CN111294430A - Electronic device and control method of electronic device - Google Patents

Abstract

The embodiment of the application provides electronic equipment and a control method of the electronic equipment. The electronic equipment comprises an equipment body and a rotating piece, wherein the equipment body is provided with an accommodating groove; the rotating part comprises a first end and a second end which are arranged relatively, the first end is connected with the rotating part through a rotating shaft, a functional assembly is located at the second end of the rotating part, the first end is wound on the rotating shaft, so that the functional assembly is rotated into or out of the accommodating groove, a limiting mechanism is arranged between the rotating part and the equipment body, the limiting mechanism comprises a first sliding groove and a limiting part, the limiting part can slide in the first sliding groove, and therefore the second end rotates along a set track to limit the rotating part. The functional assembly is arranged on the rotating piece, so that the electronic equipment can realize various functions.

Description

Electronic device and control method of electronic device

Technical Field

The present disclosure relates to the field of electronic technologies, and in particular, to an electronic device and a control method of the electronic device.

Background

In order to realize various functions of the existing electronic equipment, more and more functional devices are installed in the electronic equipment, and how to design more and more functional devices in the limited space of the electronic equipment is a challenge at present.

Disclosure of Invention

The application provides an electronic device, the electronic device includes:

the equipment body is provided with an accommodating groove;

rotate the piece, it includes relative first end and the second end that sets up to rotate the piece, first end will through a pivot rotate the piece with the equipment body rotates to be connected, a functional unit is located the second end of rotating the piece, first end is rich the pivot is rotated so that functional unit changes over to or roll out the accepting groove, the equipment body with be provided with stop gear between the rotation piece, stop gear includes first spout and locating part, the locating part can slide in the first spout, so that the second end is rotated in order to right along setting for the orbit rotate to rotate and carry on spacingly.

The electronic equipment comprises an equipment body and a rotating piece, wherein the equipment body is provided with an accommodating groove;

the rotating part comprises a first end and a second end which are arranged relatively, the first end is connected with the rotating part through a rotating shaft, the rotating part is connected with the equipment body in a rotating mode, a functional assembly is located at the second end of the rotating part, the first end is wound around the rotating shaft, so that the functional assembly is rotated to or out of the accommodating groove, a limiting mechanism is arranged between the equipment body and the rotating part, the limiting mechanism comprises a first sliding groove and a limiting part, the limiting part can slide in the first sliding groove, so that the second end rotates along a set track to limit the rotating part, the functional assembly is installed on the rotating part, the rotating part can extend out or retract the accommodating groove of the equipment body, and various functions of the electronic equipment can be achieved.

The present application further provides an electronic device, the electronic device including:

the equipment body is provided with an accommodating groove;

the rotating piece is rotatably connected with the equipment body;

a sensor for detecting a drop signal of the electronic device;

and the processor controls the rotating piece to rotate into the accommodating groove when the sensor detects a falling signal of the electronic equipment.

The application also provides a control method of an electronic device, the electronic device comprises a device body and a functional component located inside the device body, and the method comprises the following steps:

the electronic equipment acquires an input signal;

in response to the input signal, the functional component is rotated out of the apparatus body from the inside thereof to perform a function corresponding to the functional component.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings needed to be used 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 it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

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

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

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 provided in an embodiment of the present application.

Fig. 5 is a schematic structural diagram of a third electronic device provided in the embodiment of the present application.

Fig. 6 is a schematic structural diagram of a fourth electronic device provided in the 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 provided in 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 driving mechanism in an electronic device according to a preferred embodiment of the present application.

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

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

Fig. 18 is a schematic structural diagram of a fifteenth electronic device provided in the embodiment of the present application.

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

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

Fig. 21 is a schematic structural diagram of an eighteenth electronic device provided in the embodiment of the present application.

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

Fig. 23 is a schematic structural diagram of a twentieth electronic device according to an 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 provided in the 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 illustrating a structure of the rotating member retracting into the accommodating slot in the twenty-fifth electronic device according to the embodiment of the application.

Fig. 29 is a schematic structural view illustrating a rotating member of a twenty-fifth electronic device extending out of a receiving slot according to an embodiment of the present application.

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

Fig. 31 is a flowchart of a control method of an electronic device according to a preferred embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive effort based on the embodiments in the present application are within the scope of protection 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 has an accommodating slot 100a, the rotating member 200 is at least partially accommodated in the accommodating slot 100a, the rotating member 200 includes a first end 210 and a second end 220 that are oppositely disposed, the first end 210 is rotatably connected to the device body 100 along an arc-shaped track S through a first sliding slot 310, when the first end 210 rotates relative to the device body 100, the second end 220 can extend out of or retract into the accommodating slot 100a, a limiting mechanism 1000 is disposed between the device body 100 and the rotating member 200, the limiting mechanism 1000 includes a first sliding slot 310 and a limiting member 1200, and the limiting member 1200 can slide in the first sliding slot 310, so that the second end 220 rotates along a set track.

The electronic device 10 may be any device having communication and storage functions. For example: the system comprises intelligent equipment with a network function, such as a tablet Computer, a mobile phone, an electronic reader, a remote controller, a Personal Computer (PC), a notebook Computer, vehicle-mounted equipment, a network television, wearable equipment and the like.

The device body 100 includes a battery cover 101, a display screen 102, and a middle frame 103. In one embodiment, the battery cover 101 is fixed to the middle frame 103, and the display screen 102 is fixed to the middle frame 103, and the middle frame 103 forms the receiving groove 100 a. In another embodiment, the middle frame 103 is accommodated in the battery cover 101, the display screen 102 is fixed to the battery cover 101, and the frame opening of the battery cover 101 forms the accommodating groove 100 a.

The functional component 3000 is located at the second end 220 of the rotating member 200, and the first end 210 rotates around the rotating shaft T to rotate the functional component 3000 into or out of the accommodating slot 100 a.

The functional component 3000 can be a camera module, a flash lamp module, a proximity light sensor module and a structured light sensor module.

The first end 210 is adjacent to one side of the equipment body 100 to form an avoidance space a1, the avoidance space a1 is located at the outer surface of the equipment body 100 facing the inside of the equipment body 100, and the avoidance space a1 is used for avoiding components arranged in the equipment body 100. Since the escape space a1 is located inside the main body 100, the tool raising portion of the tool does not lie on the outer surface of the main body 100 during machining, and sharp corners do not remain on the outer surface of the main body 100, which can enhance the structural strength of the main body 100 and improve the appearance uniformity of the electronic device.

