CN114382996B - Electronic equipment - Google Patents

Abstract

The embodiment of the application discloses electronic equipment, electronic equipment includes: the electronic equipment comprises a first body, a second body and a first control unit, wherein the first body is used for enabling the electronic equipment to be placed on a bearing surface and is provided with a first supporting surface; the second body is provided with a second supporting surface; the connecting assembly is used for connecting the first body and the second body and at least comprises a first connecting piece arranged on the first supporting surface and a second connecting piece arranged on the second supporting surface; wherein the second body is rotatable and movable relative to the first body or movable relative to the first body by movement of the first and second connectors on the respective second and first support surfaces.

Description

Electronic equipment

Technical Field

The present application relates to an electronic device.

Background

Electronic devices are devices that are often used by people; however, at present, the two bodies of the electronic device can only rotate relatively, so that the electronic device has single use form and poor adaptability.

Disclosure of Invention

In view of this, it is desirable for embodiments of the present application to provide an electronic device.

The technical scheme of the application is realized as follows:

the embodiment of the application provides electronic equipment, which comprises:

The electronic equipment comprises a first body, a second body and a first control unit, wherein the first body is used for enabling the electronic equipment to be placed on a bearing surface and is provided with a first supporting surface;

the second body is provided with a second supporting surface;

the connecting assembly is used for connecting the first body and the second body and at least comprises a first connecting piece arranged on the first supporting surface and a second connecting piece arranged on the second supporting surface;

wherein the second body is rotatable and movable relative to the first body or movable relative to the first body by movement of the first and second connectors on the respective second and first support surfaces.

In some optional implementations, the first supporting surface is provided with a first slideway, and the second supporting surface is provided with a second slideway;

the first end of the first connecting piece is rotatably connected with the first supporting surface, and the second end of the first connecting piece can rotate and/or move in the second slideway, so that the first connecting piece can move on the second supporting surface and/or rotate relative to the second supporting surface;

the first end of the second connecting piece is connected with the second supporting surface, and the second end of the second connecting piece can rotate and/or move in the first slideway, so that the second connecting piece can move on the first supporting surface and/or rotate relative to the first supporting surface.

In some optional implementations, the first connecting piece includes a connecting rod, and a first connecting shaft and a second connecting shaft that are disposed at two ends of the connecting rod, where the first connecting shaft and the second connecting shaft are disposed at two opposite sides of the connecting rod, and one end of the first connecting shaft away from the connecting rod is rotationally connected with the first body, so that the first connecting piece can rotate relative to the first supporting surface with the first connecting shaft as an axis, and one end of the second connecting shaft away from the connecting rod can rotate and/or move in the second slideway;

the second connecting piece comprises a third connecting shaft perpendicular to the second supporting surface, and one end, far away from the second supporting surface, of the third connecting shaft can rotate and/or move in the first slideway.

In some optional implementations, a third slide way is further provided on the first supporting surface, and the connecting rod can rotate in the third slide way with the first connecting shaft as an axis;

the electronic device further comprises an elastic restoring mechanism for providing a force to the first connecting piece to restore the first connecting piece to a first limit position so as to provide an assisting force or a damping force for the first connecting piece in a rotating direction in the rotating process of the first body and the second body.

In some optional implementations, the first supporting surface is further provided with a fourth slideway, the fourth slideway is an arc slideway, the first connecting piece comprises a fourth connecting shaft with a first end limited to rotate and/or move in the arc slideway, and a second end of the fourth connecting shaft can rotate and/or move in the second slideway;

the electronic device further comprises an elastic restoring mechanism for providing a force to the first connecting piece to restore the first connecting piece to a first limit position so as to provide an assisting force or a damping force for the first connecting piece in a rotating direction in the rotating process of the first body and the second body.

In some alternative implementations, the elastic restoring mechanism includes:

the elastic piece is respectively connected with the first connecting piece and the first body;

the elastic piece is deformed in the process that the first connecting piece rotates from the first limit position to the second limit position; in the process that the first connecting piece rotates from the second limit position to the first limit position, the elastic piece provides assistance in the rotation direction for the first connecting piece.

In some alternative implementations, the second body has a first pose and a second pose relative to the first body;

The first slide way is of a strip-shaped structure, the first slide way is arranged along a first direction, the first direction and the height direction of the first body meet the parallel condition, and the first end of the second connecting piece is connected with the center of the second body; and/or the number of the groups of groups,

the second slide way is of a strip-shaped structure, and the length direction and the second direction of the second slide way meet the parallel condition; the second direction is the length direction or the width direction of the second body; or alternatively, the first and second heat exchangers may be,

the second slide includes:

the length direction and the second direction of the first strip-shaped groove meet the parallel condition;

the first end of the second strip-shaped groove is communicated with the first end of the first strip-shaped groove, and the first end of the second strip-shaped groove and the first end of the first strip-shaped groove are close to one end of the second connecting piece;

in the first posture, the first strip-shaped groove and the first slideway meet a parallel condition, and the second body can move relative to the first body through the first strip-shaped groove and the second slideway; in the second posture, the second strip-shaped groove and the first slideway meet the parallel condition, and the second body can move relative to the first body through the second strip-shaped groove and the second slideway.

