving body 30 includes a sleeve body fitted over the guide shaft 20, and an extension portion radially extending from the sleeve body to the two guide plates 70 so as to be able to contact the guide surface 71. Thus, when the moving body 30 moves, the moving body 30 drives the carrier 10 to rotate by pushing against the guide surface 71 of the guide plate 70.

In a preferred embodiment of the present invention, as shown in fig. 6, positioning columns 111 are respectively disposed at two sides of the guide shaft 20, the positioning columns 111 are fixed to the pin shaft and perpendicular to each other, and one ends of the guide shaft 20 and the two positioning columns 111, which are far from the rotating body 40, are fixed by a connecting plate 110 parallel to the moving body 30, so that the guide shaft 20 and the two positioning columns 111 can be kept relatively fixed, a spring 90 as a pre-tightening member is sleeved on the guide shaft 20 and is located between the moving body 30 and the connecting plate 110, and the other ends of the positioning columns 111 penetrate through the moving body 30 to limit the rotation of the moving body 30 relative to the guide shaft 20. In addition, the positioning column 111 also has a guiding function for the movement of the moving body 30.

In another preferred embodiment of the present invention, as shown in fig. 1, a U-shaped bracket 80 is disposed between two extending arms 11, two side plates of the U-shaped bracket 80 are pivoted to the two extending arms 11 through pins, and a guide shaft 20 is fixed on a bottom plate of the U-shaped bracket 80 so that the guide shaft 20 is pivoted to the two extending arms 11, and in this embodiment, the guide shaft 20 is perpendicular to the bottom plate.

In order not to affect the signal receiving performance of the antenna of the electronic device having the entire metal case, the guide shaft 20 is made of a plastic material or a rubber material, and a routing hole is formed at the center of the guide shaft 20 so that the antenna of the electronic device extends into the routing hole, so that the antenna of the electronic device extends into the routing hole when the carrier 10 is mounted on the electronic device.

The above embodiments are only exemplary embodiments of the present invention and are not intended to limit the present invention, the scope of which is defined by the claims. Various modifications and equivalent arrangements of this invention will occur to those skilled in the art, and are intended to be within the spirit and scope of the invention.

Claims

1. A stand assembly for supporting an electronic device, the stand assembly comprising:

a carrier for fixing to the electronic device;

the guide shaft is pivoted on the bearing frame;

the bracket is sleeved on the guide shaft and can rotate relative to the moving body; the support comprises a rotating body sleeved on the guide shaft and a supporting rod fixed on the rotating body;

a pretensioner for holding the moving body in contact with the bracket; and

the guide plate is fixed on the bearing frame;

wherein, a guide surface is formed on the guide plate, and the moving body can be at least partially abutted with the guide surface; the guide surface is inclined upwards from one end close to the bracket to one end far away from the bracket;

2. The rack assembly of claim 1, wherein the carrier has a mounting surface for engaging the electronic device, the undulating end teeth of the mobile body and the undulating end teeth of the rack being in engagement when the rack is parallel to the mounting surface.

3. The bracket assembly of claim 2, wherein the strut has at least a first angle of rotation that places the two undulating end teeth in a staggered state and a second angle of rotation that places the two undulating end teeth in an engaged state in sequence when the bracket is rotated between 0 ° and 180 ° relative to the mounting surface; the carrier has a first rotation state in which the mounting surface thereof is parallel to the guide shaft, and a second rotation state in which the guide surface is brought into contact with the movable body when the strut is at the first rotation angle, and when the strut is rotated from the second rotation angle to the first rotation angle, the movable body is moved in a direction away from the bracket to urge the carrier to rotate from the second rotation state to the first rotation state by contact with the guide surface.

4. A bracket assembly according to claim 3, wherein when the carrier is in the first rotational state and the strut is switched to the first rotational angle, the movable body moves away from the bracket and restricts the carrier from rotating by contact with the guide surface.

5. The bracket assembly of claim 1, wherein the carrier includes a mounting portion for coupling with the electronic device and two arms extending from the mounting portion and disposed in parallel, the guide shaft being pivotally connected to the two arms.

6. The bracket assembly of claim 5, wherein the guide plate comprises two guide plates, the two guide plates are respectively fixed on the two extending arms, and the guide surface is formed on the side edge of the guide plate; the moving body comprises a sleeve body sleeved on the guide shaft and two extending parts which radially extend from the sleeve body to the two guide plates so as to be in contact with the guide surfaces.

7. The bracket assembly of claim 1, wherein the guide shaft is made of a plastic material or a rubber material, and a routing hole is formed in the center of the guide shaft so that an antenna of the electronic device protrudes into the routing hole when the carrier is mounted on the electronic device.

8. The bracket assembly according to claim 1, wherein positioning columns are respectively arranged on two sides of the guide shaft, one ends of the guide shaft and the two positioning columns, which are far away from the bracket, are fixed through a connecting plate, the connecting plate is arranged in parallel with the moving body, and the other ends of the two positioning columns penetrate through the moving body to limit the moving body to rotate relative to the guide shaft.

9. The bracket assembly of claim 5, wherein a U-shaped bracket is provided between the two arms, two side plates of the U-shaped bracket are pivotally connected to the two arms by a pin, and the guide shaft is fixed to a bottom plate of the U-shaped bracket so that the guide shaft is pivotally connected to the two arms.

10. An electronic device comprising the stand assembly of any one of claims 1 to 9.