CN111629088B - Electronic equipment - Google Patents

Abstract

The application provides an electronic device. The electronic equipment comprises an equipment body and a rotating piece, wherein the rotating piece can rotate relative to the equipment body, the equipment body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding piece, the second mounting hole is provided with a second sliding piece, and when the rotating piece rotates relative to the equipment body, the first sliding piece and the second sliding piece respectively support against the rotating piece. The electronic equipment provided by the application can form a gap between the equipment body and the rotating piece, avoid direct contact between the rotating piece and the equipment body, avoid scratch on the equipment body caused by rotation of the rotating piece, and ensure smoother movement of the rotating piece relative to the equipment body.

Description

Electronic equipment

Technical Field

The present disclosure relates to electronic technology, and in particular, to an electronic device.

Background

In order to realize various functions of the existing electronic devices, more and more functional devices are installed in the electronic devices, and how to design more and more functional devices in the limited space of the electronic devices is a current challenge. In the related art, the functional device is mounted on the rotating base, and then the rotating base rotates relative to the housing of the electronic device, however, a large friction exists between the rotating base and the housing, which easily results in unsmooth movement of the rotating base.

Disclosure of Invention

The embodiment of the application provides electronic equipment. The electronic device includes:

the device comprises a device body and a rotating piece, wherein the rotating piece can rotate relative to the device body, the device body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding piece, the second mounting hole is provided with a second sliding piece, and when the rotating piece rotates relative to the device body, the first sliding piece and the second sliding piece respectively support against the rotating piece.

The electronic equipment provided by the embodiment of the application comprises an equipment body and a rotating piece which are connected in a rotating way, wherein the rotating piece can rotate relative to the equipment body, the equipment body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding piece, the second mounting hole is provided with a second sliding piece, and when the rotating piece rotates relative to the equipment body, the first sliding piece and the second sliding piece respectively support against the rotating piece. Through the slider support in the rotating member, can make keep the clearance between rotating member and the equipment body, avoid rotating member and the direct contact of equipment body, can avoid the rotation of rotating member to cause the scratch to the equipment body, can reduce the frictional force when rotating member and the relative motion of equipment body, avoid the condition that the rotating member blocked, guarantee that the motion of rotating member relative equipment body is more smooth and easy.

The embodiment of the application also provides electronic equipment. The electronic equipment comprises an equipment body and a rotating piece, wherein the equipment body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding piece, the second mounting hole is provided with a second sliding piece, the rotating piece is rotationally connected to the equipment body, the first sliding piece is used for providing a first supporting force for the rotating piece, the second sliding piece is used for providing a second supporting force for the rotating piece, and the first supporting force and the second supporting force are mutually matched to limit the rotating piece.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a rotating member in a retracted state in an electronic device according to an embodiment of the present application.

Fig. 2 is a schematic structural view of a rotating member in an extended state in an electronic device according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of a first electronic device according to an embodiment of the present application.

Fig. 4 is a schematic structural diagram of a second electronic device according to an embodiment of the present application.

Fig. 5 is a schematic structural diagram of a third electronic device according to an embodiment of the present application.

Fig. 6 is a schematic structural diagram of a fourth electronic device according to an embodiment of the present application.

Fig. 7 is a schematic structural diagram of a fifth electronic device according to an embodiment of the present application.

Fig. 8 is a schematic structural diagram of a sixth electronic device according to an embodiment of the present application.

Fig. 9 is a schematic structural diagram of a seventh electronic device according to an embodiment of the present application.

Fig. 10 is a schematic structural diagram of an eighth electronic device according to an embodiment of the present application.

Fig. 11 is a schematic structural diagram of a ninth electronic device according to an embodiment of the present application.

Fig. 12 is a schematic structural diagram of a tenth electronic device according to an embodiment of the present application.

Fig. 13 is a schematic structural diagram of an eleventh electronic device according to an embodiment of the present application.

Fig. 14 is a schematic structural diagram of a twelfth electronic device according to an embodiment of the present application.

Fig. 15 is a schematic structural diagram of a thirteenth electronic device according to an embodiment of the present application.

Fig. 16 is a schematic structural diagram of a fourteenth electronic device according to an embodiment of the present application.

Fig. 17 is a schematic structural diagram of a fifteenth electronic device according to an embodiment of the present application.

Fig. 18 is a schematic structural diagram of a sixteenth electronic device according to an embodiment of the present application.

Fig. 19 is a schematic structural diagram of a seventeenth electronic device according to an embodiment of the present application.

Fig. 20 is a schematic structural diagram of an eighteenth electronic device according to an embodiment of the present application.

Fig. 21 is a schematic structural diagram of a nineteenth electronic device according to an embodiment of the present application.

Fig. 22 is a schematic structural diagram of a twentieth electronic device according to an embodiment of the present application.

Fig. 23 is a schematic structural view of a driving mechanism in an electronic device according to a preferred embodiment of the present application.

Fig. 24 is a schematic structural diagram of a twenty-first electronic device according to an embodiment of the present application.

Fig. 25 is a schematic structural diagram of a twenty-second electronic device according to an embodiment of the present application.

Fig. 26 is a schematic structural diagram of a twenty-third electronic device according to an embodiment of the present application.

Fig. 27 is a schematic structural diagram of a twenty-fourth electronic device according to an embodiment of the present application.

Fig. 28 is a schematic structural diagram of a twenty-fifth electronic device according to an embodiment of the present application.

Fig. 29 is a schematic structural view of a twenty-sixth electronic device according to an embodiment of the present application.

Fig. 30 is a schematic structural diagram of a twenty-seventh electronic device according to an embodiment of the present application.

Fig. 31 is a schematic structural diagram of a twenty-eighth electronic device according to an embodiment of the present application.

Fig. 32 is a schematic structural diagram of a twenty-ninth electronic device according to an embodiment of the present application.

Fig. 33 is a schematic structural diagram of a thirty-first electronic device according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without any inventive effort, are within the scope of the present application.

Referring to fig. 1, 2, 3 and 4, the electronic device 10 includes a device body 100 and a rotating member 200, the device body 100 and the rotating member 200 are rotatably connected, the device body 100 is provided with a sliding member 300, the sliding member 300 can slide relative to the rotating member 200, and the sliding member 300 abuts against the rotating member 200, so that the rotating member 200 rotates along a preset track relative to the device body 100.

The electronic device 10 may be any device having communication and storage capabilities. For example: tablet personal computers, mobile phones, electronic readers, remote controllers, personal computers (Personal Computer, PCs), notebook computers, vehicle-mounted devices, network televisions, wearable devices and other intelligent devices with network functions.

The device body 100 is configured to remove the rotating member 200 from the electronic device 10, and the device body 100 includes a battery cover 110, a display 120, and a middle frame 130. In one embodiment, the battery cover 110 is secured to the middle frame 130, and the display 120 is secured to the middle frame 130. In another embodiment, the middle frame 130 is accommodated in the battery cover 110, and the display 120 is fixed to the battery cover 110.

The rotating member 200 is provided with a functional component 400, and the functional component 400 may be a camera module, a flash lamp module, a near light sensor module, or a structural light sensor module. When the rotating member 200 rotates relative to the device body 100, the functional component 400 can extend out of the device body 100, so that the functions of the functional component 400 can be realized out of the device body 100, which is helpful for the electronic device 10 to present various structure transformation modes, and expands the application range of the electronic device 10. When the functional module 400 is a camera module, the camera module is mounted on the rotating member 200, and the camera module is disposed obliquely relative to the rotating member 200. When the rotating member 200 extends out of the accommodating groove 100A, the image captured by the camera module is a normal viewing angle. The fact that the image captured by the camera module is at the normal viewing angle means that the image captured by the camera module accords with the daily photographing habit of people, that is, the viewing angle of the image is adapted to the device body 100.

The sliding member 300 may be a ball, a roller, or other sliding structures. The sliding member 300 is located on the apparatus body 100 and can slide relative to the rotating member 200, and the sliding member 300 abuts against the rotating member 200 to assist the rotating member 200 to rotate along a predetermined track relative to the apparatus body 100.

Further, in some embodiments, the sliding member 300 may be connected to the apparatus body 100 through a fixing member, the fixing member may be a rotating shaft T, the sliding member 300 may be relatively stationary with respect to the apparatus body 100, and the sliding member 300 may also relatively move with respect to the apparatus body 100. The sliding member 300 and the rotating member 200 are relatively movable. In other embodiments, the apparatus body 100 may be perforated, and the sliding member 300 is accommodated in the hole, so that the sliding member 300 is prevented from being fixed by a fixing member, and the sliding member 300 is installed in a small space of the apparatus body 100, which is helpful for realizing the light and thin design of the electronic apparatus 10. Through propping against the rotating piece 200 by the sliding piece 300, a certain gap can be kept between the rotating piece 200 and the equipment body 100, the rotating piece 200 is prevented from being in direct contact with the equipment body 100, friction force between the rotating piece 200 and the equipment body 100 is reduced, and smooth movement of the rotating piece 200 relative to the equipment body 100 is ensured. Further, when the sliding member 300 is a ball, the ball is in point contact with the rotating member 200, and the surface contact between the rotating member 200 and the apparatus body 100 is small in point contact, so that the friction force is small due to small friction contact area, so that the rotating member 200 can move more smoothly relative to the apparatus body 100, and further, the situation that the rotating member 200 is jammed can be avoided. Furthermore, since the rotating member 200 is not in direct contact with the apparatus body 100, the apparatus body 100 is prevented from being scratched by the movement of the rotating member 200, and the anode layer of the apparatus body 100 is damaged.