In some alternative implementations, the electronic device further includes:

and the damping structure is arranged between the second connecting piece and the first body and is used for providing damping force for the second end of the second connecting piece.

In some alternative implementations, the damping structure includes:

friction parts which are arranged on two side walls of the first slideway and are in contact with the second end of the second connecting piece; and/or the number of the groups of groups,

a constant force spring; the first end of the fixed force spring is rotatably arranged on the first body, and the first end of the fixed force spring is positioned on the top side of the first slideway; the second end of the constant force spring is connected with the second connecting piece.

In some alternative implementations of the present invention,

during rotation of the second body relative to the first body, the first end of the first connector rotates and/or moves relative to the first support surface, the second end of the first connector rotates and/or moves within the second slide, and the second end of the second connector rotates and/or moves within the first slide such that the height and angle of the second body relative to the first body varies; or alternatively, the first and second heat exchangers may be,

In the case that the second end of the first connecting piece is located at a first position in the second slideway and the second body rotates relative to the first body, the second end of the first connecting piece rotates and/or moves in the second slideway after moving from the first position to a second position, and the second end of the second connecting piece rotates and/or moves in the first slideway so that the height and angle of the second body relative to the first body change, wherein the first position is different from the first position of the first strip-shaped groove or the first end of the second strip-shaped groove of the second slideway, and the second position is the position of the first strip-shaped groove or the first end of the second strip-shaped groove of the second slideway.

The electronic device in the embodiment of the application comprises: the electronic equipment comprises a first body, a second body and a first control unit, wherein the first body is used for enabling the electronic equipment to be placed on a bearing surface and is provided with a first supporting surface; the second body is provided with a second supporting surface; the connecting assembly is used for connecting the first body and the second body and at least comprises a first connecting piece arranged on the first supporting surface and a second connecting piece arranged on the second supporting surface; wherein the second body is rotatable and movable relative to the first body or movable relative to the first body by movement of the first and second connectors on the respective second and first support surfaces.

Drawings

FIG. 1 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 2 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 3 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 4 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 5 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 6 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

FIG. 7 is a schematic diagram of an alternative configuration of an electronic device according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of an alternative electronic device in an embodiment of the present application.

Reference numerals: 100. a first body; 110. a first support surface; 120. a first slideway; 130. a third slideway; 200. a second body; 210. a second support surface; 220. a second slideway; 221. a first strip-shaped groove; 222. a second strip-shaped groove; 310. a first connector; 311. a first connecting shaft; 312. a second connecting shaft; 313. a connecting rod; 320. a second connector; 410. and a constant force spring.

Detailed Description

The technical scheme of the application is further elaborated below with reference to the drawings in the specification and the specific embodiments.

In the description of the embodiments of the present application, unless otherwise indicated and defined, the term "connected" should be construed broadly, and for example, may be an electrical connection, may be a communication between two elements, may be a direct connection, or may be an indirect connection via an intermediary, and it will be understood by those skilled in the art that the specific meaning of the term may be understood according to the specific circumstances.

It should be noted that, the term "first\second\third" in the embodiments of the present application is merely to distinguish similar objects, and does not represent a specific order for the objects, it is to be understood that "first\second\third" may interchange a specific order or sequence where allowed. It is to be understood that the "first\second\third" distinguishing objects may be interchanged where appropriate such that the embodiments of the present application described herein may be implemented in sequences other than those illustrated or described herein.

The electronic device according to the embodiment of the present application will be described in detail with reference to fig. 1 to 8.

An electronic device includes: the first body 100, the second body 200, and the connection assembly. The first body 100 is used for placing the electronic device on the bearing surface, and the first body 100 is provided with a first supporting surface 110; the second body 200 has a second supporting surface 210; the connecting assembly is used for connecting the first body 100 and the second body 200, and comprises at least a first connecting piece 310 arranged on the first supporting surface 110 and a second connecting piece 320 arranged on the second supporting surface 210; the second body 200 can rotate and move relative to the first body 100 through the movement of the first connecting piece 310 and the second connecting piece 320 on the corresponding second supporting surface 210 and the first supporting surface 110, or move relative to the first body 100, and the second body 200 can rotate and move relative to the first body 100 through the movement of the first connecting piece 310 and the second connecting piece 320 on the corresponding second supporting surface 210 and the first supporting surface 110, so that the use form of the electronic device is greatly increased, and the adaptability of the electronic device is improved.

In the embodiment of the present application, the structure of the electronic device is not limited. For example, the electronic device may be an integrated computer, a television, or a display of a desktop computer.