One side of the apparatus body 100 adjacent to the rotation member 200 has an avoiding groove a2, and the avoiding groove a2 is used for avoiding a partial structure of the rotation member 200 so as to avoid interference with the rotation process of the rotation member 200. Offer and dodge groove A2 on one side that the equipment body 100 is close to rotating piece 200, can hold the partial structure who rotates piece 200, dodge the shape of groove A2 promptly and rotate the partial structure shape of piece 200 the same to can save the space of arranging of components and parts in the electronic equipment, make the arrangement of components and parts in the electronic equipment compacter. In addition, the rotating member 200 can be pushed out of the accommodating groove 100a of the apparatus body 100 by a smaller pushing stroke, which contributes to saving power consumption.

The rotating member 200 includes a first state of being completely received in the receiving groove 100a and a second state of being partially received in the receiving groove 100 a. When the rotation piece 200 is in the first state, an orthographic projection of the rotation piece 200 on the apparatus body 100 falls within the outline of the apparatus body 100; when the rotation member 200 is in the second state, the orthographic projection of the rotation member 200 on the apparatus body 100 is projected outside the outline of the apparatus body 100.

The first sliding groove 310 may be an arc-shaped groove, and may also be a groove of other forms. The first sliding groove 310 is adapted to the motion track of the rotating member 200, that is, the first sliding groove 310 is configured not to interfere with the motion of the rotating member 200.

When the rotating member 200 rotates along the rotating shaft T, the limiting member 1200 rotates along the first sliding groove 310 synchronously to limit the rotating member 200.

The first sliding groove 310 serves to limit the movement of the rotating member 200, and the first sliding groove 310 includes a first side wall and a second side wall opposite to each other, wherein the first side wall is adjacent to an edge portion of the apparatus body 100 relative to the second side wall. When the rotating member 200 is completely received in the receiving groove 100a, the rotating member 200 abuts against the second side wall, and when the rotating member 200 completely extends out of the receiving groove 100a, the rotating member 200 abuts against the first side wall, so that the moving stroke of the rotating member 200 is limited between the first side wall and the second side wall.

In an embodiment, the rotating member 200 is provided with the first sliding slot 310, and the apparatus body 100 is provided with a first protruding structure, which can slide in the first sliding slot 310, so that the rotating member 200 is rotatably connected to the apparatus body 100 along the arc-shaped track S. In another embodiment, the apparatus body 100 is provided with the first sliding slot 310, and the rotating member 200 is provided with a second protruding structure, which can slide in the first sliding slot 310, so that the rotating member 200 is rotatably connected to the apparatus body 100 along the arc-shaped track S.

In a preferred embodiment, the rotation angle of the rotation element 200 relative to the device body 100 is less than 45 degrees, so that the rotation element 200 shields the opening of the receiving slot 100a, which helps to improve the uniformity of the appearance of the electronic device 10.

Referring to fig. 5, in another preferred embodiment, the second end 220 includes a sliding surface 220a far away from the first end 210, the sliding surface 220a is an arc-shaped surface, and the sliding surface 220a protrudes from a direction far away from the first end 210, and when the second end 220 extends out of or retracts into the accommodating slot 100a relative to the first end 210, the sliding surface 220a is always attached to the apparatus body 100.

Specifically, the curved track of the sliding surface 220a and the curved track of the first sliding groove 310 are kept consistent, which helps to reduce the friction between the rotating member 200 and the device body 100, and the sliding surface 220a can be kept always attached to the device body 100 during the movement of the rotating member 200, which helps to solve the problem of consistency of the appearance of the electronic device 10 during the movement of the rotating member 200.

The electronic device 10 provided by the present application includes a device body 100 and a rotation member 200, the rotation member 200 is rotatably connected to the device body 100, when the rotation member 200 rotates relative to the device body 100, the rotation member 200 includes a first state completely received in the receiving groove 100a of the device body 100 and a second state partially received in the receiving groove 100a, and is rotatably connected to the device body 100 through the rotation member 200, and when the rotation member 200 rotates relative to the device body 100, the reception groove 100a can be extended or retracted, which helps to make the electronic device 10 exhibit various structural transformation modes.

Referring to fig. 6 and fig. 7, in another preferred embodiment, the electronic device 10 further includes a camera 400, the camera 400 is mounted on the rotating member 200, and the camera 400 is disposed obliquely with respect to the rotating member 200.

The electronic device 10 further includes a camera 400, the camera 400 is installed in the rotating member 200, and when the rotating member 200 completely extends out of the accommodating groove 100a, an acquired image is captured by the camera 400 as a normal viewing angle.

The fact that the image obtained by shooting through the camera 400 is in the normal view means that the image obtained by shooting through the camera 400 conforms to the daily shooting habit of people, namely, the view of the image is adaptive to the device body 100.

Specifically, the electronic device 10 further includes a camera support 410, the camera support 410 is used for fixing the camera 400, the camera support 410 and the camera 400 form a camera module 4041, and the camera module 4041 is fixed to the rotating member 200, the camera support 410 is rectangular, when the rotating member 200 is at least partially accommodated in the accommodating groove 100A, an acute angle α is formed between a top wall 410A of the camera support 410 and the top wall 100A of the device body 100, and when the rotating member 200 completely extends out of the accommodating groove 100A, an angle of 0 degree is formed between the top wall 410A of the camera support 410 and the top wall 100A of the device body 100.

Further, the direction of the optical main axis of the camera 400 is perpendicular to the rotation direction of the rotation member 200, and the electronic device 10 further includes a flash lamp 420, wherein the flash lamp 420 is installed on the rotation member 200, and the flash lamp 420 is disposed adjacent to the camera 400.

The direction of the optical main shaft is consistent with the light incident direction of the camera 400. In other embodiments, the flash 420 is provided on the apparatus body 100.

Referring to fig. 8, in an embodiment, the electronic device 10 further includes a flexible circuit board 430, the flexible circuit board 430 includes a first fixing portion 431, a bending portion 432, and a second fixing portion 433 that are connected to each other, the first fixing portion 431 is fixedly connected to the rotating member 200, the first fixing portion 431 is electrically connected to the camera 400 and the flashlight 420, and the second fixing portion 433 is fixedly connected to the middle frame 103 of the electronic device 10 and is electrically connected to the main circuit board 1030 on the middle frame 103. When the first end 210 rotates relative to the device body 100 to extend or retract the second end 220 into the receiving slot 100a, the bent portion 432 is in a free state, so that the bent portion can move along with the movement of the rotating member 200, thereby preventing the flexible circuit board 430 from being pulled, and facilitating a stable electrical connection relationship among the camera 400, the flashlight 420 and the main circuit board 1030.

Referring to fig. 9, in an embodiment, the rotating member 200 is provided with the first sliding slot 310 adjacent to the first end 210, and the device body 100 is provided with a limiting member 510, wherein the limiting member 510 can slide in the first sliding slot 310 to extend or retract the second end 220 into the receiving slot 100 a.