In some possible embodiments, the rotating member 200 is rotatably connected to the apparatus body 100 through a rotation shaft T. The rotating shaft T is fixed on the rotating member 200, the device body 100 is provided with a first fixing hole, and the rotating shaft T is accommodated in the first fixing hole. Alternatively, the rotating shaft T is fixed on the apparatus body 100, the rotating member 200 is provided with a second fixing hole, and the rotating shaft T is accommodated in the second fixing hole.

With continued reference to fig. 5, in other possible embodiments, the rotating member 200 includes a rotating body 210 and a fastening portion 220, the apparatus body 100 has a fastening slot 100b, and the fastening portion 220 is received in the fastening slot 100b and can rotate in the fastening slot 100 b. The rotary body 210 rotates relative to the apparatus body 100 through the engagement part 220. The fastening part 220 is in a hook shape and can hook the inner wall of the fastening groove 100b, so that the rotary body 210 can be prevented from falling off from the device body 100. And because the buckling part 220 can rotate in the buckling groove 100b, the rotating body 210 can be tightly attached to the outer wall of the buckling groove 100b of the equipment body 100 after rotating by controlling the movement track of the buckling part 220 relative to the rotating shaft T, so that the situation that the appearance surface of the electronic equipment 10 presents a broken difference after the rotating piece 200 rotates relative to the equipment body 100 can be avoided. In other words, the present embodiment can solve the problem of the electronic device 10 with poor disconnection, thereby improving the uniformity of the appearance of the electronic device 10.

The electronic device 10 provided in the embodiment of the application includes a device body 100 and a rotating member 200 rotatably connected, wherein a sliding member 300 is mounted on the device body 100, the sliding member 300 can slide relative to the rotating member 200, and when the rotating member 200 rotates relative to the device body 100, the sliding member 300 abuts against the rotating member 200, so that the rotating member 200 rotates along a preset track relative to the device body 100. Through slider 300 support in rotating member 200, can make keeping the clearance between rotating member 200 and the equipment body 100, avoid rotating member 200 and equipment body 100 direct contact to can avoid the motion of rotating member 200 to cause the scratch to equipment body 100, and can reduce the frictional force when rotating member 200 and equipment body 100 relative motion, avoid the condition that rotating member 200 blocked, guarantee that the motion of rotating member 200 is more smooth and easy relative to equipment body 100. And the sliding piece 300 is propped against the rotating piece 200 to slide, so that the rotating piece 200 is prevented from unnecessarily shaking on the premise of ensuring the normal sliding of the rotating piece 200, and the structural arrangement of the electronic equipment 10 is more refined.

With continued reference to fig. 6, in one embodiment, the apparatus body 100 has a receiving groove 100A, the rotating member 200 is at least partially received in the receiving groove 100A, and the rotating member 200 includes a first end 201 and a second end 202 disposed opposite to each other, and the first end 201 is rotatably connected to the apparatus body 100. When the first end 201 is rotated relative to the apparatus body 100, the second end 202 may extend or retract into the receiving slot 100A,

Specifically, the rotating member 200 includes a first state of being completely accommodated in the accommodating groove 100A and a second state of being partially accommodated in the accommodating groove 100A. When the rotating member 200 is in the first state, an orthographic projection of the rotating member 200 on the apparatus body 100 falls within a contour of the apparatus body 100; when the rotary member 200 is in the second state, the orthographic projection portion of the rotary member 200 on the apparatus body 100 protrudes outside the outline of the apparatus body 100.

The first end 201 is adjacent to one side of the device body 100 to form an avoidance space 100B, the avoidance space 100B is located in the direction of the appearance surface of the device body 100 to the inside of the device body 100, and the avoidance space 100B is used for avoiding components arranged in the device body 100. Because the avoidance space 100B is located inside the device body 100, during processing, the knife lifting part of the knife is not located on the appearance surface of the device body 100, and sharp corners are not left on the appearance surface of the device body 100, so that on one hand, the structural strength of the device body 100 can be enhanced, and on the other hand, the appearance consistency of the electronic device 10 can be improved.

The device body 100 has a relief groove 100C on a side adjacent to the rotary member 200, where the relief groove 100C is used to relieve a part of the structure of the rotary member 200, so as to avoid interference with the rotation process of the rotary member 200. The avoidance groove 100C is formed in one side, close to the rotating member 200, of the device body 100, and part of the structure of the rotating member 200 can be accommodated, that is, the shape of the avoidance groove 100C is the same as that of part of the structure of the rotating member 200, so that the arrangement space of components in the electronic device 10 can be saved, and the arrangement of components in the electronic device 10 is more compact. In addition, the rotary member 200 can be pushed out of the housing groove 100A of the apparatus body 100 with a smaller pushing stroke, contributing to saving power consumption.

With continued reference to fig. 7 and 8, the apparatus body 100 has a mounting hole 101, the sliding member 300 is received in the mounting hole 101, a limiting member 500 is disposed at an opening of the mounting hole 101, and the limiting member 500 is used for limiting the sliding member 300.

The mounting hole 101 communicates with the accommodating groove 100A, and the slider 300 is located at a communication portion between the mounting hole 101 and the accommodating groove 100A. The opening of the mounting hole 101 is provided with a limiting member 500, and the limiting member 500 abuts against the sliding member 300 to prevent the sliding member 300 from being separated from the mounting hole 101. The stop 500 may be a hardware press.

With continued reference to fig. 9, in one embodiment, the device body 100 includes a front surface 102, a back surface 103 opposite to the front surface 102, and a side surface 104 located between the front surface 102 and the back surface 103, the mounting hole 101 includes a first mounting hole 101a and a second mounting hole 101b, the first mounting hole 101a is opened at the front surface 102, the second mounting hole 101b is opened at the back surface 103, and the receiving slot 100A is opened at the side surface 104. The first mounting hole 101a is provided with a first slider 310, the second mounting hole 101b is provided with a second slider 320, and when the rotating member 200 rotates relative to the apparatus body 100, the first slider 310 and the second slider 320 respectively abut against the rotating member 200. The limiting member 500 includes a first limiting member 510 and a second limiting member 520, where the first limiting member 510 is fixed at the opening of the first mounting hole 101a and abuts against the first sliding member 310, and the second limiting member 520 is fixed at the opening of the second mounting hole 101b and abuts against the second sliding member 320. Since the mounting hole 101 includes the first and second mounting holes 101a and 101b, the first and second sliders 310 and 320 can be mounted from the first and second mounting holes 101a and 101b, respectively, and thus, the mounting and dismounting of the first and second sliders 310 and 320 can be facilitated.

Specifically, in the present embodiment, the sliding member 300 includes a first sliding member 310 and a second sliding member 320, where the first sliding member 310 and the second sliding member 320 are abutted against the rotating member 200, so that a gap is maintained between the rotating member 200 and the apparatus body 100, and thus scratches caused by movement of the rotating member 200 on the apparatus body 100 are avoided. The first sliding member 310 and the second sliding member 320 are symmetrically distributed along a symmetry plane 200A of the rotating member 200, and the first sliding member 310 and the second sliding member 320 are propped against the rotating member 200, so that the device body 100 and the rotating member 200 can be prevented from being in direct contact, the friction area is reduced, the friction force can be further reduced, and the rotating member 200 can move relatively smoothly relative to the device body 100. When the first slider 310 and the second slider 320 are balls, the contact between the first slider 310 and the second slider 320 and the rotating member 200 is point contact, so that the friction force during rotation of the rotating member 200 can be reduced to the greatest extent, and thus, the occurrence of seizing can be avoided.

In one embodiment, the method for processing the apparatus body 100 includes, but is not limited to, the following steps:

(a1) A blank is provided having oppositely disposed first and second surfaces and a side 104 connected between the first and second surfaces.

(b1) The sides 104 of the blank are machined to form the receiving pocket 100A.

(c1) The first surface of the blank is machined to form the mounting hole 101.

In another embodiment, the method for processing the apparatus body 100 includes, but is not limited to, the following steps:

(a2) A blank is provided having oppositely disposed first and second surfaces and a side 104 connected between the first and second surfaces.

(b2) The sides 104 of the blank are machined to form the receiving pocket 100A.

(c2) The first and second surfaces of the blank are machined to form first and second mounting holes 101a and 101b, respectively.

Wherein the first surface finish forms the front side 102 and the second surface finish forms the back side 103.

With continued reference to fig. 10, in one possible embodiment, the first mounting hole 101a communicates with the second mounting hole 101b, and the first sliding member 310 abuts against the second sliding member 320.