Here, the second body 200 may have a first posture and a second posture with respect to the first body 100. The form of the first posture and the second posture is not limited. As an example, the first gesture is a landscape gesture and the second gesture is a portrait gesture.

In the embodiment of the present application, the structure of the first body 100 is not limited. For example, the first body 100 may have a block structure. As another example, as shown in fig. 1 and 3, the first body 100 may have a plate-like structure.

Here, the carrying surface may be a tabletop or a ground.

Here, the first support surface 110 refers to a surface of the first body 100 on the side close to the second body 200.

In the embodiment of the present application, the structure of the second body 200 is not limited. For example, the second body 200 may have a block structure. As another example, as shown in fig. 1 and 3, the second body 200 may have a plate-like structure.

Here, the second support surface 210 refers to a surface of the second body 200 near the first body 100 side.

As an example, the first body 100 is a supporting structure, and the second body 200 includes a display device; here, the second body 200 may have a first posture and a second posture with respect to the first body 100. As shown in fig. 1, 2 and 3, the first gesture may be a landscape gesture and the second gesture may be a portrait gesture.

In the embodiment of the present application, the structure of the connection assembly is not limited as long as the connection assembly can connect the first body 100 and the second body 200.

The connection assembly includes at least a first connection member 310 provided at the first support surface 110 and a second connection member 320 provided at the second support surface 210 so as to connect the first body 100 and the second body 200 through the first connection member 310 and the second connection member 320.

Here, the structure of the first connector 310 is not limited. For example, the first connector 310 may have a bar-shaped structure.

Here, the structure of the second connector 320 is not limited. For example, the second connector 320 may have a bar-shaped structure.

The second body 200 can rotate and move relative to the first body 100 or move relative to the first body 100 by the movement of the first and second connectors 310, 320 on the respective second and first support surfaces 210, 110; so that the second body 200 has various postures with respect to the first body 100.

The movement of the first connector 310 and the second connector 320 on the corresponding second supporting surface 210 and the first supporting surface 110 refers to the movement of the first connector 310 on the second supporting surface 210 and the movement of the second connector 320 on the first supporting surface 110.

The first connecting member 310 may be moved on the second supporting surface 210 by rotating the first connecting member 310 on the second supporting surface 210, moving the first connecting member 310 on the second supporting surface 210, or moving and rotating the first connecting member 310 on the second supporting surface 210.

The second connection member 320 may be movable on the first supporting surface 110 by rotating the second connection member 320 on the first supporting surface 110, or by moving and rotating the second connection member 320 on the first supporting surface 110.

The second body 200 can rotate and move relative to the first body 100, and at this time, the second body 200 can change both angle and height relative to the first body 100.

The second body 200 is movable relative to the first body 100, and at this time, the second body 200 can be changed in height relative to the first body 100.

In some optional implementations of the embodiments of the present application, the first supporting surface 110 is provided with a first slideway 120, and the second supporting surface 210 is provided with a second slideway 220; a first end of the first connecting member 310 is rotatably connected to the first supporting surface 110; the second end of the first link 310 is rotatable and/or movable within the second slide 220 such that the first link 310 is movable on the second support surface 210 and/or rotatable relative to the second support surface 210; the first end of the second connecting member 320 is connected to the second supporting surface 210; the second end of the second link 320 is rotatable and/or movable within the first slide 120 such that the second link 320 is movable on the first support surface 110 and/or rotatable relative to the first support surface 110; the first link 310 can be smoothly moved on the second support surface 210 and/or smoothly rotated with respect to the second support surface 210 by the first slide 120, and the second link 320 can be smoothly moved on the first support surface 110 and/or smoothly rotated with respect to the first support surface 110 by the second slide 220.

In this implementation manner, during the rotation of the second body 200 relative to the first body 100, the second body 200 drives the second slide way 220 to rotate, the first end of the first connecting member 310 rotates and/or moves relative to the first supporting surface 110, during the rotation of the second slide way 220, the second end of the first connecting member 310 rotates and/or moves in the second slide way 220, and the second end of the second connecting member 320 rotates and/or moves in the first slide way 120, so that the height and angle of the second body 200 relative to the first body 100 change.

In this implementation manner, during the movement of the second body 200 relative to the first body 100, the second body 200 drives the second slide way 220 and the second connecting member 320 to move, the second end of the first connecting member 310 moves in the second slide way 220, and the second end of the second connecting member 320 moves in the first slide way 120, so that the height of the second body 200 relative to the first body 100 is changed.

In the present embodiment, the structure of the first connector 310 is not limited. For example, the first connector 310 may be a rod-like structure.

In the present embodiment, the structure of the second connector 320 is not limited. For example, the second connector 320 may be a rod-like structure.