When the first end 210 rotates relative to the device body 100 to extend or retract the second end 220 into the accommodating slot 100a, the arc track S of the rotation member 200 and the curve track of the first sliding slot 310 are located on the same concentric circle, so that the rotation member 200 can smoothly extend or retract into the accommodating slot 100a, which is beneficial to reducing the wear of the rotation member 200.

Further, when the rotating member 200 is provided with the first sliding slot 310, the first sliding slot 310 may penetrate through the rotating member 200, or the first sliding slot 310 may not penetrate through the rotating member 200. The limiting member 510 may be fixed to the battery cover 101 of the device body 100 or fixed to the middle frame 103 of the device body 100, and the limiting member 510 and the first sliding groove 310 are matched with each other, so that the rotating member 200 extends or retracts relative to the device body 100.

Referring to fig. 10, in another embodiment, the apparatus body 100 is provided with the first sliding groove 310 adjacent to the first end 210, the rotating member 200 is provided with a limiting member 520 adjacent to the first end 210, and the limiting member 520 can slide in the first sliding groove 310 to extend or retract the second end 220 into the accommodating groove 100 a.

When the first chute 310 is opened in the middle frame 103 of the apparatus body 100, the first chute 310 may penetrate through the middle frame 103 of the apparatus body 100, or the first chute 310 may not penetrate through the middle frame 103 of the apparatus body 100. When the battery cover 101 of the device body 100 opens the first sliding slot 310, the first sliding slot 310 does not penetrate through the battery cover 101 of the device body 100. The limiting member 520 is fixed to the rotating member 200, and the limiting member 520 and the first sliding groove 310 are matched with each other, so that the rotating member 200 extends or retracts relative to the apparatus body 100.

Referring to fig. 11, the electronic device 10 further includes a rotating shaft 530, the rotating shaft 530 is disposed at the first end 210 of the rotating member 200 and is located at a side of the first sliding slot 310 away from the second end 220, the rotating member 200 is rotatably connected to the device body 100 through the rotating shaft 530, and the first sliding slot 310 rotates with the rotating shaft 530 as a rotating shaft.

When the first sliding chute 310 is an arc-shaped chute, the arc-shaped locus S of the first sliding chute 310 is on a circle with the rotating shaft 530 as the center. The rotation shaft 530 is a fixed shaft, and the rotation member 200 is rotatable with respect to the apparatus body 100 through the rotation shaft 530.

In one embodiment, the rotating shaft 530 is fixed to the rotating member 200, a mounting hole 530a is formed in the device body 100, and the rotating shaft 530 is at least partially received in the mounting hole 530a and can rotate in the mounting hole 530 a.

When the apparatus body 100 includes the middle frame 103, the mounting hole 530a is opened on the middle frame 103, and the mounting hole 530a may be a through hole, that is, the mounting hole 530a penetrates through the middle frame 103, or the mounting hole 530a may be a blind hole, that is, the mounting hole 530a does not penetrate through the middle frame 103.

When the device body 100 includes the battery cover 101, the mounting hole 530a is opened on the battery cover 101, and the mounting hole 530a is a blind hole, that is, the mounting hole 530a does not penetrate through the battery cover 101.

Referring to fig. 12, in another embodiment, the rotating shaft 530 is fixed to the device body 100, the rotating member 200 is provided with a mounting hole 530b, and the rotating shaft 530 is at least partially received in the mounting hole 530b and can rotate in the mounting hole 530 b.

Specifically, when the rotating member 200 is provided with the mounting hole 530b, the mounting hole 530b may be a through hole, that is, the mounting hole 530b penetrates through the rotating member 200, and the mounting hole 530b may also be a blind hole, and the mounting hole 530b does not penetrate through the rotating member 200.

When the apparatus body 100 includes the middle frame 103, the rotation shaft 530 is fixed to the middle frame 103, and when the apparatus body 100 includes the battery cover 101, the rotation shaft 530 is fixed to the battery cover 101.

Referring to fig. 13, the electronic device 10 further includes a second sliding slot 320, the second sliding slot 320 is located on a side of the first sliding slot 310 away from the first end 210, and the rotating element 200 extends out of or retracts into the accommodating slot 100a through the second sliding slot 320 and the first sliding slot 310.

In one embodiment, when the first sliding chute 310 and the second sliding chute 320 are both arc-shaped chutes, the curvature of the curved track of the second sliding chute 320 and the curved track of the first sliding chute 310 are kept consistent, the second sliding chute 320 and the first sliding chute 310 both rotate with the rotating shaft 530 as a rotating shaft, and the sliding stroke of the second sliding chute 320 is greater than that of the first sliding chute 310.

Specifically, the first sliding groove 310 and the second sliding groove 320 may be simultaneously located on the rotating member 200, and the first sliding groove 310 and the second sliding groove 320 may also be simultaneously located on the device body 100. When the first sliding groove 310 is located on the rotating member 200, the second sliding groove 320 may be located on the device body 100. When the first sliding groove 310 is located on the device body 100, the second sliding groove 320 may be located on the rotating member 200.

In one embodiment, when the rotating member 200 opens the second sliding slot 320, the second sliding slot 320 may penetrate the rotating member 200, and the second sliding slot 320 may not penetrate the rotating member 200.

In another embodiment, the equipment body 100 opens the second chute 320.

When the second chute 320 is opened in the middle frame 103 of the apparatus body 100, the second chute 320 may penetrate through the middle frame 103 of the apparatus body 100, and the second chute 320 may not penetrate through the middle frame 103 of the apparatus body 100. When the battery cover 101 of the device body 100 opens the second sliding slot 320, the second sliding slot 320 does not penetrate through the battery cover 101 of the device body 100.

Further, the curved tracks of the first sliding chute 310 and the second sliding chute 320 are on a concentric circle with the rotation axis 530 as the center, and the second sliding chute 320 is located at a side of the first sliding chute 310 away from the first end 210, so that the radius of the concentric circle corresponding to the curved track of the second sliding chute 320 is larger than the radius of the concentric circle corresponding to the curved track of the first sliding chute 310, and when the sliding stroke of the second sliding chute 320 is larger than the sliding stroke of the first sliding chute 310, the second sliding chute 320 and the first sliding chute 310 are matched with each other without interfering with the movement form of the rotating member 200.

In another embodiment, the curved tracks of the second sliding slot 320 and the first sliding slot 310 have unequal curvature, and the second sliding slot 320 and the first sliding slot 310 cooperate with each other to limit the swing angle of the rotating member 200.

Specifically, the extending directions of the first sliding groove 310 and the second sliding groove 320 are not the same, so that the first sliding groove 310 and the second sliding groove 320 are constrained with each other, and when the rotating member 200 extends out of or retracts into the accommodating groove 100a relative to the device body 100 through the first sliding groove 310 and the second sliding groove 320, because the extending directions of the first sliding groove 310 and the second sliding groove 320 are not the same, a certain degree of interference is generated on the movement of the rotating member 200, and a limiting effect is performed on the rotating member 200, so that the rotating member 200 is limited at a preset position of the device body 100.