Specifically, the first mounting hole 101a and the second mounting hole 101b are communicated to form the mounting hole 101, the first slider 310 and the second slider 320 are both located in the mounting hole 101, and the first slider 310 is directly contacted with the second slider 320. That is, the first slider 310 and the second slider 320 have relative sliding therebetween, and the first slider 310 and the second slider 320 are both abutted against the rotating member 200. The first sliding piece 310 is directly abutted against the second sliding piece 320, the first sliding piece 310 and the second sliding piece 320 can slide relatively, so that the relative movement between the first sliding piece 310 and the second sliding piece 320 is smoother, and because the first sliding piece 310 and the second sliding piece 320 have the same mechanical property, the first sliding piece 310 and the second sliding piece 320 are abutted against each other, the abutting force between the first sliding piece 310 and the second sliding piece 320 is more uniform, the first sliding piece 310 and the second sliding piece 320 are symmetrically distributed along one symmetrical surface 200A of the rotating piece 200, and the situation that the rotating piece 200 generates a certain offset due to uneven stress between the first sliding piece 310 and the second sliding piece 320, so that the clamping is possibly caused is avoided. And the first sliding member 310 and the second sliding member 320 are mutually matched and mutually supported on the rotating member 200, when the components of the supporting force of the first sliding member 310 and the second sliding member 320 on the rotating member 200 in the thickness direction of the rotating member 200 are consistent, the rotating member 200 can be balanced in stress, namely, the rotating member 200 can be positioned in the middle part of the accommodating groove 100A, so that the gap between the rotating member 200 and the equipment body 100 is ensured, and the situation that the rotating member 200 is clamped can be better avoided.

With continued reference to fig. 11, in another possible embodiment, a spacer 550 is disposed between the first mounting hole 101a and the second mounting hole 101b, the spacer 550 isolating the first slider 310 within the first mounting hole 101a and isolating the second slider 320 within the second mounting hole 101 b.

Wherein the spacer 550 is spaced apart from the rotator 200. That is, the spacer 550 does not interfere with the movement of the rotary member 200, and it is possible to ensure smoother movement of the rotary member 200 with respect to the apparatus body 100. The spacer 550 is disposed between the first mounting hole 101a and the second mounting hole 101b, and the first slider 310 is spaced apart in the first mounting hole 101a, and the second slider 320 is spaced apart in the second mounting hole 101b, so that interference between the first slider 310 and the second slider 320 due to inconsistent movement directions can be avoided. Given that the first sliding member 310 and the second sliding member 320 move in an unsynchronized manner, they will interfere with each other, which may cause uneven stress between the first sliding member 310 and the second sliding member 320, and when such uneven stress is transferred to the rotating member 200, the rotating member 200 will shift, so that a gap between the rotating member 200 and the device body 100 cannot be ensured, and at this time, the rotating member 200 is at risk of seizing, and normal application functions of the electronic device 10 cannot be ensured.

In an embodiment, the spacer 550 may be additionally provided, not being a part of the rotating member 200 itself, or not being a part of the apparatus body 100 itself, and the spacer 550 is fixedly mounted on the apparatus body 100 or mounted on the rotating member 200 to form a separation between the first slider 310 and the second slider 320.

In another embodiment, the spacer 550 is a part of the device body 100, and the spacer 550 is formed together when the device body 100 is formed, so that a fixing structure of the spacer 550 is not required to be additionally provided, which is helpful for realizing the light and thin design of the electronic device 10.

In yet another embodiment, the spacer 550 is a part of the rotator 200, and the spacer 550 is formed together when the rotator 200 is formed, so that a fixing structure of the spacer 550 is not required to be additionally provided, which contributes to the light and thin design of the electronic device 10.

With continued reference to fig. 12, the first mounting hole 101a includes a first hole 1011 and a second hole 1012 which are connected and are disposed opposite to each other, the first hole 1011 is disposed adjacent to the second mounting hole 101b with respect to the second hole 1012, a radial dimension of the first hole 1011 is smaller than a radial dimension of the second hole 1012, the first hole 1011 is configured to receive the first slider 310, and the second hole 1012 is configured to mount the first stopper 510.

The second mounting hole 101b includes a third hole 1013 and a fourth hole 1014, which are connected and are disposed opposite to each other, the third hole 1013 is disposed adjacent to the first mounting hole 101a with respect to the fourth hole 1014, a radial dimension of the third hole 1013 is smaller than a radial dimension of the fourth hole 1014, the third hole 1013 is configured to receive the second slider 320, and the fourth hole 1014 is configured to mount the second stopper 520. When the radial dimension of the first hole 1011 is smaller than the radial dimension of the second hole 1012, the first slider 310 is convenient to be mounted in the first hole 1011, and the first stopper 510 is convenient to be fixed on the bottom wall of the second hole 1012, and the first stopper 510 is convenient to be detached. Also, when the radial dimension of the third hole 1013 is smaller than the radial dimension of the fourth hole 1014, the second slider 320 is easily installed in the third hole 1013, and the second stopper 520 is easily fixed to the bottom wall of the fourth hole 1014, and the second stopper 520 is easily removed.

With continued reference to fig. 13, in another possible embodiment, the portion of the rotating member 200 adjacent to the first mounting hole 101a and the second mounting hole 101b is arc-shaped, and includes a first arc-shaped portion 2001 and a second arc-shaped portion 2002 connected to each other, the first sliding member 310 is attached to the first arc-shaped portion 2001, and the second sliding member 320 is attached to the second arc-shaped portion 2002.

Specifically, when the abutting portions of the rotating member 200, the first sliding member 310 and the second sliding member 320 are arc-shaped, the stress at the abutting portions is in a divergent distribution, so that the stress of the rotating member 200 at the abutting portions is more uniform, and the problem of stress concentration is avoided. When the first slider 310 is attached to the first arc portion 2001 and slides relative to the first arc portion 2001, and the second slider 320 is attached to the second arc portion 2002 and slides relative to the second arc portion 2002, the movement of the first slider 310 and the second slider 320 can be smoother, so that, on one hand, the rotation of the rotating member 200 relative to the apparatus body 100 is smoother, and on the other hand, because the movement of the first slider 310 and the second slider 320 relative to the rotating member 200 is smoother, the holding force of the first slider 310 and the second slider 320 against the rotating member 200 is also more uniform, thereby avoiding unnecessary offset of the rotating member 200, and facilitating the movement of the rotating member 200 relative to the apparatus body 100.

Further, the bending curvature center of the first arc portion 2001 is located at a side away from the first mounting hole 101a, the bending curvature center of the second arc portion 2002 is located at a side away from the second mounting hole 101b, and the bending curvature radius of the first arc portion 2001 is consistent with the bending curvature radius of the second arc portion 2002.

Specifically, the first arcuate portion 2001 assumes an outwardly arched shape, and the second arcuate portion 2002 also assumes an outwardly arched shape. When the radius of curvature of the first arc portion 2001 is the same as the radius of curvature of the second arc portion 2002, and the volumes of the first slider 310 and the second slider 320 are kept the same, the holding force of the first slider 310 against the first arc portion 2001 and the holding force of the second slider 320 against the second arc portion 2002 are kept the same, at this time, the holding forces of the first slider 310 and the second slider 320 against the rotating member 200 can be kept uniform, so that the rotating member 200 can keep a centered position with respect to the apparatus body 100, so that the gap between the rotating member 200 and the apparatus body 100 can be ensured more easily, and the rotation of the rotating member 200 with respect to the apparatus body 100 can be smoother.

With continued reference to fig. 14, the first arcuate portion 2001 has a first sliding groove 2003, the second arcuate portion 2002 has a second sliding groove 2004, the first sliding member 310 is slidable in the first sliding groove 2003, and the second sliding member 320 is slidable in the second sliding groove 2004 when the rotating member 200 rotates relative to the apparatus body 100.

Specifically, the first sliding groove 2003 is used for limiting the first sliding member 310, the second sliding groove 2004 is used for limiting the second sliding member 320, and the first sliding groove 2003 and the second sliding groove 2004 are parallel and spaced, so that the direction of the holding force of the first sliding member 310 and the second sliding member 320 on the rotating member 200 can be kept unchanged all the time. That is, in the process of rotating the rotating member 200 relative to the apparatus body 100, the magnitude of the holding force of the first sliding member 310 against the rotating member 200 and the holding force of the second sliding member 320 against the rotating member 200 are always uniform, so that the situation that the rotating member 200 is stressed unevenly in the rotating process of the rotating member 200 relative to the apparatus body 100 can be avoided, the gap between the rotating member 200 and the apparatus body 100 is conveniently ensured, the situation that the rotating member 200 is jammed is avoided, and the rotating member 200 can rotate relatively to the apparatus body 100 smoothly.

Further, in an embodiment, the first sliding member 310 slides against the first sliding groove 2003, and the second sliding member 320 slides against the second sliding groove 2004. At this time, the first slider 310 is in surface contact with the first runner 2003, and the second slider 320 is also in surface contact with the second runner 2004. In this embodiment, the first sliding member 310 and the second sliding member 320 are intentionally in surface contact with the rotating member 200, so that the contact area between the first sliding member 310 and the first chute 2003 is increased, and the contact area between the second sliding member 320 and the second chute 2004 is increased, so that the first chute 2003 is more stable in limiting the first sliding member 310, and the second chute 2004 is more stable in limiting the second sliding member 320, so that shaking of the rotating member 200 in the rotating process of the rotating member 200 relative to the device body 100 can be avoided, and the rotating of the rotating member 200 relative to the device body 100 can be more stable.

