CN110133989B

CN110133989B - Intelligent host computer and intelligent wrist-watch of upset are slided to realization side direction

Info

Publication number: CN110133989B
Application number: CN201811152711.5A
Authority: CN
Inventors: 金祖涛; 齐磊; 罗楠
Original assignee: Guangdong Genius Technology Co Ltd
Current assignee: Guangdong Genius Technology Co Ltd
Priority date: 2018-09-29
Filing date: 2018-09-29
Publication date: 2023-11-24
Anticipated expiration: 2038-09-29
Also published as: CN110133989A

Abstract

The invention relates to the technical field of intelligent watches, and particularly discloses an intelligent host for realizing lateral sliding and overturning. By adopting the design, a user can turn the main machine body into different using postures relative to the chassis bracket according to different using requirements, so that the function use of the intelligent watch is greatly optimized. In addition, the invention also discloses an intelligent watch with the intelligent host.

Description

Intelligent host computer and intelligent wrist-watch of upset are slided to realization side direction

Technical Field

The invention relates to the technical field of intelligent watches, in particular to an intelligent host machine for realizing lateral sliding and overturning and an intelligent watch.

Background

The traditional watch is mainly a simple watch with a single dial plate, along with the gradual enrichment of watch functions, watches with the dial plate capable of being lifted relative to the watchband appear on the market so as to better realize multifunction of the watch, however, the design mode is that the dial plate is lifted relative to the watchband to form different angles or the dial plate is in a reconnection state with the watchband is manually kept by a user, so that the watch is troublesome to use, and the user experience is not high.

Disclosure of Invention

The embodiment of the invention discloses an intelligent host and an intelligent watch for realizing lateral sliding and overturning, which are characterized in that a holding structure is arranged to enable a host body to overturn relative to a chassis bracket and keep different postures so as to meet different use requirements of users.

In order to achieve the above object, in a first aspect, an embodiment of the present invention discloses an intelligent host for implementing lateral slipping rollover, including:

the chassis support comprises two first opposite sides, the two first opposite sides are respectively provided with a sliding rail, and the sliding rail is provided with a first preset position and a second preset position;

the host machine body is provided with rotary connecting parts corresponding to the two sliding rails, and the two rotary connecting parts are respectively connected with the corresponding sliding rails in a matching way;

when the rotary connecting part is positioned at the first preset position or the second preset position, the host body can turn over relative to the chassis bracket so that the host body has different postures relative to the chassis bracket; and

and a holding structure arranged to connect the host body and the chassis support, the holding structure being for providing a force to hold the host body in the different positions relative to the chassis support.

As an alternative implementation manner, in an embodiment of the first aspect of the present invention, the different postures include at least a first posture and a second posture, the holding structure includes a first holding structure and a second holding structure, the first holding structure is used for providing a force for keeping the main body in the first posture relative to the chassis bracket, and the second holding structure is used for providing a force for keeping the chassis bracket in the second posture;

the first gesture is a gesture that the host computer body is stacked on the chassis support, and the second gesture is a gesture that the host computer body is inclined or vertical relative to the chassis support.

As an alternative implementation manner, in an embodiment of the first aspect of the present invention, the second holding structure is provided at the first preset position of the chassis support;

the host body comprises two second opposite sides, the two second opposite sides can slide relative to the two first opposite sides, the second opposite sides are provided with first positions, and the first fixing structure is arranged at the first positions.

As an optional implementation manner, in an embodiment of the first aspect of the present invention, two second opposite sides of the host body further have a second position spaced from the first position, and the rotation connection portion is disposed at the second position;

The second fixing structure is used for being connected with the rotary connecting part when the rotary connecting part slides to the first preset position and turns over, so that the host body keeps the second posture relative to the chassis bracket.

As an optional implementation manner, in an embodiment of the first aspect of the present invention, the first holding structure includes a first fastener and a first elastic member, where the first fastener includes a fastening portion and a connecting portion, and the first elastic member is connected between the fastening portion and the connecting portion, and is used to provide a force for fastening the fastening portion and the chassis support.

As an alternative embodiment, in an embodiment of the first aspect of the present invention, the second holding structure includes a fixing member and a second elastic member, where the second elastic member is configured to be connected to the fixing member, and is configured to provide a force for the fixing member to abut against the rotating connection portion.

In an optional implementation manner, in an embodiment of the first aspect of the present invention, the rotary connection portion is at least provided with a first limiting surface and a second limiting surface that are disposed at an angle, and the fixing piece is configured to abut against the first limiting surface and/or the second limiting surface when the rotary connection portion turns relative to the chassis support, so that the host body forms different angles relative to the chassis support.