With reference to fig. 14, the electronic device 10 further includes a driving assembly 600, the driving assembly 600 includes a driving mechanism 610 and a pushing assembly 620, the driving mechanism 610 is fixedly connected to the device body 100, the pushing assembly 620 is movably connected to the second end 220, and the driving mechanism 610 is configured to control the pushing assembly 620 to move, so that the second end 220 swings relative to the first end 210 to extend or retract the accommodating slot 100 a.

The pushing assembly 620 includes a pushing element 621 and an elastic element 622, one end of the pushing element 621 is movably connected to the rotating element 200, the other end of the pushing element 621 can slide relative to the driving mechanism 610, the elastic element 622 is sleeved on the pushing element 621, one end of the elastic element 622 is fixedly connected to the pushing element 621, the other end of the elastic element 622 is fixedly connected to the driving mechanism 610, and the driving mechanism 610 is configured to control the elastic element 622 to move to drive the rotating element 200 to swing, so as to extend or retract the rotating element 200 into the receiving slot 100 a.

Referring to fig. 15, the driving mechanism 610 includes a case 611, a driving motor 612, a rotating member 613 and a sliding member 614, the case 611 is fixedly connected to the apparatus body 100, the driving motor 612 is fixedly connected to the case 611, the rotating member 613 is rotatably connected to the case 611, the driving motor 612 is used for controlling the rotating member 613 to rotate, one end of the sliding member 614 is sleeved on the rotating member 613, and the other end of the sliding member 614 is connected to the elastic member 622; when the driving motor 612 controls the rotating part 613 to rotate so as to drive the sliding part 614 to move, the elastic part 622 moves towards or away from the rotating part 200.

The driving mechanism 610 further includes a guide 615, the guide 615 is fixedly connected to the case 611, the sliding member 614 is sleeved on the guide 615, the guide 615 is used for assisting the sliding member 614 to move, the sliding member 614, the guide 615 and the driving motor 612 are arranged side by side, and the guide 615 and the rotating member 613 together form a sliding track of the sliding member 614.

The driving mechanism 610 further includes a transmission member 616, the box body 611 includes a box body 6111 and a box body extension portion 6112 extending from one side of the box body 6111, the box body 6111 is used for fixing the driving motor 612 and is used for accommodating the transmission member 616, the box body extension portion 6112 is surrounded to form an accommodating space 6112a, the accommodating space 6112a is used for accommodating the rotating member 613 and the sliding member 614, and the rotating member 613 is rotatably connected to the box body extension portion 6112; when the power output by the driving motor 612 is transmitted to the rotating part 613 through the transmission part 616, the rotating part 613 can rotate around its central axis compared with the case extension part 6112, so as to drive the sliding part 614 to slide compared with the case extension part 6112.

The box extension part 6112 includes a fixing part 6113 and a connecting part 6114, which are connected, the fixing part 6113 is fixedly connected with the box body 6111, the connecting part 6114 is connected to the fixing part 6113 and is located at one side of the fixing part 6113, which is far away from the box body 6111, the fixing part 6113 and the rotating part 613 are arranged side by side, and the sliding part 614 is connected between the connecting part 6114 and the box body 6111.

The driving motor 612 is located on one side of the fixing portion 6113 away from the connecting portion 6114, the driving motor 612 and the rotating part 613 are arranged side by side, and the driving motor 612, the rotating part 613 and the sliding part 614 are located on the same side of the box body 6111.

With reference to fig. 16, the apparatus body 100 has an accommodating space 100b, the accommodating space 100b is communicated with the accommodating groove 100a through a first through hole 100c, the accommodating space 100b is used for completely accommodating the driving mechanism 610 and partially accommodating the pushing assembly 620, the pushing member 621 can extend out of or retract into the accommodating space 100b through the first through hole 100c, a sealing sleeve 623 is disposed outside the elastic member 622 and the pushing member 621, a sealing ring 624 is disposed outside the sealing sleeve 623, the sealing ring 624 is fixed to the apparatus body 100 and accommodated in the first through hole 100c, and the sealing sleeve 623 and the sealing ring 624 are used for sealing the pushing assembly 620.

Referring to fig. 17, the electronic device 10 includes a device body 100 and a rotating member 200, the device body 100 has a receiving slot 100a, the rotating member 200 is rotatably connected to the device body 100 through a first rotating shaft 540, the rotating member 200 can rotate out of the receiving slot 100a from the receiving slot 100a relative to the device body 100, and can rotate into the receiving slot 100a from the receiving slot 100a relative to the device body 100; the opening of the receiving groove 100a penetrates only one side wall of the device body 100, and the rotating member 200 has a force receiving portion 2000, the force receiving portion 2000 is offset from the center of the first rotating shaft 540, and when the force receiving portion 2000 receives an external force, the rotating member 200 can rotate relative to the device body 100.

Specifically, the first rotating shaft 540 is along the thickness direction of the apparatus body 100.

The device body 100 includes a battery cover 101, a display screen 102, and a middle frame 103. In one embodiment, the battery cover 101 is fixed to the middle frame 103, and the display screen 102 is fixed to the middle frame 103, and the middle frame 103 forms the receiving groove 100 a. In another embodiment, the middle frame 103 is accommodated in the battery cover 101, the display screen 102 is fixed to the battery cover 101, and the frame opening of the battery cover 101 forms the accommodating groove 100 a.

Alternatively, the first rotating shaft 540 may be located on the rotating member 200 or the device body 100. When the first rotating shaft 540 is located on the rotating member 200, the apparatus body 100 is provided with a third mounting hole 540a, and the first rotating shaft 540 is received in the third mounting hole 540a and can rotate in the third mounting hole 540 a. When the apparatus body 100 includes the middle frame 103, the third mounting hole 540a is opened on the middle frame 103, and the third mounting hole 540a may be a through hole, that is, the third mounting hole 540a penetrates through the middle frame 103; the third mounting hole 540a may also be a blind hole, that is, the third mounting hole 540a does not penetrate through the middle frame 103. When the apparatus body 100 includes the battery cover 101, the third mounting hole 540a is opened on the battery cover 101, the third mounting hole 540a is a blind hole, and the third mounting hole 540a does not penetrate through the battery cover 101. When the first rotating shaft 540 is located in the device body 100, the rotating member 200 is provided with a fourth mounting hole, and the first rotating shaft 540 is accommodated in the fourth mounting hole and can rotate in the fourth mounting hole. When the apparatus body 100 includes the middle frame 103, the first rotating shaft 540 is located on the middle frame 103; when the apparatus body 100 includes the battery cover 101, the first rotation shaft 540 is located on the battery cover 101.