In yet another possible embodiment, the sliding member 300 is a ball, the volumes of the first sliding member 310 and the second sliding member 320 are consistent, the first mounting hole 101a is opposite to the second mounting hole 101b, and the radial dimensions of the first mounting hole 101a and the second mounting hole 101b are consistent.

Specifically, the first slider 310 is completely aligned with the second slider 320, the first mounting hole 101a is directly opposite to the second mounting hole 101b, and the radial dimensions of the first mounting hole 101a and the second mounting hole 101b are also kept completely aligned. When the first sliding member 310 abuts against the rotating member 200 and the second sliding member 320 abuts against the rotating member 200, the first sliding member 310 and the second sliding member 320 are symmetrically distributed with respect to a symmetry plane 200A of the rotating member 200, so that a balance between a first abutting force of the first sliding member 310 against the rotating member 200 and a second abutting force of the second sliding member 320 against the rotating member 200 can be ensured, a gap between the rotating member 200 and the device body 100 can be ensured, on one hand, friction force between the rotating member 200 and the device body 100 is reduced, and therefore, movement of the rotating member 200 relative to the device body 100 is smoother, and on the other hand, scratches caused by movement of the rotating member 200 to the device body 100 can be avoided.

With continued reference to fig. 15, the slider 300 includes a first sub-slider 301 and a second sub-slider 302, the apparatus body 100 has a mounting hole 101, and the first sub-slider 301 and the second sub-slider 302 are accommodated in the mounting hole 101.

Specifically, the mounting hole 101 is formed in the front surface 102 or the back surface 103 of the device body 100, the side surface 104 of the device body 100 has a receiving groove 100A, and the first sub-slider 301 and the second sub-slider 302 are stacked along the extending direction of the mounting hole 101. When the rotating member 200 is received in the receiving groove 100A of the apparatus body 100, the opening of the mounting hole 101 abuts against the inner wall of the apparatus body 100, so that the mounting hole 101 can be waterproof and dustproof.

In one embodiment, the first sub-slider 301 and the second sub-slider 302 are in direct contact, and at least one of the first sub-slider 301 and the second sub-slider 302 abuts against the rotating member 200.

Specifically, the first sub-slider 301 is in direct contact with the second sub-slider 302. That is, there is a relative sliding between the first sub-slider 301 and the second sub-slider 302, and at least one of the first sub-slider 301 and the second sub-slider 302 abuts against the rotating member 200. The first sub-slider 301 is directly abutted against the second sub-slider 302, and the first sub-slider 301 and the second sub-slider 302 can slide relatively, so that the relative movement between the first sub-slider 301 and the second sub-slider 302 is smoother. When the structural shapes of the first sub-slider 301 and the second sub-slider 302 are consistent, the first sub-slider 301 and the second sub-slider 302 have the same mechanical properties, and the first sub-slider 301 and the second sub-slider 302 are abutted against each other, so that the abutting force between the first sub-slider 301 and the second sub-slider 302 is more uniform, the first sub-slider 301 and the second sub-slider 302 are symmetrically distributed along one symmetry plane 200A of the rotating member 200, and the situation that the rotating member 200 generates a certain offset due to uneven stress between the first sub-slider 301 and the second sub-slider 302, which may cause jamming, is avoided. And at least one of the first sub-sliding piece 301 and the second sub-sliding piece 302 is propped against the rotating piece 200, so that a gap can be kept between the rotating piece 200 and the equipment body 100, friction force between the rotating piece 200 and the equipment body 100 is reduced, on one hand, scratch on the equipment body 100 caused by rotation of the rotating piece 200 can be avoided, and on the other hand, the situation that the rotating piece 200 is clamped can be avoided.

With continued reference to fig. 16, in another embodiment, a spacer 550 is disposed between the first sub-slider 301 and the second sub-slider 302, and the spacer 550 is used to form a separation between the first sub-slider 301 and the second sub-slider 302.

Wherein the spacer 550 is spaced apart from the rotator 200. That is, the spacer 550 does not interfere with the movement of the rotary member 200, and it is possible to ensure smoother movement of the rotary member 200 with respect to the apparatus body 100. Providing the spacer 550 between the first sub-slider 301 and the second sub-slider 302 can avoid mutual interference of the first slider 310 and the second slider 320 due to inconsistent movement directions. Given that the first sliding member 310 and the second sliding member 320 move in an unsynchronized manner, they will interfere with each other, which may cause uneven stress between the first sliding member 310 and the second sliding member 320, and when such uneven stress is transferred to the rotating member 200, the rotating member 200 will shift, so that a gap between the rotating member 200 and the device body 100 cannot be ensured, and at this time, the rotating member 200 is at risk of seizing, and normal application functions of the electronic device 10 cannot be ensured.

With continued reference to fig. 17, the slider 300 further includes a third sub-slider 303, the third sub-slider 303 is received in the mounting hole 101, and the first sub-slider 301 and the second sub-slider 302 are both abutted against the third sub-slider 303.

Specifically, the first sub-slider 301 directly abuts against the third sub-slider 303, and the second sub-slider 302 directly abuts against the third sub-slider 303. That is, there is a relative sliding motion between the first sub-slider 301 and the third sub-slider 303, there is a relative sliding motion between the second sub-slider 302 and the third sub-slider 303, and the first sub-slider 301 and the second sub-slider 302 are abutted against the rotating member 200 together. The first sub-slider 301 is directly abutted against the third sub-slider 303, and the first sub-slider 301 and the third sub-slider 303 can slide relatively, and the second sub-slider 302 is directly abutted against the third sub-slider 303, and the second sub-slider 302 and the third sub-slider 303 can slide relatively, so that the relative movement between the first sub-slider 301 and the third sub-slider 303 and the relative movement between the second sub-slider 302 and the third sub-slider 303 can be smoother. When the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 have the same structure, since the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 have the same mechanical properties, the first sub-slider 301 and the third sub-slider 303 abut against each other, and the second sub-slider 302 and the third sub-slider 303 abut against each other, the abutting force between the first sub-slider 301 and the third sub-slider 303 and the abutting force between the second sub-slider 302 and the third sub-slider 303 are more uniform, and the first sub-slider 301 and the second sub-slider 302 are symmetrically distributed along one symmetry plane 200A of the rotating member 200, so that a certain offset is generated between the first sub-slider 301 and the second sub-slider 302 due to uneven stress, and thus, the situation of seizing may be caused. And the first sub-sliding piece 301 and the second sub-sliding piece 302 are propped against the rotating piece 200 together, so that the stress balance of the rotating piece 200 can be better ensured, a gap can be kept between the rotating piece 200 and the equipment body 100, friction force between the rotating piece 200 and the equipment body 100 is reduced, on one hand, scratch on the equipment body 100 caused by rotation of the rotating piece 200 can be avoided, and on the other hand, the situation that the rotating piece 200 is clamped can be avoided.

With continued reference to fig. 18, the third sub-slider 303 is located between the first sub-slider 301 and the second sub-slider 302, and the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 are stacked along the extending direction of the mounting hole 101.

Specifically, the first sub-slider 301 abuts against the third sub-slider 303, the second sub-slider 302 abuts against the third sub-slider 303, and the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 all abut against the rotating member 200. The first sub-slider 301 abuts against the second sub-slider 302 on the one hand, and also abuts against the rotating member 200 on the other hand. The second sub-slider 302 abuts against the second sub-slider 302 on the one hand, and also abuts against the rotating member 200 on the other hand. The third sub-slider 303 is simultaneously abutted against the first sub-slider 301, the second sub-slider 302 and the rotator 200. Through the first sub-sliding piece 301, the second sub-sliding piece 302 and the third sub-sliding piece 303 all prop against the rotating piece 200, a gap can be kept between the rotating piece 200 and the equipment body 100, so that direct contact between the rotating piece 200 and the equipment body 100 is avoided, scratch of the rotating piece 200 to the equipment body 100 can be avoided, friction force between the rotating piece 200 and the equipment body 100 can be reduced, and smooth rotation process of the rotating piece 200 propping against the equipment body 100 is ensured.

Further, in an embodiment, the extending direction of the mounting hole 101 is an arc track, that is, the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 are arranged along the arc track, so that the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 are simultaneously abutted against the rotating member 200, and as the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 can provide the rotating member 200 with a plurality of holding forces, when the holding forces in the plurality of directions are balanced, the rotating member 200 can be kept in balanced stress, which is helpful to ensure a gap between the rotating member 200 and the device body 100, thereby avoiding direct contact between the rotating member 200 and the device body 100, avoiding scratches on the device body 100 caused by the rotating member 200, reducing friction between the rotating member 200 and the device body 100, and ensuring a smooth rotation process of the rotating member 200 against the device body 100. And because the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 are arranged along the arc track, the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 can be better attached to the surface of the rotating member 200, so as to provide a supporting force for the rotating member 200, and ensure that the movement of the rotating member 200 is smoother.

With continued reference to fig. 19, the first sub-slider 301 and the second sub-slider 302 are stacked along the extending direction of the mounting hole 101, the third sub-slider 303 is located on a side of the first sub-slider 301 away from the rotating member 200, and the third sub-slider 303 is simultaneously abutted against the first sub-slider 301 and the second sub-slider 302.