Here, the connection position of the first end of the second connector 320 and the second body 200 is not limited. For example, the first end of the second connector 320 is connected with the center of the second body 200.

In this implementation manner, the second end of the first connecting piece 310 may further be provided with a first clamping portion, and the second slide way 220 may be provided with a first clamping groove therein, where the first clamping portion is clamped in the first clamping groove, so as to prevent the second end of the first connecting piece 310 from being separated from the second slide way 220; here, the first engaging portion and the first engaging groove are not limited in shape. For example, the first clamping portion and the second end of the first connecting member 310 form a T-shaped structure, and the first clamping groove and the second slideway 220 form a T-shaped structure.

In this implementation manner, the second end of the second connecting piece 320 may further be provided with a second clamping portion, and the first slideway 120 may be provided with a second clamping groove, where the second clamping portion is clamped in the second clamping groove, so as to prevent the second end of the second connecting piece 320 from being separated from the first slideway 120; here, the shapes of the second engaging portion and the second engaging groove are not limited. For example, the second clamping portion and the second end of the second connector 320 form a T-shaped structure, and the second clamping groove and the first slideway 120 form a T-shaped structure.

As shown in fig. 4, the first connecting member 310 includes a connecting rod 313, and a first connecting shaft 311 and a second connecting shaft 312 disposed at two ends of the connecting rod 313, where the first connecting shaft 311 and the second connecting shaft 312 are disposed at two opposite sides of the connecting rod 313, one end of the first connecting shaft 311 away from the connecting rod 313 is rotatably connected with the first body 100, so that the first connecting member 310 can rotate relative to the first supporting surface 110 with the first connecting shaft 311 as an axis, and one end of the second connecting shaft 312 away from the connecting rod 313 can rotate and/or move in the second slideway 220; the second connecting member 320 includes a third connecting shaft disposed perpendicular to the second supporting surface 210, and an end of the third connecting shaft away from the second supporting surface 210 can rotate and/or move in the first sliding way 120.

In example one, the cross-sectional shape of the connection rod 313 is not limited. For example, the cross-sectional shape of the link 313 may be rectangular, square, or circular.

In an example one, an end of the first connecting shaft 311 away from the connecting rod 313 is rotatably connected to the first body 100, so that the first connecting member 310 can rotate relative to the first supporting surface 110 about the first connecting shaft 311. In other examples, an end of the first connecting shaft 311 away from the connecting rod 313 may be fixedly connected to the first body 100, and the first connecting shaft 311 may be rotatably connected to the connecting rod 313, so as to enable the end of the connecting rod 313 to rotate relative to the first body 100 through the first connecting shaft 311. Of course, the first connection shaft 311 may be rotatably connected to one end of the connection rod 313 and the first body 100, respectively.

In the first example, an end of the second connecting shaft 312 away from the connecting rod 313 may be inserted into the second slide way 220, and the second connecting shaft 312 may rotate in the second slide way 220, may move in the second slide way 220, and may also rotate and move in the second slide way 220.

Here, the second connecting shaft 312 may be fixedly connected to the connecting rod 313, and at this time, an end of the second connecting shaft 312 away from the connecting rod 313 may be movable in the second slide 220, and the second slide 220 may rotate in the second slide 220 as the second body 200 rotates relative to the first body 100, so that the end of the second connecting shaft 312 away from the connecting rod 313 rotates. Of course, the second connecting shaft 312 may be rotatably connected to the connecting rod 313, and at this time, an end of the second connecting shaft 312 away from the connecting rod 313 may be movable, rotatable, movable and rotatable in the second slideway 220.

In an example one, an end of the third connecting shaft away from the second supporting surface 210 may be inserted into the first sliding way 120, and an end of the third connecting shaft away from the second supporting surface 210 may rotate in the first sliding way 120, may move in a sliding way, and may also rotate and move in the first sliding way 120.

In an example one, the third connecting shaft may be fixedly connected to the second body 200, where an end of the third connecting shaft away from the second supporting surface 210 is capable of moving in the first sliding way 120, and the third connecting shaft rotates in the first sliding way 120 along with the rotation of the second body 200 relative to the first body 100, so that an end of the third connecting shaft away from the second supporting surface 210 rotates in the first sliding way 120. Of course, the third connecting shaft may be rotatably connected to the second body 200, and at this time, an end of the third connecting shaft away from the second supporting surface 210 may move, rotate, and both move and rotate in the first slideway 120.