The electronic device 10 provided by the embodiment of the present application includes a device body 100 and a rotating member 200, the device body 100 has an accommodating slot 100a, the rotating member 200 is rotatably connected to the device body 100 through a first rotating shaft 540, when the rotating member 200 rotates relative to the device body 100, the accommodating slot 100a can be extended or retracted, and an opening of the accommodating slot 100a only penetrates through one side wall of the device body 100. The rotating member 200 is rotatably connected to the device body 100 through the first rotating shaft 540, and the rotating member 200 can partially extend out of the receiving slot 100a and completely retract into the receiving slot 100a, so as to prevent the rotating member 200 from occupying the space of the display area of the electronic device 10, which is helpful for increasing the screen occupation ratio of the electronic device 10.

Referring to fig. 18, the electronic device 10 further includes a second rotating shaft 550, the first rotating shaft 540 is fixedly connected to the device body 100 or the rotating member 200, and the second rotating shaft 550 is slidably connected to the device body 100 or the rotating member 200.

Specifically, the first rotating shaft 540 is a fixed shaft with respect to the apparatus body 100 or the rotating member 200, and the second rotating shaft 550 is a movable shaft with respect to the apparatus body 100 or the rotating member 200. The first rotating shaft 540 and the second rotating shaft 550 may be simultaneously located on the rotating member 200. The first rotating shaft 540 and the second rotating shaft 550 may be located on the apparatus body 100 at the same time. When the first rotating shaft 540 is located on the rotating member 200, the second rotating shaft 550 may be located on the device body 100. When the first rotating shaft 540 is located on the device body 100, the second rotating shaft 550 is located on the rotating member 200. The first rotating shaft 540 and the second rotating shaft 550 are engaged with each other to partially extend or retract the rotating member 200 into the receiving groove 100 a.

The second rotating shaft 550 is slidably connected to the apparatus body 100 or the rotating member 200 through a third sliding slot 330 along the arc-shaped track S.

In one embodiment, when the rotating member 200 opens the third sliding slot 330, the third sliding slot 330 may penetrate the rotating member 200, and the third sliding slot 330 may not penetrate the rotating member 200.

In another embodiment, the equipment body 100 opens the third chute 330.

When the third sliding groove 330 is formed in the middle frame 103 of the apparatus body 100, the third sliding groove 330 may penetrate through the middle frame 103 of the apparatus body 100, and the third sliding groove 330 may not penetrate through the middle frame 103 of the apparatus body 100. When the battery cover 101 of the device body 100 opens the third sliding chute 330, the third sliding chute 330 does not penetrate through the battery cover 101 of the device body 100.

Specifically, the third sliding groove 330 may be an arc-shaped groove, and may also be a groove with other structural forms. The second rotating shaft 550 slides in the third sliding slot 330 along the arc-shaped track S. When the third sliding slot 330 is an arc-shaped slot, the third sliding slot 330 and the second rotating shaft 550 cooperate with each other to extend or retract the rotating member 200 into the receiving slot 100 a.

Referring to fig. 19, the electronic device 10 further includes a third rotating shaft 560, the first rotating shaft 540 is slidably connected to the device body 100 or the rotating member 200, and the third rotating shaft 560 is slidably connected to the device body 100 or the rotating member 200.

The first rotating shaft 540 is a movable shaft relative to the apparatus body 100 or the rotating member 200, and the third rotating shaft 560 is a movable shaft relative to the apparatus body 100 or the rotating member 200.

Specifically, the first rotating shaft 540 and the third rotating shaft 560 may be simultaneously located on the rotating member 200. The first rotating shaft 540 and the third rotating shaft 560 may also be located on the apparatus body 100 at the same time. When the first rotating shaft 540 is located on the rotating member 200, the third rotating shaft 560 may be located on the device body 100. When the first rotating shaft 540 is located on the device body 100, the third rotating shaft 560 may be located on the rotating member 200.

The first rotating shaft 540 is slidably connected to the apparatus body 100 or the rotating member 200 through a fourth sliding groove 340 along an arc-shaped track S, and the third rotating shaft 560 is slidably connected to the apparatus body 100 or the rotating member 200 through a fifth sliding groove 350 along the arc-shaped track S.

In one embodiment, when the rotating member 200 opens the fourth sliding groove 340, the fourth sliding groove 340 may penetrate the rotating member 200, and the fourth sliding groove 340 may not penetrate the rotating member 200.

In another embodiment, the equipment body 100 is provided with the fourth chute 340.

When the fourth chute 340 is opened in the middle frame 103 of the apparatus body 100, the fourth chute 340 may penetrate through the middle frame 103 of the apparatus body 100, and the fourth chute 340 may not penetrate through the middle frame 103 of the apparatus body 100. When the battery cover 101 of the device body 100 opens the fourth sliding groove 340, the fourth sliding groove 340 does not penetrate through the battery cover 101 of the device body 100.

Referring to fig. 20, in one embodiment, when the rotating component 200 opens the fifth sliding slot 350, the fifth sliding slot 350 may penetrate through the rotating component 200, and the fifth sliding slot 350 may not penetrate through the rotating component 200.

In another embodiment, the equipment body 100 is opened with the fifth chute 350.

When the fifth chute 350 is opened in the middle frame 103 of the apparatus body 100, the fifth chute 350 may penetrate through the middle frame 103 of the apparatus body 100, and the fifth chute 350 may not penetrate through the middle frame 103 of the apparatus body 100. When the battery cover 101 of the device body 100 opens the fifth sliding groove 350, the fifth sliding groove 350 does not penetrate through the battery cover 101 of the device body 100.

Referring to fig. 21, the electronic device 10 includes a device body 100, a rotating member 200, a sensor 700 and a processor 710, wherein the rotating member 200 is rotatably connected to the device body 100, the device body 100 has a receiving slot 100a, and when the rotating member 200 rotates relative to the device body 100, the receiving slot 100a can be extended or retracted; when the rotating member 200 extends out of the accommodating slot 100a and the sensor 700 detects that the variation of the acceleration of the rotating member 200 in a unit time is greater than a preset threshold, the sensor 700 is configured to detect a drop signal of the electronic device 10, and the processor 710 controls the rotating member 200 to rotate into the accommodating slot 100a when the sensor 700 detects the drop signal of the electronic device 10.

The sensor 700(acceleration transducer) is a sensor capable of measuring acceleration. The damper is generally composed of a mass block, a damper, an elastic element, a sensitive element, an adjusting circuit and the like. In the acceleration process, the sensor obtains an acceleration value by measuring the inertial force borne by the mass block and utilizing Newton's second law. Common sensors 700 include capacitive, inductive, strain-gauge, piezoresistive, piezoelectric, etc., depending on the sensor's sensing elements.