Specifically, in the present embodiment, the third sub-slider 303 is disposed at a distance from the rotating member 200, the third sub-slider 303 is abutted against the rotating member 200 through the first sub-slider 301 and the second sub-slider 302, and the first sub-slider 301 slides relative to the second sub-slider 302 through the third sub-slider 303. The third sub-slider 303 provides a holding force to the first sub-slider 301 and the second sub-slider 302 respectively, then the holding force from the third sub-slider 303 is transmitted to the rotating member 200 by the first sub-slider 301 and the second sub-slider 302, and by controlling the position of the third sub-slider 303 relative to the first sub-slider 301 and the second sub-slider 302, the holding force direction of the third sub-slider 303 to the first sub-slider 301 and the second sub-slider 302 can be changed, so that the force balance of the rotating member 200 is ensured, so that a gap is kept between the rotating member 200 and the device body 100, and the scratch of the device body 100 caused by the movement of the rotating member 200 is avoided. And the situation that the rotating member 200 is jammed can be avoided, so that the rotating member 200 rotates smoothly relative to the device body 100.

With continued reference to fig. 20, the mounting hole 101 is formed by a first limiting hole 111 and a second limiting hole 112 that are connected, the second limiting hole 112 is disposed away from the rotating member 200 relative to the first limiting hole 111, the first sub-slider 301 and the second sub-slider 302 are located in the first limiting hole 111, and the third sub-slider 303 is received in the second limiting hole 112.

Wherein, the depth of the second limiting hole 112 is smaller than that of the first limiting hole 111. The first limiting hole 111 is used for accommodating the first sub-slider 301 and the second sub-slider 302, the second limiting hole 112 is used for accommodating the third sub-slider 303, and the third sub-slider 303 is located between the first sub-slider 301 and the second sub-slider 302 and is far away from one side of the rotating member 200. Limiting the third sub-slider 303 is achieved by the second limiting hole 112, the first sub-slider 301 and the second sub-slider 302.

Further, the sliding member 300 is a ball, and the volumes of the first sub-sliding member 301, the second sub-sliding member 302, and the third sub-sliding member 303 are kept identical.

Specifically, the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 are completely identical. When the first sub-slider 301 abuts against the rotating member 200, the second sub-slider 302 abuts against the rotating member 200, and the third sub-slider 303 abuts against both the first sub-slider 301 and the second sub-slider 302, the first sub-slider 301 and the second sub-slider 302 are symmetrically distributed with respect to one symmetry plane 200A of the rotating member 200, and the third sub-slider 303 is symmetrical with respect to one symmetry plane 200A of the rotating member 200, at this time, it is ensured that the first abutting force of the first sub-slider 301 against the rotating member 200 and the second abutting force of the second sub-slider 302 against the rotating member 200 are balanced, so that a gap between the rotating member 200 and the apparatus body 100 can be ensured, on one hand, the friction force between the rotating member 200 and the apparatus body 100 is reduced, so that the movement of the rotating member 200 relative to the apparatus body 100 is smoother, and on the other hand, scratches caused by the movement of the rotating member 200 to the apparatus body 100 can be avoided. In addition, the relative sliding among the first sub-sliding member 301, the second sub-sliding member 302 and the third sub-sliding member 303 can be smoother, so that the movement of the rotating member 200 relative to the apparatus body 100 is smoother.

With continued reference to fig. 21, a spring 600 is disposed between the rotating member 200 and the device body 100, and when the rotating member 200 rotates relative to the device body 100, the spring 600 is used for limiting the movement of the rotating member 200.

In one embodiment, the elastic sheet 600 is fixed on the rotating member 200, and the elastic sheet 600 is used for providing a holding force to the device body 100, so as to prevent the device body 100 from approaching the rotating member 200, so that a gap is formed between the rotating member 200 and the device body 100. On the one hand, the situation that the rotating member 200 is blocked can be avoided, the rotating member 200 is ensured to move relatively smoothly relative to the device body 100, on the other hand, when the elastic sheet 600 is propped against the device body 100, the device body 100 can have a reaction force to the elastic sheet 600, and the reaction force can be transmitted to the rotating member 200, that is, the device body 100 has a propping force to the rotating member 200, so that unnecessary shaking of the rotating member 200 can be avoided, and the rotating member 200 can rotate relatively smoothly relative to the device body 100.

In another embodiment, the elastic piece 600 is fixed on the device body 100, and the elastic piece 600 is used for providing a supporting force for the rotating piece 200, so as to prevent the rotating piece 200 from approaching the device body 100, so that a gap is formed between the rotating piece 200 and the device body 100. On the one hand, the situation that the rotating member 200 is blocked can be avoided, the rotating member 200 is ensured to move relatively smoothly relative to the device body 100, on the other hand, when the elastic sheet 600 abuts against the rotating member 200, the rotating member 200 has a reaction force to the elastic sheet 600, and the reaction force is transmitted to the device body 100, that is, the rotating member 200 has an abutting force to the device body 100, so that a gap between the device body 100 and the rotating member 200 can be ensured, and the rotating member 200 can rotate relatively smoothly relative to the device body 100.

With continued reference to fig. 22, the electronic device 10 further includes a driving assembly 610, where the driving assembly 610 includes a driving mechanism 620 and a pushing assembly 630, the driving mechanism 620 is fixedly connected to the device body 100, the pushing assembly 630 is movably connected to the second end 202, and the driving mechanism 620 is used for controlling the pushing assembly 630 to move, so that the second end 202 swings relative to the first end 201 to extend or retract the accommodating groove 100A.

The pushing assembly 630 includes a pushing member 631 and an elastic member 632, one end of the pushing member 631 is movably connected to the rotating member 200, the other end of the pushing member 631 can slide relative to the driving mechanism 620, the elastic member 632 is sleeved on the pushing member 631, one end of the elastic member 632 is fixedly connected to the pushing member 631, the other end of the elastic member 632 is fixedly connected to the driving mechanism 620, and the driving mechanism 620 is used for controlling the elastic member 632 to move to drive the rotating member 623 to swing so as to extend or retract the rotating member 200 from or into the accommodating groove 100A.

With continued reference to fig. 23, the driving mechanism 620 includes a casing 621, a driving motor 622, a rotating member 623, and a sliding member 624, where the casing 621 is fixedly connected to the apparatus body 100, the driving motor 622 is fixedly connected to the casing 621, the rotating member 623 is rotatably connected to the casing 621, the driving motor 622 is used for controlling the rotating member 623 to rotate, one end of the sliding member 624 is sleeved on the rotating member 623, and the other end of the sliding member 624 is connected to the elastic member 632; when the driving motor 622 controls the rotation of the rotating member 623 to move the sliding member 624, the elastic member 632 moves in a direction approaching or separating from the rotating member 623.

The driving mechanism 620 further includes a guiding element 625, the guiding element 625 is fixedly connected to the box 621, the sliding element 624 is sleeved on the guiding element 625, the guiding element 625 is used for assisting the sliding element 624 to move, the sliding element 624, the guiding element 625 and the driving motor 622 are arranged side by side, and the guiding element 625 and the rotating element 623 together form a sliding track of the sliding element 624.

The driving mechanism 620 further includes a transmission member 626, the case 621 includes a case body 6211 and a case extension portion 6212 extending from one side of the case body 6211, the case body 6211 is used for fixing the driving motor 622 and for accommodating the transmission member 626, the case extension portion 6212 encloses an accommodating space 6212A, the accommodating space 6212A is used for accommodating the rotation member 623 and the sliding member 624, and the rotation member 623 is rotatably connected to the case extension portion 6212; when the power output from the driving motor 622 is transmitted to the rotating member 623 through the transmission member 626, the rotating member 623 can rotate around its central axis relative to the housing extension 6212, so as to drive the sliding member 624 to slide relative to the housing extension 6212.

The box extension portion 6212 includes a fixing portion 6212a and a connecting portion 6212b, where the fixing portion 6212a is fixedly connected with the box body 6211, the connecting portion 6212b is connected to the fixing portion 6212a and located at a side of the fixing portion 6212a away from the box body 6211, the fixing portion 6212a and the rotating member 623 are arranged side by side, and the sliding member 624 is connected between the connecting portion 6212b and the box body 6211.

The driving motor 622 is located at a side of the fixing portion 6212a away from the connecting portion 6212b, the driving motor 622 and the rotating member 623 are disposed side by side, and the driving motor 622, the rotating member 623 and the sliding member 624 are located at the same side of the case body 6211.

With continued reference to fig. 24, the apparatus body 100 has an accommodating space 100D, the accommodating space 100D is communicated with the accommodating groove 100A through a first through hole 100D, the accommodating space 100D is used for completely accommodating the driving mechanism 620 and partially accommodating the pushing assembly 630, the pushing member 631 may extend or retract from the accommodating space 100D through the first through hole 100D, the elastic member 632 and the outer side of the pushing member 631 are provided with a sealing sleeve 640, the outer side of the sealing sleeve 640 is provided with a sealing ring 650, the sealing ring 650 is fixed on the apparatus body 100 and accommodated in the first through hole 100D, and the sealing sleeve 640 and the sealing ring 650 are jointly used for sealing the pushing assembly 630.