As an alternative implementation manner, in an embodiment of the first aspect of the present invention, the sliding rail includes a first end portion and a second end portion that are disposed opposite to each other, where the first end portion and the second end portion are provided with a first clamping groove and a second clamping groove, the first clamping groove forms the first preset position, and the second clamping groove forms the second preset position.

As an optional implementation manner, in an embodiment of the first aspect of the present invention, the different poses include at least a first pose, a second pose, and a third pose;

when the rotary connecting part is positioned at the second preset position, the host body overturns relative to the chassis bracket, so that the host body overturns from the first posture to the second posture relative to the chassis bracket;

when the rotary connecting part slides from the second preset position to the first preset position, the host body overturns relative to the chassis bracket so that the host body overturns relative to the chassis bracket from the first posture to the second posture, and when the host body is positioned in the second posture, the host body can overturns relative to the chassis bracket again so that the host body overturns from the second posture to the third posture;

The third gesture is a gesture that the host computer body is stacked on the chassis support, and the host computer body is located when the third gesture, the orientation of the display surface that is used for showing of host computer body is reverse with the orientation of the display surface that the host computer body is located the first gesture.

In an alternative embodiment, in an embodiment of the first aspect of the present invention, the chassis support includes a bottom plate and two side plates connected to two sides of the bottom plate and forming the two first opposite sides, and the two side plates are separately provided with the sliding rails.

In an optional implementation manner, in an embodiment of the first aspect of the present invention, the side plate is convexly provided with a boss, the chassis support further includes a fixing plate, the fixing plate is disposed on the side plate, the fixing plate is opposite to the boss and is disposed at a distance, and the sliding rail is formed between the fixing plate and the boss.

In an alternative embodiment, in an embodiment of the first aspect of the present invention, the host body includes a host housing having a receiving cavity, and a cover embedded with a display screen and connected to the host housing, where the display surface covers an opening of the receiving cavity of the host housing.

In an optional implementation manner, in an embodiment of the first aspect of the present invention, the host body is provided with a camera module, the camera module includes a front camera module and a rear camera module, a view direction of the front camera module is set in the same direction as the display surface, and a view direction of the rear camera module is set in the same direction as the non-display surface, where the non-display surface is opposite to the display surface.

As an optional implementation manner, in an embodiment of the first aspect of the present invention, a projection position of the rear camera module on the display surface corresponds to a projection position of the front camera module on the display surface.

In a second aspect, the embodiment of the invention also discloses an intelligent host for realizing lateral sliding and overturning, which comprises the following steps:

the main body can be connected to the sliding rail of the chassis bracket in a sliding manner, and can turn over relative to the chassis bracket when sliding to the first preset position along the second preset position on the sliding rail and/or sliding to the second preset position from the first preset position, so that the main body has different postures relative to the chassis bracket; and

In a third aspect, the present invention further provides a smart watch, the smart watch including a watchband and a smart host for implementing lateral sliding and turning as described in the first aspect, the watchband being connected to the two first opposite sides of the chassis support; or alternatively

The smart watch comprises a watchband and the smart host for realizing lateral sliding and overturning according to the second aspect, wherein the watchband is connected to the two first opposite sides of the chassis bracket.

Compared with the prior art, the intelligent host for realizing the lateral sliding and overturning and the intelligent watch have the following beneficial effects:

according to the intelligent host and the intelligent watch for realizing the lateral sliding and overturning, the fixing structure for connecting the host body and the chassis support is arranged in the intelligent host, and the fixing structure is utilized to provide acting forces for keeping the host body in different postures relative to the chassis support for the intelligent host, so that the host body can keep different postures relative to the chassis support. By adopting the mode, a user can turn the main machine body into different using postures relative to the chassis bracket according to different using requirements, so that the function use of the intelligent watch is greatly optimized.

When the photographing or code scanning function is required to be used, the host body can be slid to a designated position and turned to an angle suitable for photographing, the fixing structure can enable the host body to keep the turned posture, and the photographing module can be aligned to the direction required by a user to photograph or scan codes, so that the inconvenience caused by the fact that the traditional intelligent watch can only photograph a fixed direction or twist an arm to adjust the photographing angle, scan the code direction and the like and is not flexible is solved. And because of setting up the dual camera module that has leading camera module and rearmounted camera module, can enrich and shoot the function to can satisfy the user in different occasions, the different shooting demands under the different sight, this can greatly improve user's use experience to intelligent wrist-watch.