The processor 710 may be a Central Processing Unit (CPU), which is an ultra-large scale integrated circuit and is a computing Core (Core) and a control Core (control Unit) of a computer. Its functions are mainly to interpret computer instructions and to process data in computer software. The system mainly comprises an Arithmetic Unit (ALU), a Cache memory (Cache) and a Bus (Bus) for realizing Data, control and state of the connection between the ALU and the Cache memory.

When the sensor 700 detects that the variation amount of the acceleration of the rotating member 200 per unit time is greater than the preset threshold, the rotating member 200 is considered to have a sudden acceleration, and at this time, the processor 710 determines that the rotating member 200 is in a state of a sudden acceleration or a sudden deceleration, and if the rotating member 200 is in a state of extending out of the accommodating slot 100a at this time, in order to safely protect the rotating member 200, at this time, the sensor 700 sends a first feedback signal, and the processor 710 receives the first feedback signal and controls the rotating member 200 to retract into the accommodating slot 100a according to the first feedback signal, so as to prevent the rotating member 200 from being damaged when the rotating member 200 is subjected to a violent movement (including a sudden acceleration or a sudden deceleration), thereby helping to protect the rotating member 200.

When the sensor 700 detects that the acceleration of the rotating member 200 is the gravitational acceleration, the sensor 700 sends a first feedback signal, the processor 710 receives the first feedback signal and generates a first control signal according to the first feedback signal, and the processor 710 controls the rotating member 200 to retract into the accommodating slot 100a according to the first control signal.

Specifically, when the acceleration of the rotating member 200 is the acceleration of gravity, it is considered that the electronic device 10 is in the free-fall state, at this time, the sensor 700 sends a first feedback signal, and the processor 710 receives the first feedback signal and controls the rotating member 200 to retract into the accommodating groove 100a according to the first feedback signal, so that the rotating member 200 can be protected from falling, and the rotating member 200 is prevented from being damaged in the falling process.

The electronic device 10 provided by the embodiment of the application comprises a device body 100, a rotating piece 200, a sensor 700 and a processor 710, wherein the rotating piece 200 is rotatably connected with the device body 100, the device body 100 is provided with an accommodating groove 100a, the rotating piece 200 can extend out of or retract into the accommodating groove 100a, the rotating piece 200 is prevented from occupying the space of the display area of the electronic device 10, and the screen occupation ratio of the electronic device 10 is improved. And further, when the rotating member 200 extends out of the receiving slot 100a and the sensor 700 detects that the variation of the acceleration of the rotating member 200 per unit time is greater than the preset threshold, the processor 710 controls the rotating member 200 to retract into the receiving slot 100a, so that the rotating member 200 can be prevented from being damaged due to the sudden acceleration, which is helpful for protecting the rotating member 200.

Referring to fig. 22, the electronic device 10 further includes a photosensitive sensor 720, the photosensitive sensor 720 is received in the receiving slot 100a and disposed adjacent to the rotating member 200, when the photosensitive sensor 720 detects that the intensity of the light radiation on the side adjacent to the rotating member 200 is greater than a predetermined intensity, the photosensitive sensor 720 sends a second feedback signal, and the processor 710 receives the second feedback signal and determines that the rotating member 200 extends out of the receiving slot 100a according to the second feedback signal.

The photosensor 720 is a sensor that converts an optical signal into an electrical signal using a photosensor, and has a wavelength near visible light wavelengths, including infrared wavelengths and ultraviolet wavelengths.

When the light sensor 720 detects that the intensity of light radiation in the receiving slot 100a adjacent to the rotating member 200 is greater than a predetermined intensity, it is determined that light outside the electronic device 10 enters the device body 100 through the receiving slot 100a, and the light sensor 720 determines that the rotating member 200 is in a state of extending out of the receiving slot 100a, i.e. a second feedback signal is sent, the processor 710 can determine that the rotating member 200 extends out of the receiving slot 100a according to the second feedback signal, at this time, the sensor 700 can detect the variation of acceleration of the rotating member 200 in a state of extending out of the receiving slot 100a in a unit time, and when the variation of acceleration of the rotating member 200 is detected to be greater than a predetermined threshold, the sensor 700 sends a first feedback signal, and the processor 710 receives the first feedback signal, and generating a first control signal according to the first feedback signal, wherein the first control signal is used for controlling the rotating member 200 to retract into the accommodating groove 100a, so as to form safety protection for the rotating member 200.

Referring to fig. 23, the electronic device 10 further includes a distance sensor 730, the distance sensor 730 is disposed adjacent to the rotating member 200, when the distance sensor 730 detects that the distance between the rotating member 200 and the device body 100 is greater than a predetermined distance, the distance sensor 730 sends a third feedback signal, and the processor 710 receives the third feedback signal and determines that the rotating member 200 extends out of the accommodating slot 100a according to the third feedback signal.

The distance sensor 730 is also called a displacement sensor, and is used for sensing a distance between the distance sensor and an object to perform a predetermined function. The distance sensor 730 may be classified into an optical distance sensor 730, an infrared distance sensor 730, an ultrasonic distance sensor 730, and the like according to its operation principle.

When the distance sensor 730 detects that the distance between the rotor 200 and the apparatus body 100 is greater than a predetermined distance, the distance sensor 730 determines that the rotor 200 is in a state of extending out of the receiving slot 100a, i.e., sends a third feedback signal, the processor 710 can determine that the rotor 200 extends out of the receiving slot 100a according to the third feedback signal, at this time, the sensor 700 can detect an acceleration variation per unit time when the rotor 200 is in a state of extending out of the receiving slot 100a, when the acceleration variation of the rotor 200 is detected to be greater than a predetermined threshold, the sensor 700 sends a first feedback signal, the processor 710 receives the first feedback signal and generates a first control signal according to the first feedback signal, the first control signal is used for controlling the rotor 200 to retract into the receiving slot 100a, thereby providing safety protection for the rotation member 200.

With reference to fig. 24, the electronic device 10 includes a device body 100, a rotating member 200 and a second processor 740, wherein the device body 100 has a receiving slot 100a, and the rotating member 200 is rotatably connected to the device body 100 such that the rotating member 200 can extend out of or retract into the receiving slot 100 a; the second processor 740 starts a preset function in a target application according to the state of the rotator 200 and the state of the target application in the electronic device 10.

In an embodiment, the electronic device 10 further includes a camera 400, the camera 400 is installed on the rotating component 200, the target application is a photographing application, and when the second processor 740 detects that the target application is in an open state and the rotating component 200 extends out of the accommodating slot 100a, the second processor 740 starts a photographing function of the photographing application, so that the display screen 102 of the electronic device 10 enters a photographing interface.