With continued reference to fig. 25, the electronic device 10 includes a rotating member 200 and a device body 100, wherein one end of the rotating member 200 is rotatably connected with the device body 100, a sliding member 300 is mounted on the device body 100, the sliding member 300 can rotate relative to the rotating member 200, and the sliding member 300 is configured to provide a holding force F for the rotating member 200, so that the other end of the rotating member 200 rotates along a preset track relative to the device body 100.

The number of the sliding members 300 may be one or more. The sliding member 300 may be a ball, a roller, or other sliding structures. The sliding member 300 is located on the apparatus body 100 and can slide relative to the rotating member 200, the sliding member 300 abuts against the rotating member 200 to provide an abutting force for the rotating member 200, and the auxiliary rotating member 200 rotates along a preset track relative to the apparatus body 100 on the premise of ensuring a gap between the rotating member 200 and the apparatus body 100. When the sliding member 300 is a ball, the ball is in point contact with the rotating member 200, and the surface contact between the rotating member 200 and the apparatus body 100 is small in point contact, so that the friction force is small due to small contact area of friction, so that the rotating member 200 can move more smoothly relative to the apparatus body 100, and further, the situation that the rotating member 200 is jammed can be avoided. Furthermore, since the rotating member 200 is not in direct contact with the apparatus body 100, the apparatus body 100 is prevented from being scratched by the movement of the rotating member 200, and the anode layer of the apparatus body 100 is damaged.

The electronic device 10 provided in the embodiment of the application includes a device body 100 and a rotating member 200 rotatably connected, wherein a sliding member 300 is mounted on the device body 100, the sliding member 300 can slide relative to the rotating member 200, and when the rotating member 200 rotates relative to the device body 100, the sliding member 300 is used for providing a holding force for the rotating member 200, so that the other end of the rotating member 200 rotates along a preset track relative to the device body 100. Through slider 300 support in rotating member 200, can make keeping the clearance between rotating member 200 and the equipment body 100, avoid rotating member 200 and equipment body 100 direct contact to can avoid the motion of rotating member 200 to cause the scratch to equipment body 100, and can reduce the frictional force when rotating member 200 and equipment body 100 relative motion, avoid the condition that rotating member 200 blocked, guarantee that the motion of rotating member 200 is more smooth and easy relative to equipment body 100. And the sliding piece 300 is propped against the rotating piece 200 to slide, so that the rotating piece 200 is prevented from unnecessarily shaking on the premise of ensuring the normal sliding of the rotating piece 200, and the structural arrangement of the electronic equipment 10 is more refined.

With continued reference to fig. 26, the apparatus body 100 has a mounting hole 101, the sliding member 300 is received in the mounting hole 101, and a sidewall of the mounting hole 101 is used to provide a circumferential holding force for the sliding member 300.

In one embodiment, the mounting hole 101 has a first mounting hole 101a and a second mounting hole 101b, the first mounting hole 101a is provided with a first slider 310, the second mounting hole 101b is provided with a second slider 320, the rotating member 200 is rotatably connected to the apparatus body 100, the first slider 310 is used for providing a first supporting force for the rotating member 200, the second slider 320 is used for providing a second supporting force for the rotating member 200, and the first supporting force and the second supporting force cooperate with each other to limit the rotating member 200.

Specifically, in the present embodiment, the sliding member 300 includes a first sliding member 310 and a second sliding member 320, where the first sliding member 310 and the second sliding member 320 are abutted against the rotating member 200, so that a gap is maintained between the rotating member 200 and the apparatus body 100, and thus scratches caused by movement of the rotating member 200 on the apparatus body 100 are avoided. The first sliding member 310 and the second sliding member 320 are symmetrically distributed along a symmetry plane 200A of the rotating member 200, and the first sliding member 310 and the second sliding member 320 are propped against the rotating member 200, so that the device body 100 and the rotating member 200 can be prevented from being in direct contact, the friction area is reduced, the friction force can be further reduced, and the rotating member 200 can move relatively smoothly relative to the device body 100. When the first slider 310 and the second slider 320 are balls, the contact between the first slider 310 and the second slider 320 and the rotating member 200 is point contact, so that the friction force during rotation of the rotating member 200 can be reduced to the greatest extent, and thus, the occurrence of seizing can be avoided.

With continued reference to fig. 27, a limiting member 500 is disposed at the opening of the mounting hole 101, and the limiting member 500 is configured to provide a holding force along the extending direction of the mounting hole 101 for the sliding member 300.

In one embodiment, the limiting member 500 includes a first limiting member 510 and a second limiting member 520, where the first limiting member 510 is located at the opening of the first mounting hole 101a and is used for providing a first supporting force along the extending direction of the first mounting hole 101a for the first slider 310, and the second limiting member 520 is located at the opening of the second mounting hole 101b and is used for providing a second supporting force along the extending direction of the second mounting hole 101b for the second slider 320.

Further, a spacer 550 is disposed between the first mounting hole 101a and the second mounting hole 101b, where the spacer 550 is configured to provide a third supporting force for the first slider 310 and provide a fourth supporting force for the second slider 320, the third supporting force is equal to the first supporting force, opposite in direction, and the fourth supporting force is equal to the second supporting force, opposite in direction.

Wherein the spacer 550 is spaced apart from the rotator 200. That is, the spacer 550 does not interfere with the movement of the rotary member 200, and it is possible to ensure smoother movement of the rotary member 200 with respect to the apparatus body 100. The spacer 550 is disposed between the first mounting hole 101a and the second mounting hole 101b, and the first slider 310 is spaced apart in the first mounting hole 101a, and the second slider 320 is spaced apart in the second mounting hole 101b, so that interference between the first slider 310 and the second slider 320 due to inconsistent movement directions can be avoided. Given that the first sliding member 310 and the second sliding member 320 move in an unsynchronized manner, they will interfere with each other, which may cause uneven stress between the first sliding member 310 and the second sliding member 320, and when such uneven stress is transferred to the rotating member 200, the rotating member 200 will shift, so that a gap between the rotating member 200 and the device body 100 cannot be ensured, and at this time, the rotating member 200 is at risk of seizing, and normal application functions of the electronic device 10 cannot be ensured.

In an embodiment, the spacer 550 may be additionally provided, not being a part of the rotating member 200 itself, or not being a part of the apparatus body 100 itself, and the spacer 550 is fixedly mounted on the apparatus body 100 or mounted on the rotating member 200 to form a separation between the first slider 310 and the second slider 320.

In another embodiment, the spacer 550 is a part of the device body 100, and the spacer 550 is formed together when the device body 100 is formed, so that a fixing structure of the spacer 550 is not required to be additionally provided, which is helpful for realizing the light and thin design of the electronic device 10.

In yet another embodiment, the spacer 550 is a part of the rotator 200, and the spacer 550 is formed together when the rotator 200 is formed, so that a fixing structure of the spacer 550 is not required to be additionally provided, which contributes to the light and thin design of the electronic device 10.

In another embodiment, the side wall of the first mounting hole 101a provides a first elastic force to the first slider 310 toward the rotating member 200, and the side wall of the second mounting hole 101b provides a second elastic force to the second slider 320 toward the rotating member 200, the first elastic force forming the first holding force and the second elastic force forming the second holding force.

Further, the portions of the rotating member 200 adjacent to the first mounting hole 101a and the second mounting hole 101b are arc-shaped, and include a first arc-shaped portion 2001 and a second arc-shaped portion 2002 that are connected, the supporting force of the first sliding member 310 on the first arc-shaped portion 2001 is a first elastic force, the direction of the first elastic force points to the bending curvature center of the first arc-shaped portion 2001, the supporting force of the second sliding member 320 on the second arc-shaped portion 2002 is a second elastic force, and the direction of the second elastic force points to the bending curvature center of the second arc-shaped portion 2002.

Specifically, when the abutting portions of the rotating member 200, the first sliding member 310 and the second sliding member 320 are arc-shaped, the stress at the abutting portions is in a divergent distribution, so that the stress of the rotating member 200 at the abutting portions is more uniform, and the problem of stress concentration is avoided. When the first slider 310 is attached to the first arc portion 2001 and slides relative to the first arc portion 2001, and the second slider 320 is attached to the second arc portion 2002 and slides relative to the second arc portion 2002, the movement of the first slider 310 and the second slider 320 can be smoother, so that, on one hand, the rotation of the rotating member 200 relative to the apparatus body 100 is smoother, and on the other hand, because the movement of the first slider 310 and the second slider 320 relative to the rotating member 200 is smoother, the holding force of the first slider 310 and the second slider 320 against the rotating member 200 is also more uniform, thereby avoiding unnecessary offset of the rotating member 200, and facilitating the movement of the rotating member 200 relative to the apparatus body 100.

Further, the bending curvature center of the first arc portion 2001 is located at a side away from the first mounting hole 101a, the bending curvature center of the second arc portion 2002 is located at a side away from the second mounting hole 101b, and the bending curvature radius of the first arc portion 2001 is consistent with the bending curvature radius of the second arc portion 2002.

Specifically, the first arcuate portion 2001 assumes an outwardly arched shape, and the second arcuate portion 2002 also assumes an outwardly arched shape. When the radius of curvature of the first arc portion 2001 is the same as the radius of curvature of the second arc portion 2002, and the volumes of the first slider 310 and the second slider 320 are kept the same, the holding force of the first slider 310 against the first arc portion 2001 and the holding force of the second slider 320 against the second arc portion 2002 are kept the same, at this time, the holding forces of the first slider 310 and the second slider 320 against the rotating member 200 can be kept uniform, so that the rotating member 200 can keep a centered position with respect to the apparatus body 100, so that the gap between the rotating member 200 and the apparatus body 100 can be ensured more easily, and the rotation of the rotating member 200 with respect to the apparatus body 100 can be smoother.