In addition, when the functions of video, communication and the like with larger heating value are used, the fixing structure can enable the host body to be inclined/vertical relative to the chassis support, so that the heating source can not directly contact skin, and meanwhile, the rapid heat dissipation of the host body is facilitated, and the overall heat dissipation effect is improved. When a user does not need to use the intelligent host, the fixing structure can enable the intelligent host to keep the state that the host body is overlapped on the chassis support and the display surface of the host body faces the chassis support, so that the display surface is not arranged upwards any more, the display surface can be protected, and the risk of scratching or breaking the screen is reduced.

Drawings

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

Fig. 1 is a schematic diagram of a host body of a smart host in a first posture according to a second embodiment of the present invention;

fig. 2 is a schematic structural diagram of a host body of an intelligent host according to a second embodiment of the present invention turning over to a second position at a second preset position;

fig. 3 is a schematic structural diagram of a host body of an intelligent host according to a second embodiment of the present invention sliding to a first preset position;

fig. 4 is a schematic diagram of a host body of an intelligent host according to a second embodiment of the present invention turning over to a second position at a first preset position;

fig. 5 is a schematic structural view of a slide rail on an opposite side of a chassis bracket of a smart host disclosed in a second embodiment of the present invention;

fig. 6 is a schematic structural diagram of a first holding structure of an intelligent host according to a second embodiment of the present invention, where the first holding structure holds a host body in a first posture relative to a chassis bracket;

Fig. 7 is a schematic structural diagram of a first holding structure of a smart host according to a second embodiment of the present invention;

fig. 8 is a schematic structural diagram of a rotary connection portion of an intelligent host according to a second embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a second holding structure of a smart host according to a second embodiment of the present invention;

fig. 10 is a schematic structural diagram of a chassis support of a smart host disclosed in the second embodiment of the present invention;

FIG. 11 is a schematic diagram of a host body of a smart host in a third posture according to a second embodiment of the present invention;

fig. 12 is a schematic structural diagram of a host body of an intelligent host according to the second embodiment of the present invention sliding from a third posture to a second preset position;

fig. 13 is a schematic diagram of a host body of an intelligent host according to the second embodiment of the present invention turned from a third posture to a second posture;

fig. 14 is a schematic structural diagram of a host body of a smart host according to a second embodiment of the present invention;

fig. 15 is a schematic structural diagram of a camera module when a host body disclosed in the third embodiment of the present invention is located in a first posture;

fig. 16 is a schematic structural diagram of a host body of a smart host according to the third embodiment of the present invention sliding to a first preset position;

FIG. 17 is a schematic diagram of a camera module when the host body disclosed in the third embodiment of the present invention is in the second posture;

FIG. 18 is a schematic diagram of a camera module when a host body of the smart host disclosed in the third embodiment of the present invention is in a third posture;

fig. 19 is a schematic structural diagram of a host body of the smart host according to the third embodiment of the present invention sliding from a third posture to a second preset position;

FIG. 20 is a schematic diagram of a host body of an intelligent host according to the third embodiment of the present invention being flipped from a third posture to a second posture;

fig. 21 is a schematic structural diagram of a smart watch according to a fifth embodiment of the present invention in a first posture;

fig. 22 is a schematic structural diagram of a main body of a smart watch according to a fifth embodiment of the present invention turned over at a first preset position to be located in a second posture;

fig. 23 is a schematic structural diagram of a host body of a smart watch according to a fifth embodiment of the present invention turned over at a second preset position to be located in a second posture.

Detailed Description

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

It should be noted that the terms "comprises" and "comprising," along with any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed or inherent to such process, method, article, or apparatus, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The embodiment of the invention discloses an intelligent host for realizing lateral sliding and overturning, which can enable a host body to overturn relative to a chassis bracket and keep different postures by arranging a fixing structure so as to meet different use requirements of users. The following detailed description will be given with reference to the accompanying drawings.

Example 1

The invention discloses an intelligent host for realizing lateral sliding and overturning, which comprises a chassis bracket, wherein the chassis bracket comprises two first opposite sides, and slide rails are respectively arranged on the two first opposite sides and provided with a first preset position and a second preset position;

the main machine body is provided with rotary connecting parts corresponding to the two sliding rails, and the two rotary connecting parts are respectively connected to the corresponding sliding rails in a matching way;

The fixing structure is arranged to connect the main body and the chassis bracket and is used for providing acting force for keeping the main body at different postures relative to the chassis bracket.