In the first example, in the case that the second body 200 has the first posture and the second posture with respect to the first body 100, as shown in fig. 4, the second body 200 is in the first posture with respect to the first body 100, and in the process that the second body 200 rotates in the second posture of fig. 6 in the third direction with respect to the first body 100 under the action of the external force, the second slide way 220 rotates along with the second body 200, the second slide way 220 drives the second connecting shaft 312 to move and rotate in the second slide way 220, and the second connecting shaft 312 drives the connecting rod 313 to rotate in the fourth direction with respect to the first body 100; the end of the third connecting shaft away from the second supporting surface 210 rotates and moves in the first slideway 120, and the height and angle of the second body 200 relative to the first body 100 change; wherein the third direction and the fourth direction are opposite; here, the angle through which the second body 200 rotates relative to the first body 100 may be 90 degrees, and at the same time, as shown in fig. 4 and 6, the position of the end of the third connecting shaft away from the second supporting surface 210 in the first slideway 120 also changes, at this time, the height of the second body 200 relative to the first body 100 changes, and as an example, the height of the second body 200 relative to the first body 100 increases, so that in the case that the second body 200 has the second posture relative to the first body 100, the second body 200 is prevented from abutting against the bearing surface.

Of course, the second body 200 can also rotate from the second posture of fig. 6 to the first posture of fig. 4 relative to the first body 100, and the process of rotating the second body 200 from the second posture of fig. 6 to the first posture of fig. 4 relative to the first body 100 is similar to the process of rotating the second body 200 from the first posture of fig. 4 to the second posture of fig. 6 relative to the first body 100, and will not be repeated here.

In an example one, the first supporting surface 110 may further be provided with a third slide way 130, and the connecting rod 313 may rotate in the third slide way 130 with the first connecting shaft 311 as an axis; so as to reduce the installation space of the connecting rod 313 on the first support surface 110. Here, the shape of the third slide 130 is not limited. For example, the link 313 can rotate from the first limit position to the second limit position with the first connecting shaft 311 as an axis; the third slide 130 may be shaped by the link 313 rotating between the first limit position and the second limit position.

Of course, the first connector 310 may be provided in other configurations.

For example, the first connecting member 310 has a strip structure, and opposite sides of two ends of the first connecting member 310 may be provided with a first protrusion and a second protrusion, where the first protrusion is inserted into the circular hole of the first supporting surface 110, and the second protrusion is inserted into the second slideway 220.

For another example, the first supporting surface 110 is further provided with a fourth sliding way, the fourth sliding way is an arc sliding way, the first connecting piece 310 includes a fourth connecting shaft with a first end limited to rotate and/or move in the arc sliding way, and a second end of the fourth connecting shaft can rotate and/or move in the second sliding way.

In this example, the first end of the fourth connecting shaft may move within the fourth slide, may rotate within the fourth slide, and may also move and rotate within the fourth slide.

In this example, the second end of the fourth connecting shaft may move within the second slide, may rotate within the second slide, and may also move and rotate within the second slide.

In this example, the fourth connecting shaft is similar to the second connecting shaft 312 in the first example described above, where the fourth connecting shaft rotates relative to the first body 100 with the center of the arc-shaped slide as the axis by moving in the arc-shaped slide, and the center of the arc-shaped slide is similar to the first connecting shaft 311 in the first example described above.

In the present embodiment, the first connector 310 is rotatable relative to the first body 100 between a first limit position and a second limit position. With the second body 200 in the first posture, the first connector 310 may be in the first extreme position, as shown in fig. 4 and 5; with the second body 200 in the second posture, the first connector 310 may be in the second extreme position, as shown in fig. 6 and 7.

The electronic device may further include an elastic restoring mechanism for providing a force to the first connector 310 to restore it to the first limit position, so as to provide an assistance or damping force to the first connector 310 in a rotation direction during the rotation of the first body 100 and the second body 200; when the second body 200 rotates from the first posture to the second posture relative to the first body 100, the elastic restoring mechanism deforms to provide a damping force for the rotation of the second body 200 relative to the first body 100; when the second body 200 rotates from the second posture to the first posture relative to the first body 100, the elastic restoring mechanism provides assistance for the rotation of the second body 200 relative to the first body 100 through the deformation force, so as to prevent the second body 200 from being jammed during the rotation process relative to the first body 100.

Here, the structure of the elastic restoring mechanism is not limited. For example, the elastic restoring mechanism may include: elastic members respectively connected with the first connecting member 310 and the first body 100; the elastic member is deformed during the rotation of the first connecting member 310 from the first limit position to the second limit position; in the process of rotating the first connecting member 310 from the second limit position to the first limit position, the elastic member provides an assistance force for the first connecting member 310 in the rotation direction.

The structure of the elastic member is not limited. For example, the elastic member may be a spring or a rubber string.

The arrangement of the elastic member is not limited. For example, a first end of the elastic member may be fixed to the first supporting surface 110, and a second end of the elastic member may be fixedly coupled with a middle portion of the first coupling member 310. As an example, the elastic member is a rubber rope, the first supporting surface 110 is provided with a first convex column, the surface of the first connecting member 310 is provided with a second convex column, and two ends of the rubber rope are sleeved outside the first convex column and the second convex column; here, in order to increase the length of the rubber string, the first support surface 110 may be further provided with an annular wire-arranging groove in which the middle portion of the rubber string is located.