With continued reference to fig. 28, in yet another embodiment, the rotating member 200 has a first groove 1015 and a second groove 1016 spaced apart, and when the rotating member 200 rotates relative to the apparatus body 100, the first sliding member 310 may slide against an inner wall of the first groove 1015, and the second sliding member 320 may slide against an inner wall of the second groove 1016.

Specifically, the first groove 1015 is used for limiting the first sliding member 310, the second groove 1016 is used for limiting the second sliding member 320, and the first groove 1015 and the second groove 1016 are parallel and spaced, so that the direction of the holding force of the first sliding member 310 and the second sliding member 320 on the rotating member 200 is kept unchanged all the time. That is, in the process of rotating the rotating member 200 relative to the apparatus body 100, the magnitude of the holding force of the first sliding member 310 against the rotating member 200 and the holding force of the second sliding member 320 against the rotating member 200 are always uniform, so that the situation that the rotating member 200 is stressed unevenly in the rotating process of the rotating member 200 relative to the apparatus body 100 can be avoided, the gap between the rotating member 200 and the apparatus body 100 is conveniently ensured, the situation that the rotating member 200 is jammed is avoided, and the rotating member 200 can rotate relatively to the apparatus body 100 smoothly.

Further, in one embodiment, the first slider 310 slides against the first groove 1015 and the second slider 320 slides against the second groove 1016. At this time, the first slider 310 is in surface contact with the first groove 1015, and the second slider 320 is also in surface contact with the second groove 1016. In this embodiment, the first slider 310 and the second slider 320 are intentionally in surface contact with the rotating member 200, so that the contact area between the first slider 310 and the first groove 1015 is increased, and the contact area between the second slider 320 and the second groove 1016 is increased, so that the first groove 1015 is more stable in limiting the first slider 310, and the second groove 1016 is more stable in limiting the second slider 320, so that shaking of the rotating member 200 relative to the rotating member 100 in the rotating process of the rotating member 200 can be avoided, and the rotating of the rotating member 200 relative to the rotating member 100 can be more stable.

In other embodiments, the sliding member 300 is a ball, the volumes of the first sliding member 310 and the second sliding member 320 are consistent, and the first supporting force and the second supporting force are equal.

Specifically, the first slider 310 is completely aligned with the second slider 320, the first mounting hole 101a is directly opposite to the second mounting hole 101b, and the radial dimensions of the first mounting hole 101a and the second mounting hole 101b are also kept completely aligned. When the first sliding member 310 abuts against the rotating member 200 and the second sliding member 320 abuts against the rotating member 200, the first sliding member 310 and the second sliding member 320 are symmetrically distributed with respect to a symmetry plane 200A of the rotating member 200, so that a balance between a first abutting force of the first sliding member 310 against the rotating member 200 and a second abutting force of the second sliding member 320 against the rotating member 200 can be ensured, a gap between the rotating member 200 and the device body 100 can be ensured, on one hand, friction force between the rotating member 200 and the device body 100 is reduced, and therefore, movement of the rotating member 200 relative to the device body 100 is smoother, and on the other hand, scratches caused by movement of the rotating member 200 to the device body 100 can be avoided.

With continued reference to fig. 29, the slider 300 includes a first sub-slider 301 and a second sub-slider 302, where the second sub-slider 302 and the first sub-slider 301 are stacked along the extending direction of the mounting hole 101, and the second sub-slider 302 and the first sub-slider 301 together provide a holding force for the rotating member 200.

Specifically, the mounting hole 101 is formed in the front surface 102 or the back surface 103 of the device body 100, the side surface 104 of the device body 100 has a receiving groove 100A, and the first sub-slider 301 and the second sub-slider 302 are stacked along the extending direction of the mounting hole 101. When the rotating member 200 is received in the receiving groove 100A of the apparatus body 100, the opening of the mounting hole 101 abuts against the inner wall of the apparatus body 100, so that the mounting hole 101 can be waterproof and dustproof.

With continued reference to fig. 30, the first sub-slider 301 has a first supporting force F1 in a first direction on the rotating member 200, the second sub-slider 302 has a second supporting force F2 in a second direction on the rotating member 200, and the magnitudes of the components of the first supporting force F1 and the second supporting force F2 in the extending direction of the mounting hole 101 are consistent, and the directions are opposite.

Specifically, the first sub-slider 301 is in direct contact with the second sub-slider 302. That is, there is a relative sliding between the first sub-slider 301 and the second sub-slider 302, and at least one of the first sub-slider 301 and the second sub-slider 302 abuts against the rotating member 200. The first sub-slider 301 is directly abutted against the second sub-slider 302, and the first sub-slider 301 and the second sub-slider 302 can slide relatively, so that the relative movement between the first sub-slider 301 and the second sub-slider 302 is smoother. When the structural shapes of the first sub-slider 301 and the second sub-slider 302 are consistent, the first sub-slider 301 and the second sub-slider 302 have the same mechanical properties, and the first sub-slider 301 and the second sub-slider 302 are abutted against each other, so that the abutting force between the first sub-slider 301 and the second sub-slider 302 is more uniform, the first sub-slider 301 and the second sub-slider 302 are symmetrically distributed along one symmetry plane 200A of the rotating member 200, and the situation that the rotating member 200 generates a certain offset due to uneven stress between the first sub-slider 301 and the second sub-slider 302, which may cause jamming, is avoided. And at least one of the first sub-sliding piece 301 and the second sub-sliding piece 302 is propped against the rotating piece 200, so that a gap can be kept between the rotating piece 200 and the equipment body 100, friction force between the rotating piece 200 and the equipment body 100 is reduced, on one hand, scratch on the equipment body 100 caused by rotation of the rotating piece 200 can be avoided, and on the other hand, the situation that the rotating piece 200 is clamped can be avoided.

With continued reference to fig. 31, the slider 300 further includes a third sub-slider 303, where the third sub-slider 303 is located between the first sub-slider 301 and the second sub-slider 302, and the first sub-slider 301, the second sub-slider 302, and the third sub-slider 303 together provide a holding force for the rotating member 200.

Specifically, the first sub-slider 301 directly abuts against the third sub-slider 303, and the second sub-slider 302 directly abuts against the third sub-slider 303. That is, there is a relative sliding motion between the first sub-slider 301 and the third sub-slider 303, there is a relative sliding motion between the second sub-slider 302 and the third sub-slider 303, and the first sub-slider 301 and the second sub-slider 302 are abutted against the rotating member 200 together. The first sub-slider 301 is directly abutted against the third sub-slider 303, and the first sub-slider 301 and the third sub-slider 303 can slide relatively, and the second sub-slider 302 is directly abutted against the third sub-slider 303, and the second sub-slider 302 and the third sub-slider 303 can slide relatively, so that the relative movement between the first sub-slider 301 and the third sub-slider 303 and the relative movement between the second sub-slider 302 and the third sub-slider 303 can be smoother. When the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 have the same structure, since the first sub-slider 301, the second sub-slider 302 and the third sub-slider 303 have the same mechanical properties, the first sub-slider 301 and the third sub-slider 303 abut against each other, and the second sub-slider 302 and the third sub-slider 303 abut against each other, the abutting force between the first sub-slider 301 and the third sub-slider 303 and the abutting force between the second sub-slider 302 and the third sub-slider 303 are more uniform, and the first sub-slider 301 and the second sub-slider 302 are symmetrically distributed along one symmetry plane 200A of the rotating member 200, so that a certain offset is generated between the first sub-slider 301 and the second sub-slider 302 due to uneven stress, and thus, the situation of seizing may be caused. And the first sub-sliding piece 301 and the second sub-sliding piece 302 are propped against the rotating piece 200 together, so that the stress balance of the rotating piece 200 can be better ensured, a gap can be kept between the rotating piece 200 and the equipment body 100, friction force between the rotating piece 200 and the equipment body 100 is reduced, on one hand, scratch on the equipment body 100 caused by rotation of the rotating piece 200 can be avoided, and on the other hand, the situation that the rotating piece 200 is clamped can be avoided.

With continued reference to fig. 32, the mounting hole 101 is formed by a first limiting hole 111 and a second limiting hole 112, which are connected, the second limiting hole 112 is disposed away from the rotating member 200 relative to the first limiting hole 111, the first limiting hole 111 is used for providing a circumferential holding force to the first sub-slider 301 and the second sub-slider 302, and the second limiting hole 112 is used for providing a circumferential holding force to the third sub-slider 303.

Wherein, the depth of the second limiting hole 112 is smaller than that of the first limiting hole 111. The first limiting hole 111 is used for accommodating the first sub-slider 301 and the second sub-slider 302, the second limiting hole 112 is used for accommodating the third sub-slider 303, and the third sub-slider 303 is located between the first sub-slider 301 and the second sub-slider 302 and is far away from one side of the rotating member 200. Limiting the third sub-slider 303 is achieved by the second limiting hole 112, the first sub-slider 301 and the second sub-slider 302.