Example two

Referring to fig. 1 to 4, fig. 1 is a state in which the main body 2 is stacked on the chassis support 1 and the display surface 21 is away from the chassis support 1, fig. 2 is a state in which the main body 2 is turned from the first posture around the second preset position 112 to the state in which the display surface 21 is inclined to and/or perpendicular to the chassis support 1, fig. 3 is a state in which the main body 2 is laterally slid to the first preset position relative to the chassis support 1, and fig. 4 is a state in which the main body 2 is turned from the chassis support 1 around the first preset position 111 to the state in which the display surface 21 is inclined to and/or perpendicular to the chassis support 1. The embodiment of the invention provides an intelligent host 10 for realizing lateral sliding and overturning, wherein the intelligent host 10 comprises a chassis bracket 1, a host body 2 and a fixing structure. The chassis bracket 1 includes two first opposite sides 11, and the two first opposite sides 11 are respectively provided with a sliding rail 12, where the sliding rail 12 has a first preset position 111 and a second preset position 112. The host machine body 2 is provided with rotary connecting parts 23 corresponding to the two slide rails 12, and the two rotary connecting parts 23 are respectively matched and connected with the corresponding slide rails 12; when the rotary connecting part 23 is located at the first preset position 111 and/or the second preset position 112, the main body 2 can be turned over relative to the chassis bracket 1, so that the main body 2 has different postures relative to the chassis bracket 1; and a holding structure is provided to connect the main body 2 and the chassis bracket 1, the holding structure being for providing a force to hold the main body 2 in different attitudes with respect to the chassis bracket 1.

That is, the main body 2 can be turned over relative to the chassis frame 1, and the turned posture can be the same or different, regardless of whether the rotation connection portion 23 is located at the first preset position 111 or the second preset position 112.

Through the mode that this host computer body 2 can slide to the first mode of overturning of predetermineeing behind the position 111 of position relative chassis support 1, the user can overturn host computer body 2 into different use postures relative chassis support 1 according to different user demands to optimize the function use of intelligent wrist-watch greatly.

When the intelligent host 10 of the invention is applied to the intelligent watch, the host body 2 can be used as a host of the intelligent watch, the chassis bracket 1 can be used as a part for connecting the watchband 20, and under the action of the fixing structure, the host body 2 can keep different postures relative to the chassis bracket 1, namely, the host body 2 can keep different postures relative to the watchband 20. Specifically, the host body 2 of the present invention includes not only a main board, a touch screen and/or a display surface for realizing a touch and display function, a battery for supplying power to the main board and the touch screen and display surface, a photographing device for realizing a photographing function of the host body, a communication device (e.g., a wireless communication device, a bluetooth communication device, an infrared communication device, etc.) for realizing a communication function of the host body, a sensor (e.g., a gravity sensor, an acceleration sensor, a distance sensor, a barometric sensor, an ultraviolet detector, a play water detection and identification module) for realizing a detection function of the host body, a heart rate detector for realizing a detection of a heart rate of a user, a timer for realizing a timing function of the host body, an element for identifying an identity of a user, such as a fingerprint module, a facial recognition module, and a microphone, a speaker, etc. for realizing audio input and/or output. It should be appreciated that each device and each functional module are all arranged inside the host body and electrically connected with the main board, and the devices and the functional modules are controlled through the main board so as to further control the corresponding functions.

Therefore, the main body 2 of the embodiment of the present invention is different from the dial plate of the conventional wristwatch, which can only realize the functions of time display, timing, etc.

In this embodiment, in order to facilitate sliding of the host body 2 relative to the two first opposite sides 11 of the chassis support 1, the two first opposite sides 11 of the chassis support 1 are provided with sliding rails 12, and the host body 2 is slidably disposed on the sliding rails 12. In particular, the slide rail 12 may be formed by a slide groove provided on two first opposite sides 11 of the chassis support 1 or by a boss protruding on two first opposite sides 11 of the chassis support 1. Preferably, the slide rail 12 is formed by bosses protruding on two first opposite sides 11 of the chassis frame 1.

Further, in order to define the sliding position of the host body 2 on the sliding rail 12, the sliding rail includes a first end portion and a second end portion that are disposed opposite to each other, the first end portion is provided with a first clamping groove 121, the first clamping groove 121 forms a first preset position 111, the second end portion is provided with a second clamping groove 122, and the second clamping groove 122 forms a second preset position 112.

Therefore, when the first preset position 111 and the second preset position 112 are turned over, the turning direction is reversed if the turning postures are the same.