In the present embodiment, the shape of the first slide 120 is not limited. For example, as shown in fig. 3 and 4, the first slide 120 may have a strip-like structure.

Here, the first slide 120 may be disposed along a first direction; wherein the first direction and the height direction of the first body 100 satisfy a parallel condition, so that the height of the second body 200 can be changed along the first slideway 120 relative to the first body 100. The parallel condition refers to parallel or substantially parallel.

In the present embodiment, the shape of the second slideway 220 is not limited.

For example, the second slide way 220 may have a strip structure, and the length direction of the second slide way 220 and the second direction satisfy a parallel condition; the second direction may be a longitudinal direction of the second body 200 or a width direction of the second body 200; the parallel condition refers to parallel or substantially parallel.

As an example, as shown in fig. 1, the second slideway 220 may have a strip structure, and the second direction is the width direction of the second body 200; the second body 200 is in the first posture, the second slide way 220 and the first slide way 120 may satisfy the parallel condition, and the second body 200 may move relative to the first body 100 through the second slide way 220 and the first slide way 120, at this time, the posture of the second body 200 relative to the first body 100 is unchanged, the angle is unchanged, but the height of the second body 200 relative to the first body 100 is changed.

It should be noted that, in the first posture, as shown in fig. 5, in the case that the first connecting member 310 is located at the first end of the non-second slideway 220, during the rotation of the second body 200 relative to the first body 100, the second end of the first connecting member 310 rotates and/or moves in the second slideway 220 after moving to the first end of the second slideway 220, the first end of the first connecting member 310 rotates relative to the first supporting surface, and the second end of the second connecting member 320 rotates and/or moves in the first slideway 120, so that the height and the angle of the second body 200 relative to the first body 100 change; here, during the rotation of the second body 200 relative to the first body 100, the second body 200 moves from the state of fig. 5 to the state of fig. 4 relative to the first body 100 and then rotates; at this time, the second body 200 is rotated after being at the lowest position in the height direction with respect to the first body 100.

Here, the first end of the second slideway 220 refers to the second slideway 220 being adjacent to the first end of the second connector.

Here, in the first posture, as shown in fig. 4, in the case that the first link 310 is located at the first end of the second slideway 220, the second end of the first link 310 receives a downward force but cannot move upward due to the structural limitation, so that a reaction force is generated to push the second body 200 to rotate around the second end of the first link 310, and at the same time, the second end of the second link 320 rotates and moves in the first slideway 120, so that the height and angle of the second body 200 with respect to the first body 100 are changed; meanwhile, in the process of rotating the second body 200 relative to the first body 100, the thrust action of the side surface of the second slideway 220 on the second body 200 against the first end of the second connector 320 makes the second connector 320 rotate in coordination with the rotation of the second body 200 and rotate around the first end of the second connector 320, and the second connector 320 moves from the first limit position to the second limit position when the second body 200 moves to the second posture, as shown in fig. 6; the height of the second body 200 relative to the first body 100 increases, so as to avoid the second body 200 touching the bearing surface during rotation.

For another example, the second slideway 220 may include: a first bar groove 221 and a second bar groove 222. The length direction and the second direction of the first bar groove 221 satisfy the parallel condition; the second strip groove 222 and the first strip groove 221 meet a vertical condition; the first end of the second bar groove 222 communicates with the first end of the first bar groove 221 so that the second bar groove 222 and the first bar groove 221 communicate at the end side.

In this example, the first end of the second bar groove 222 and the first end of the first bar groove 221 are ends near the second connector 320.

In this example, the second direction has been described above, and will not be described here again.

In this example, the vertical condition refers to vertical or substantially vertical.

In this example, as shown in fig. 5, in the first posture, the first bar groove 221 and the first slideway 120 may satisfy a parallel condition, and the second body 200 may be movable with respect to the first body 100 through the first bar groove 221 and the second slideway 220; as shown in fig. 7, in the second posture, the second bar-shaped groove 222 and the first slideway 120 satisfy a parallel condition, and the second body 200 is movable relative to the first body 100 through the second bar-shaped groove 222 and the second slideway 220, so that the second body 200 can be moved relative to the first body 100 in both the first posture and the second posture to change the height of the second body 200 relative to the first body 100.

In the case that the second end of the first link 310 is located at a first position in the second slideway 220 and the second body 200 is rotated relative to the first body, the second end of the first link 310 rotates and/or moves in the second slideway 220 after moving from the first position to a second position, the second end of the second link 320 rotates and/or moves in the first slideway 120 such that the height and angle of the second body 200 relative to the first body 100 is changed, the first position is different from the position of the first end of the first or second bar slot 221, 222 of the second slideway 220, and the second position is the position of the first end of the first or second bar slot 221, 222 of the second slideway 220.