In another embodiment, the electronic device 10 further includes a camera 400, the camera 400 is installed on the rotating component 200, the target application is a photographing application, when the second processor 740 detects that the target application is in an open state and the rotating component 200 retracts into the accommodating slot 100a, the second processor 740 first controls the rotating component 200 to extend out of the accommodating slot 100a, so that the camera 400 extends out of the accommodating slot 100a of the device body 100, and then starts a photographing function of the photographing application.

In one embodiment, when the rotating member 200 is fully extended out of the accommodating groove 100a, the image captured by the camera 400 is a normal viewing angle. The fact that the image obtained by shooting through the camera 400 is in the normal view means that the image obtained by shooting through the camera 400 conforms to the daily shooting habit of people, namely, the view of the image is adaptive to the device body 100. Specifically, the electronic device 10 further includes a camera support 410, the camera support 410 is used for fixing the camera 400, the camera support 410 and the camera 400 form a camera module 4041, and the camera module 4041 is fixed to the rotating member 200. The camera support 410 is rectangular, and when the rotating member 200 is at least partially received in the receiving groove 100A, a top wall 410A of the camera support 410 forms an acute angle with a top wall 100A of the apparatus body 100; when the rotating member 200 completely extends out of the accommodating groove 100A, an included angle of 0 degree is formed between the top wall 410A of the camera support 410 and the top wall 100A of the apparatus body 100. Further, the direction of the optical main axis of the camera 400 is perpendicular to the rotation direction of the rotation member 200. The direction of the optical main shaft is consistent with the light incident direction of the camera 400.

Referring to fig. 25, in another embodiment, the electronic device 10 further includes an image processor 750. The image processor 750 is software for processing such as a class and a composition. I.e. to transform an image in its natural form into a digital form suitable for computer processing, including the display of picture histograms, grey-scale maps, etc., by sampling and quantization processes, and to repair pictures, i.e. to improve the quality of pictures by image enhancement or restoration.

When the rotating member 200 is completely extended out of the accommodating groove 100a, an image photographed by the camera 400 is at an abnormal viewing angle, and at this time, the second processor 740 sends a fifth feedback signal according to the image at the abnormal viewing angle, and the image processor 750 receives the fifth feedback signal and corrects the image at the abnormal viewing angle according to the fifth feedback signal, so that the image is at a normal viewing angle.

Referring to fig. 26, in another embodiment, the electronic device 10 further includes a flash 420 and an optical sensor 760, the flash 420 and the optical sensor 760 are fixed to the rotator 200, and when the rotator 200 is received in the receiving slot 100a, the flash 420 and the optical sensor 760 are hidden in the device body 100. When the rotating member 200 partially extends out of the accommodating groove 100a, the optical sensor 760 is configured to acquire light intensity of the camera 400 in the current environment, and when the light intensity is smaller than a preset intensity, the optical sensor 760 sends a sixth feedback signal, the second controller receives the sixth feedback signal and sends a control signal according to the sixth feedback signal, and the control signal is configured to control the flash 420 to be turned on to supplement light for the camera 400. It is understood that, in other embodiments, the flash 420 may be disposed on the apparatus body 100.

In another embodiment, the target application is a payment application, and when the second processor 740 detects that the target application is in an on state and the rotator 200 extends out of the receiving slot 100a, the second processor 740 controls the display screen 102 of the electronic device 10 to enter a payment interface.

In the conventional technology, when a payment application program is started, the payment application program enters a home page, and the home page comprises a plurality of submenus, wherein click icons entering a payment interface are arranged in the submenus. Compared with the conventional technology, when the rotating member 200 extends out of the accommodating slot 100a and the payment application program is started, the second processor 740 controls the payment application program to directly enter the payment interface, that is, the display screen 102 of the electronic device 10 displays the payment interface of the payment application program, so that the operations of multiple steps of the payment application program are avoided, the operation of the payment application program is saved, the efficiency of operating the payment application program is improved, the operation time is shortened, and the electronic device is more humanized.

With reference to fig. 27, in addition, the electronic device 10 further includes a structured light sensor 770, where the structured light sensor 770 is fixed on the rotating component 200, and when the second processor 740 detects that a target object is performing a transfer operation on the target application, the processor controls the rotating component 200 to extend out of the accommodating slot 100a and controls the structured light sensor 770 to perform an identity verification on the target object.

Referring to fig. 28, fig. 29 and fig. 30, in another embodiment, the electronic device 10 includes a receiver 780, the receiver 780 is located on the rotating member 200, and when the rotating member 200 is accommodated in the accommodating slot 100a, the first sound outlet 780a of the receiver 780 is hidden in the device body 100. The target application program is a voice control program, and when the second processor 740 detects that the target application program is in an open state and the rotating member 200 retracts into the accommodating slot 100a, the second processor 740 controls the rotating member 200 to extend out of the accommodating slot 100a, and then controls the display screen 102 of the electronic device 10 to enter a voice control interface.

The voice control program may be, among other things, a voice assistant application of the electronic device 10.

Specifically, when the rotating member 200 is accommodated in the accommodating groove 100a, the first sound outlet 780a of the receiver 780 is hidden in the device body 100, so that the voice control program and the user can perform voice interaction without being affected, and therefore, only when the rotating member 200 extends out of the accommodating groove 100a, the voice control program and the user can perform normal voice interaction. When a user needs to perform voice interaction with a voice control program, if the rotating member 200 extends out of the receiving groove 100a to expose the first sound outlet 780a of the receiver 780 on the rotating member 200, the voice control program can perform normal voice interaction with the user. If the rotating member 200 is in the state of retracting into the receiving groove 100a, the first sound outlet 780a of the receiver 780 on the rotating member 200 is in the state of being hidden in the device body 100, at this time, the rotating member 200 needs to be controlled to extend out of the receiving groove 100a, so that the first sound outlet 780a of the receiver 780 on the rotating member 200 is exposed, and then the normal voice interaction between the voice control program and the user can be performed. It can be understood that, in other embodiments, the receiver 780 further includes a second sound outlet 780b, when the rotating member 200 is completely received in the receiving slot 100a, the second sound outlet 780b is exposed, and the first sound outlet 780a is hidden in the device body 100, at this time, the user can also perform normal voice interaction with the voice control program through the second sound outlet 780 b.

In another embodiment, the target application is a calling application, and when the second processor 740 detects that the target application is in a calling state and the rotating member 200 is retracted into the receiving slot 100a, the second processor 740 controls the rotating member 200 to extend out of the receiving slot 100a to connect the target application.

The incoming call application program may be a call program.

When the second processor 740 detects that the target application is in a call state and the rotating member 200 is in a state of retracting into the receiving slot 100a, if the call needs to be connected, the second processor 740 needs to control the rotating member 200 to extend out of the receiving slot 100a, and the action of the rotating member 200 extending out of the receiving slot 100a serves as a trigger signal to enable the call application to be connected, so that the call application is connected without a user through additional operation, the operation time of the call application is shortened, the efficiency of operating the call application is improved, and the user experience is improved.