The different postures of the main body 2 relative to the chassis support 1 at least include a first posture and a second posture, wherein the first posture is a posture that the main body 2 is overlapped on the chassis support 1, that is, at this time, the display surface 21 of the main body 2 is approximately parallel to the chassis support 1, and under this posture, the main body 2 is used with a common watch main body when applied to the smart watch. The second posture is a posture in which the main body 2 is inclined and/or vertical with respect to the chassis frame 1, that is, at this time, the display surface 21 of the main body 2 is inclined and/or vertical to the chassis frame 1.

Specifically, when the rotary connection portion 23 is located at the second preset position 112, the main body 2 is located at the first posture relative to the chassis frame 1, the display surface 21 of the main body 2 is substantially parallel to the chassis frame 1 and disposed upward (as in the paper direction of fig. 1), and if the rotary connection portion 23 is turned in the second slot 122, the main body 2 is turned from the first posture to the second posture, at this time, the display surface 21 of the main body 2 is inclined/or perpendicular to the chassis frame 1, and the display surface 21 faces the outside of the chassis frame 1.

When the rotary connection portion 23 slides from the second preset position 112 to the first preset position 111 and turns over, the display surface 21 of the main body 2 turns over from being substantially parallel to the chassis frame 1 to being inclined or perpendicular to the chassis frame 1, and at this time, the display surface 21 of the main body 2 faces the inner side of the chassis frame 1.

In the above two cases, whether to directly turn over the second preset position 112 or to slide from the second preset position 112 to the first preset position 111 before turning over may be selected according to the wearing habit of the user, which is not limited in the embodiment of the present invention.

In this embodiment, as shown in fig. 5 and 6, the holding structure provides a force for maintaining the first posture and the second posture for the smart host. Specifically, since the main body 2 may have different attitudes with respect to the chassis frame 1, the holding structure includes a first holding structure 31 and a second holding structure 32, and the first holding structure 31 is used for providing a force for keeping the main body 2 in the first attitudes with respect to the chassis frame 1, that is, the main body 2 may keep the first attitudes with respect to the chassis frame 1 under the action of the first holding structure 31. The second holding structure 32 is used for providing a force for keeping the main body 2 in the second posture relative to the chassis frame 1, that is, the main body 2 can keep the second posture relative to the chassis frame 1 under the action of the second holding structure 32.

In this embodiment, in order to enable the main body 2 to slide laterally relative to the chassis frame 1, the main body 2 includes two second opposite sides 22, and the two second opposite sides 22 can slide relative to the two first opposite sides 11, as shown in fig. 3 and 6. The second opposite side 22 has a first position, and the first position is located at a non-rotating end of the main body 2, and the first holding structure 31 is disposed at the first position. When the host body 2 keeps a first posture relative to the chassis bracket 1, the first holding structure 31 at the first position is buckled on the first opposite side 11 of the chassis bracket 1, at this time, the host body 2 is stacked on the chassis bracket 1, and the first holding structure 31 provides an acting force for the intelligent host to keep the host body 2 in the first posture relative to the chassis bracket 1. That is, when the user does not need to use the smart host or wants to keep the host body 2 in the first posture relative to the chassis frame 1, the host body 2 does not slide relatively relative to the chassis frame 1 due to the holding effect of the first holding structure 31.

Further, a groove or a clamping hole is formed on the second opposite side 22 of the host body 2, the position of the groove or the clamping hole forms the first position, and the first holding structure 31 is partially clamped in the groove or the clamping hole. Specifically, the second opposite side 22 of the main body 2 is provided with a fastening hole, the first retaining structure 31 is a fastener structure partially disposed in the fastening hole, and includes a first fastener and a first elastic member 312, wherein the first fastener includes a fastening portion 31a and a connecting portion 31b, and the first elastic member 312 is connected between the fastening portion 31a and the connecting portion 31b and is used for providing a fastening force between the fastening portion 31a and the chassis bracket 1. The connecting portion 31b is completely engaged in the engaging hole, and the connecting portion 31b is hollow, so as to facilitate the installation of the first elastic member 312. Preferably, one end of the first elastic member 312 is connected to the inner wall surface of the connecting portion 31b, the fastening portion 31a is fastened to the connecting portion, the fastening portion 31a partially extends out of the hollow portion of the connecting portion 31b, and the fastening portion 31a can press the first elastic member 312 under the force of an external force so that the fastening portion 31a is located in the hollow portion of the connecting portion 31b, and the fastening portion 31a can be used to fasten with the first clamping groove 121 on the first opposite side 11 of the chassis support 1 when the host body 2 is located in the first posture relative to the chassis support 1, so as to keep the host body 2 in the first posture relative to the chassis support 1.