In the first posture, when the second end of the first connector 310 is located at the first position of the first bar slot and the second body 200 rotates relative to the first body 100, the second end of the first connector 310 rotates and moves in the first bar slot after moving from the first position to the first end of the first bar slot, the first end of the first connector 310 rotates relative to the first supporting surface 110, and the second end of the second connector 320 rotates and moves in the first slideway, so that the height and angle of the second body 200 relative to the first body 100 change.

In the second posture, the second end of the first connector 310 is located at the first position of the second bar slot, and when the second body 200 rotates relative to the first body 100, the second end of the first connector 310 rotates and moves in the second bar slot after moving from the first position to the first end of the second bar slot, the first end of the first connector 310 rotates relative to the first supporting surface 110, and the second end of the second connector 320 rotates and moves in the first slideway, so that the height and angle of the second body 200 relative to the first body 100 change.

In this implementation manner, the electronic device may further include: the damping structure is disposed between the second connector 320 and the first body 100, and is used for providing a damping force to the second end of the second connector 320, so as to prevent the second body 200 from damaging the connection assembly or affecting the movement of the connection assembly due to the heavy weight.

Here, the structure of the damping structure is not limited.

For example, the damping structure may include friction parts disposed on two sidewalls of the first sliding track 120, and the friction parts are abutted against the second ends of the second connectors 320 to provide damping force to the second ends of the second connectors 320, so as to prevent the second ends of the second connectors 320 from moving along the first sliding track 120 under the gravity action of the second body 200.

Here, the friction portion may be friction protrusions provided on both side walls of the first slide 120, or may be a rough surface provided on both side walls of the first slide 120.

As another example, as shown in fig. 8, the damping structure may include: a constant force spring 410; the first end of the fixed force spring 410 is rotatably disposed on the first body 100, and the first end of the fixed force spring 410 is located on the top side of the first slideway 120; the second end of the constant force spring 410 is connected to the second connector 320 so as to provide a damping force to the second connector 320 through the constant force spring 410.

Here, the deformation force of the constant force spring 410 may be the same as the gravity of the second body 200 so that the second link 320 can smoothly move in the first slideway 120 in the non-pressure state by counteracting the gravity of the second body 200 by the deformation force of the constant force spring 410.

Of course, the damping structure may also include both the friction portion and the constant force spring 410.

It should be noted that, in fig. 3, in order to facilitate the visual inspection of the structure of the connection assembly, the first body 100 is subjected to transparent treatment, which does not represent that the first body 100 is a transparent structure; in fig. 4 and 6, in order to facilitate the visual inspection of the structure of the connection assembly, the second body 200 is transparent, which does not represent the transparent structure of the second body 200.

The electronic device of the embodiment of the application comprises: a first body 100 for placing an electronic device on a carrying surface, the first body 100 having a first supporting surface 110; the second body 200 has a second supporting surface 210; a connection assembly for connecting the first body 100 and the second body 200, at least comprising a first connection member 310 disposed on the first supporting surface 110 and a second connection member 320 disposed on the second supporting surface 210; wherein the second body 200 is capable of rotating and moving relative to the first body 100 or moving relative to the first body 100 by the movement of the first and second connectors 310, 320 on the corresponding second and first support surfaces 210, 110; the second body 200 can not only rotate and move relative to the first body 100, but also move relative to the first body 100 through the movement of the first connecting piece 310 and the second connecting piece 320 on the corresponding second supporting surface 210 and first supporting surface 110, so that the use form of the electronic device is greatly increased, and the adaptability of the electronic device is improved.

The foregoing is merely specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and the changes and substitutions are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. An electronic device, comprising:

the electronic equipment comprises a first body, a second body and a first control unit, wherein the first body is used for enabling the electronic equipment to be placed on a bearing surface and is provided with a first supporting surface;

the second body is provided with a second supporting surface;

the connecting assembly is used for connecting the first body and the second body and at least comprises a first connecting piece arranged on the first supporting surface and a second connecting piece arranged on the second supporting surface;

wherein the second body can rotate and move relative to the first body or move relative to the first body by the movement of the first connecting piece on the second supporting surface and the movement of the second connecting piece on the first supporting surface;

the first supporting surface is provided with a first slideway, and the second supporting surface is provided with a second slideway;

the first end of the first connecting piece is rotatably connected with the first supporting surface, and the second end of the first connecting piece can rotate and move in the second slideway, so that the first connecting piece can move on the second supporting surface and rotate relative to the second supporting surface;

the first end of the second connecting piece is connected with the second supporting surface, and the second end of the second connecting piece can rotate and move in the first slideway, so that the second connecting piece can move on the first supporting surface and rotate relative to the first supporting surface.

2. The electronic device according to claim 1,

the first end of the first connecting piece is rotationally connected with the first supporting surface, and the second end of the first connecting piece can move in the second slideway, so that the first connecting piece can move on the second supporting surface; the first end of the second connecting piece is connected with the second supporting surface, and the second end of the second connecting piece can move in the first slideway, so that the second connecting piece can move on the first supporting surface.