Specifically, in the present embodiment, the third sub-slider 303 is disposed at a distance from the rotating member 200, the third sub-slider 303 is abutted against the rotating member 200 through the first sub-slider 301 and the second sub-slider 302, and the first sub-slider 301 slides relative to the second sub-slider 302 through the third sub-slider 303. The third sub-slider 303 provides a holding force to the first sub-slider 301 and the second sub-slider 302 respectively, then the holding force from the third sub-slider 303 is transmitted to the rotating member 200 by the first sub-slider 301 and the second sub-slider 302, and by controlling the position of the third sub-slider 303 relative to the first sub-slider 301 and the second sub-slider 302, the holding force direction of the third sub-slider 303 to the first sub-slider 301 and the second sub-slider 302 can be changed, so that the force balance of the rotating member 200 is ensured, so that a gap is kept between the rotating member 200 and the device body 100, and the scratch of the device body 100 caused by the movement of the rotating member 200 is avoided. And the situation that the rotating member 200 is jammed can be avoided, so that the rotating member 200 rotates smoothly relative to the device body 100.

With continued reference to fig. 33, a spring 600 is disposed between the rotating member 200 and the apparatus body 100, and the spring 600 is configured to provide a holding force for the rotating member 200 when the rotating member 200 rotates relative to the apparatus body 100.

In one embodiment, the elastic sheet 600 is fixed on the rotating member 200, and the elastic sheet 600 is used for providing a holding force to the device body 100, so as to prevent the device body 100 from approaching the rotating member 200, so that a gap is formed between the rotating member 200 and the device body 100. On the one hand, the situation that the rotating member 200 is blocked can be avoided, the rotating member 200 is ensured to move relatively smoothly relative to the device body 100, on the other hand, when the elastic sheet 600 is propped against the device body 100, the device body 100 can have a reaction force to the elastic sheet 600, and the reaction force can be transmitted to the rotating member 200, that is, the device body 100 has a propping force to the rotating member 200, so that unnecessary shaking of the rotating member 200 can be avoided, and the rotating member 200 can rotate relatively smoothly relative to the device body 100.

The foregoing has outlined rather broadly the more detailed description of embodiments of the application, wherein the principles and embodiments of the application are explained in detail using specific examples, the above examples being provided solely to facilitate the understanding of the method and core concepts of the application; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present application, the present description should not be construed as limiting the present application in view of the above.

Claims (19)

1. The electronic equipment is characterized by comprising an equipment body and a rotating piece, wherein the equipment body comprises a display screen, the equipment body is provided with an accommodating groove, the rotating piece is at least partially accommodated in the accommodating groove and can rotate relative to the equipment body, a functional component is arranged on the rotating piece, the rotating piece comprises a first state completely accommodated in the accommodating groove and a second state partially accommodated in the accommodating groove, when the rotating piece is in the first state, the orthographic projection of the rotating piece on the equipment body falls in the outline of the equipment body, and the functional component is shielded by the display screen; when the rotating piece is in a second state, the rotating piece extends out of the outline of the equipment body at the front projection part of the equipment body, and the functional component is exposed out of the display screen; the device comprises a device body and is characterized in that the device body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding piece, the second mounting hole is provided with a second sliding piece, when the rotating piece rotates relative to the device body, the first sliding piece and the second sliding piece respectively support against the rotating piece, the first sliding piece directly supports against the second sliding piece, relative sliding is arranged between the first sliding piece and the second sliding piece, and the first sliding piece and the second sliding piece are symmetrically distributed along one symmetry plane of the rotating piece.

2. The electronic device of claim 1, further comprising a first limiting member and a second limiting member, wherein the first limiting member is fixed at the opening of the first mounting hole and abuts against the first sliding member, and the second limiting member is fixed at the opening of the second mounting hole and abuts against the second sliding member.

3. The electronic device of claim 2, wherein the first mounting hole includes a first hole and a second hole that are in communication and are disposed opposite, the first hole being disposed adjacent to the second mounting hole relative to the second hole, a radial dimension of the first hole being smaller than a radial dimension of the second hole, the first hole being configured to receive the first slider, and the second hole being configured to mount the first limiter.

4. The electronic device of claim 1, wherein the first mounting hole communicates with the second mounting hole, and the first slider abuts against the second slider.

5. The electronic device of claim 1, wherein a spacer is disposed between the first mounting hole and the second mounting hole, the spacer isolating the first slider within the first mounting hole and the second slider within the second mounting hole.

6. The electronic device of claim 5, wherein the spacer is spaced apart from the rotating member.

7. The electronic device of claim 1, wherein the portion of the rotating member adjacent to the first mounting hole and the second mounting hole is arc-shaped and includes a first arc-shaped portion and a second arc-shaped portion that are connected, wherein the first sliding member is attached to the first arc-shaped portion, and wherein the second sliding member is attached to the second arc-shaped portion.

8. The electronic device of claim 7, wherein the first arcuate portion has a first slide slot and the second arcuate portion has a second slide slot, the first slide being slidable within the first slide slot and the second slide being slidable within the second slide slot when the rotating member rotates relative to the device body.

9. The electronic device of claim 7, wherein a center of curvature of the first arcuate portion is located on a side facing away from the first mounting hole, a center of curvature of the second arcuate portion is located on a side facing away from the second mounting hole, and a radius of curvature of the first arcuate portion is consistent with a radius of curvature of the second arcuate portion.

10. The electronic device of any of claims 1-9, wherein the first slider and the second slider are balls, the first slider and the second slider are sized to be uniform, the first mounting hole is aligned with the second mounting hole, and the radial dimensions of the first mounting hole and the second mounting hole are sized to be uniform.

11. The electronic device of any one of claims 1-9, wherein a spring is disposed between the rotating member and the device body, the spring being configured to limit movement of the rotating member when the rotating member rotates relative to the device body.

12. The electronic equipment is characterized by comprising an equipment body and a rotating piece, wherein the equipment body comprises a display screen, the equipment body is provided with an accommodating groove, the rotating piece is at least partially accommodated in the accommodating groove and can rotate relative to the equipment body, a functional component is arranged on the rotating piece, the rotating piece comprises a first state completely accommodated in the accommodating groove and a second state partially accommodated in the accommodating groove, when the rotating piece is in the first state, the orthographic projection of the rotating piece on the equipment body falls in the outline of the equipment body, and the functional component is shielded by the display screen; when the rotating piece is in a second state, the rotating piece extends out of the outline of the equipment body at the front projection part of the equipment body, and the functional component is exposed out of the display screen; the device comprises a device body, a rotating part, a first sliding part, a second sliding part, a first supporting force and a second supporting force, wherein the device body is provided with a first mounting hole and a second mounting hole, the first mounting hole is provided with a first sliding part, the second mounting hole is provided with a second sliding part, the rotating part is rotationally connected to the device body, the first sliding part is used for providing a first supporting force for the rotating part, the second sliding part is used for providing a second supporting force for the rotating part, the first supporting force and the second supporting force are mutually matched to limit the rotating part, the first sliding part is directly supported on the second sliding part, relative sliding is arranged between the first sliding part and the second sliding part, and the first sliding part and the second sliding part are symmetrically distributed along one symmetrical plane of the rotating part.

13. The electronic device of claim 12, further comprising a first stop member positioned at the opening of the first mounting hole for providing a first supporting force to the first slider in the direction of extension of the first mounting hole and a second stop member positioned at the opening of the second mounting hole for providing a second supporting force to the second slider in the direction of extension of the second mounting hole.

14. The electronic device of claim 13, wherein a spacer is disposed between the first mounting hole and the second mounting hole, the spacer is configured to provide a third supporting force to the first slider and to provide a fourth supporting force to the second slider, the third supporting force is equal in magnitude and opposite in direction to the first supporting force, and the fourth supporting force is equal in magnitude and opposite in direction to the second supporting force.

15. The electronic device of claim 12, wherein a sidewall of the first mounting hole provides a first spring force to the first slider toward the rotating member, and a sidewall of the second mounting hole provides a second spring force to the second slider toward the rotating member, the first spring force forming the first holding force and the second spring force forming the second holding force.

16. The electronic device of claim 15, wherein the portion of the rotating member adjacent to the first mounting hole and the second mounting hole is arc-shaped and includes a first arc-shaped portion and a second arc-shaped portion that are connected, wherein a supporting force of the first sliding member on the first arc-shaped portion is a first elastic force, a direction of the first elastic force is directed toward a bending curvature center of the first arc-shaped portion, a supporting force of the second sliding member on the second arc-shaped portion is a second elastic force, and a direction of the second elastic force is directed toward the bending curvature center of the second arc-shaped portion.

17. The electronic device of claim 12, wherein the rotating member has a first groove and a second groove disposed at intervals, the first sliding member being slidable against an inner wall of the first groove and the second sliding member being slidable against an inner wall of the second groove when the rotating member rotates relative to the device body.

18. The electronic device of claim 12, wherein the first slider and the second slider are balls, the first slider and the second slider are kept identical in volume, and the first holding force and the second holding force are equal in magnitude.

19. The electronic device of any one of claims 12-18, wherein a spring is disposed between the rotating member and the device body, the spring being configured to provide a holding force for the rotating member when the rotating member rotates relative to the device body.