The electronic device 10 provided by the embodiment of the application includes the device body 100, the rotating member 200 and the second processor 740, the device body 100 has the accommodating slot 100a, and the rotating member 200 can extend out of or retract into the accommodating slot 100a, so that the rotating member 200 is prevented from occupying the space of the display area of the electronic device 10, and the screen occupation ratio of the electronic device 10 is improved. Furthermore, the second processor 740 starts a preset function in the target application according to the state of the rotating member 200 and the state of the target application in the electronic device 10, so as to improve the starting efficiency of the target application, save the starting time of the target application, and improve the user experience.

With reference to fig. 31, the embodiment of the present application further provides a method for controlling an electronic device, where the electronic device 10 includes a device body 100 and a functional element 3000 located inside the device body 100, the method includes, but is not limited to, steps S100 and S200, and the following detailed descriptions about the steps S100 and S200 are provided.

S100: the electronic device 10 acquires an input signal.

S200: in response to the input signal, the function component 3000 rotates from the inside of the apparatus body 100 to the outside of the apparatus body 100 to perform a function corresponding to the function component 3000.

The functional component 3000 includes a camera 400, and when the electronic device 10 acquires an input signal, and the input signal is a shooting control signal of the camera 400, in response to the input signal, the camera 400 rotates out of the device body 100 from the inside of the device body 100 to execute a shooting function of the camera 400.

The functional component 3000 further includes a facial recognition sensor, and when the electronic device 10 acquires an input signal, which is a facial recognition signal of the facial recognition sensor, in response to the input signal, the facial recognition sensor rotates out of the device body 100 from the inside of the device body 100 to perform a facial recognition function of the facial recognition sensor.

The face recognition sensor may be a structured light sensor 770, among others.

The foregoing detailed description of the embodiments of the present application has been presented to illustrate the principles and implementations of the present application, and the above description of the embodiments is only provided to help understand the method and the core concept of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (17)

1. An electronic device, characterized in that the electronic device comprises:

the equipment body is provided with an accommodating groove;

rotate the piece, it includes relative first end and the second end that sets up to rotate the piece, first end will through a pivot rotate the piece with equipment body rotates and connects, and a functional unit is located the second end of rotating the piece, first end is rich the pivot is rotated so that functional unit changes over to or rolls over to out the accepting groove, equipment body with be provided with stop gear between the piece, stop gear includes first spout and locating part, the locating part can slide in the first spout, makes second end rotate with right along setting for the orbit rotate the piece carries on spacingly.

2. The electronic device according to claim 1, wherein the first sliding slot is located at the rotating member adjacent to the first end, and the device body is provided with the limiting member, and the limiting member is slidable in the first sliding slot to extend or retract the second end into the receiving slot.

3. The electronic device according to claim 1, wherein the device body has a first sliding slot at a position adjacent to the first end, the position-limiting member is located at a position adjacent to the first end of the rotating member, and the position-limiting member is slidable in the first sliding slot to extend or retract the second end into or out of the receiving slot.

4. The electronic device of claim 1, wherein the second end includes a sliding surface distal from the first end, the sliding surface being an arcuate surface.

5. The electronic device according to claim 1, wherein when the rotating member rotates along the rotating shaft, the limiting member rotates along the first sliding slot synchronously to limit the rotating member.

6. The electronic device according to claim 5, further comprising a second sliding slot spaced apart from the first sliding slot, wherein the rotating member extends out of or retracts into the receiving slot through the second sliding slot and the first sliding slot.

7. The electronic device according to claim 6, wherein the second sliding slot and the first sliding slot are arc-shaped sliding slots, and when the rotating member rotates along the rotating shaft, a sliding stroke of the second sliding slot is greater than a sliding stroke of the first sliding slot.

8. The electronic device according to claim 1, wherein a side of the first end adjacent to the device body forms an avoidance space, the avoidance space is located at an outer surface of the device body facing toward an inside of the device body, and the avoidance space is used for avoiding components arranged in the device body.

9. The electronic device according to claim 1, wherein a side of the device body adjacent to the rotating member has an avoiding groove for avoiding a partial structure of the rotating member to avoid interference with a rotating process of the rotating member.

10. The electronic device of any one of claims 1-9, further comprising a driving assembly, wherein the driving assembly comprises a driving mechanism and a pushing assembly, the driving mechanism is fixedly connected to the device body, the pushing assembly is movably connected to the second end, and the driving mechanism is configured to control the pushing assembly to move, so that the second end rotates relative to the first end to extend or retract the accommodating slot.

11. An electronic device, characterized in that the electronic device comprises:

the equipment body is provided with an accommodating groove;

the rotating piece is rotatably connected with the equipment body;

a sensor for detecting a drop signal of the electronic device;

and the processor controls the rotating piece to rotate into the accommodating groove when the sensor detects a falling signal of the electronic equipment.

12. The electronic device of claim 11, wherein when the sensor detects that the acceleration of the rotating member is gravity acceleration, the sensor sends a first feedback signal, the processor receives the first feedback signal and generates a first control signal according to the first feedback signal, and the processor controls the rotating member to retract into the accommodating slot according to the first control signal.

13. The electronic device according to claim 11 or 12, further comprising a photosensitive sensor, wherein the photosensitive sensor is received in the receiving slot and disposed adjacent to the rotating member, when the photosensitive sensor detects that the intensity of the light radiation adjacent to the side of the rotating member is greater than a predetermined intensity, the photosensitive sensor generates a second feedback signal, and the processor receives the second feedback signal and determines that the rotating member extends out of the receiving slot according to the second feedback signal.

14. The electronic device according to claim 11 or 12, further comprising a distance sensor disposed adjacent to the rotating member, wherein when the distance sensor detects that the distance between the rotating member and the device body is greater than a predetermined distance, the distance sensor sends a third feedback signal, and the processor receives the third feedback signal and determines that the rotating member extends out of the accommodating slot according to the third feedback signal.

15. A control method of an electronic device, wherein the electronic device includes a device body and a functional component located inside the device body, the method comprising:

the electronic equipment acquires an input signal;

in response to the input signal, the functional component rolls out of the outside of the apparatus body from the inside of the apparatus body to perform a function corresponding to the functional component.

16. The method according to claim 15, wherein the functional component includes a camera, and when the electronic device acquires an input signal that is a shooting control signal of the camera, the camera is rotated out of the device body from inside the device body in response to the input signal to execute a shooting function of the camera.

17. The method of controlling an electronic device according to claim 15, wherein the functional component further includes a face recognition sensor that rotates out of the device body from inside the device body to perform a face recognition function in response to an input signal when the electronic device acquires the input signal and the input signal is a face recognition signal of the face recognition sensor.

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