3. The electronic device of claim 2, wherein the first connecting piece comprises a connecting rod, and a first connecting shaft and a second connecting shaft which are arranged at two ends of the connecting rod, the first connecting shaft and the second connecting shaft are arranged at two opposite sides of the connecting rod, one end of the first connecting shaft away from the connecting rod is rotatably connected with the first body, so that the first connecting piece can rotate relative to the first supporting surface by taking the first connecting shaft as an axis, and one end of the second connecting shaft away from the connecting rod can rotate and move in the second slideway or move in the second slideway;

the second connecting piece comprises a third connecting shaft perpendicular to the second supporting surface, and one end, far away from the second supporting surface, of the third connecting shaft can rotate and move in the first slideway or move in the first slideway.

4. The electronic device of claim 3, wherein the first supporting surface is further provided with a third slide way, and the connecting rod can rotate in the third slide way by taking the first connecting shaft as an axis;

the electronic device further comprises an elastic restoring mechanism for providing a force to the first connecting piece to restore the first connecting piece to a first limit position so as to provide an assisting force or a damping force for the first connecting piece in a rotating direction in the rotating process of the first body and the second body.

5. The electronic device of claim 2, wherein the first supporting surface is further provided with a fourth slideway, the fourth slideway is an arc slideway, the first connecting piece comprises a fourth connecting shaft with a first end limited to rotate and/or move in the arc slideway, and a second end of the fourth connecting shaft can rotate and/or move in the second slideway;

the electronic device further comprises an elastic restoring mechanism for providing a force to the first connecting piece to restore the first connecting piece to a first limit position so as to provide an assisting force or a damping force for the first connecting piece in a rotating direction in the rotating process of the first body and the second body.

6. The electronic device of claim 4 or 5, wherein the elastic return mechanism comprises:

The elastic piece is respectively connected with the first connecting piece and the first body;

the elastic piece is deformed in the process that the first connecting piece rotates from the first limit position to the second limit position; in the process that the first connecting piece rotates from the second limit position to the first limit position, the elastic piece provides assistance in the rotation direction for the first connecting piece.

7. The electronic device of claim 2, the second body having a first pose and a second pose relative to the first body;

the first slide way is of a strip-shaped structure, the first slide way is arranged along a first direction, the first direction and the height direction of the first body meet the parallel condition, and the first end of the second connecting piece is connected with the center of the second body; and/or the number of the groups of groups,

the second slide way is of a strip-shaped structure, and the length direction and the second direction of the second slide way meet the parallel condition; the second direction is the length direction or the width direction of the second body; or alternatively, the first and second heat exchangers may be,

the second slide includes:

the length direction and the second direction of the first strip-shaped groove meet the parallel condition;

the first end of the second strip-shaped groove is communicated with the first end of the first strip-shaped groove, and the first end of the second strip-shaped groove and the first end of the first strip-shaped groove are close to one end of the second connecting piece;

In the first posture, the first strip-shaped groove and the first slideway meet a parallel condition, and the second body can move relative to the first body through the first strip-shaped groove and the first slideway; in the second posture, the second strip-shaped groove and the first slideway meet the parallel condition, and the second body can move relative to the first body through the second strip-shaped groove and the first slideway.

8. The electronic device of claim 2, the electronic device further comprising:

and the damping structure is arranged between the second connecting piece and the first body and is used for providing damping force for the second end of the second connecting piece.

9. The electronic device of claim 8, the damping structure comprising:

friction parts which are arranged on two side walls of the first slideway and are in contact with the second end of the second connecting piece; and/or the number of the groups of groups,

a constant force spring; the first end of the fixed force spring is rotatably arranged on the first body, and the first end of the fixed force spring is positioned on the top side of the first slideway; the second end of the constant force spring is connected with the second connecting piece.

10. The electronic device according to any one of claim 2 to 5,7 to 9,

During rotation of the second body relative to the first body, the first end of the first connector rotates and/or moves relative to the first support surface, the second end of the first connector rotates and/or moves within the second slide, and the second end of the second connector rotates and/or moves within the first slide such that the height and angle of the second body relative to the first body varies; or alternatively, the first and second heat exchangers may be,

in the case that the second end of the first connecting piece is located at a first position in the second slideway and the second body rotates relative to the first body, the second end of the first connecting piece rotates and/or moves in the second slideway after moving from the first position to a second position, and the second end of the second connecting piece rotates and/or moves in the first slideway so that the height and angle of the second body relative to the first body change, wherein the first position is different from the first position of the first strip-shaped groove or the first end of the second strip-shaped groove of the second slideway, and the second position is the position of the first strip-shaped groove or the first end of the second strip-shaped groove of the second slideway.