Preferably, the first holding structure 31 is a spherical fastening structure, wherein the fastening portion 31a is a sphere, so as to reduce friction of the fastening portion 31a to the chassis bracket 1 during fastening. Other alternatives for the first holding structure 31, such as a push-button type holding manner, may be used.

Preferably, the number of the first holding structures 31 is two, and the two holding structures are respectively arranged on two second opposite sides 22 of the main body 2.

The following describes the holding process of the first holding structure 31 in detail:

when the main body 2 is located at the first posture relative to the chassis support 1, the first elastic member 312 is in a pre-pressed state, and the fastening portion 31a keeps the state of being fastened to the chassis support 1 under the pre-pressing action of the first elastic member 312, at this time, the main body 2 keeps the first posture unchanged relative to the chassis support 1. When the user needs to make the main body 2 slidable and reversible relative to the chassis frame 1, the fastening effect of the fastening portion 31a and the chassis frame 1 needs to be released, and at this time, the user can separate the fastening portion 31a from the first clamping groove 121 of the chassis frame 1 by applying an external force. Specifically, since the buckling portion 31a is a sphere, the sphere of the buckling portion 31a is abutted against the end of the sliding rail 12 at an angle, when the user pushes the main body 2 manually, the pushing force received by the buckling portion 31a can be decomposed into a lateral pushing force parallel to the sliding rail 12 and a pressing force perpendicular to the first elastic member 312, when the user pushes the main body 2 such that the pressing force is greater than the pre-pressing action of the first elastic member 312 on the buckling portion 31a, the first elastic member 312 is pressed to drive the buckling portion 31a to move in a direction towards the inside of the connecting portion 31b, so that the buckling portion 31a is pressed back into the connecting portion 31b entirely, and at this time, the main body 2 can slide relative to the chassis bracket 1 because the first holding structure 31 has no protruding portion for buckling in the first clamping groove of the chassis bracket 1.

Referring to fig. 1, 3 and 4 again, when the user needs to use the main body 2 to make an angle with respect to the chassis frame 1 so as to operate the display surface 21 and the photographing device, the main body 2 can be slid to the first preset position 111 along the first opposite side 11 of the main body 2 with respect to the chassis frame 1, and then the main body 2 is not completely overlapped on the chassis frame 1. When the main body 2 slides to the first preset position 111 relative to the chassis frame 1, the main body 2 can turn over relative to the chassis frame 1, so as to obtain a second posture. That is, the second posture is a posture in which the main body 2 is turned over relative to the chassis support 1 to a state in which the display surface is inclined to and/or perpendicular to the chassis support 1 (as shown in fig. 4), that is, an angle is formed between the main body 2 and the chassis support 1, and the angle can be adjusted to be an acute angle, a right angle, an obtuse angle, or the like according to the usage habit of the user.

Further, the main body 2 can slide on the first opposite side 11 relative to the chassis frame 1 and can turn over relative to the chassis frame 1 when sliding to the first preset position 111, so as to maintain the turned posture of the main body 2 relative to the chassis frame 1, so that the main body 2 has different postures relative to the chassis frame 1, and the second holding structure 32 is disposed at the first preset position 111 of the chassis frame 1, at this time, the second holding structure 32 provides a force for maintaining the turned posture after the main body 2 turns over relative to the chassis frame 1 at the first preset position 111.

Further, the two second opposite sides 22 of the main body 2 further have second positions spaced from the first positions, and the second positions are located at one end of the main body 2 turned relative to the chassis frame 1, i.e. the first positions and the second positions are located at two opposite ends of the main body 2. The second position is formed by a card hole disposed on a second opposite side 22 of the main body 2, and the second position and the first position are approximately symmetrically disposed with respect to the center of the main body 2, and the card hole of the second position is provided with a rotary connection portion 23 (as shown in fig. 8).

Further, the rotary connecting portion 23 is slidably connected to the two first opposite sides 11, and the rotary connecting portion 23 can be turned over relative to the first opposite sides 11 when sliding to the first preset position 111. Specifically, when the main body 2 is located in the first posture relative to the chassis frame 1, the rotating connection portion 23 is located in the second clamping groove 122, that is, the rotating connection portion 23 is located in the second preset position 112, and when the main body 2 slides from the second preset position 112 to the first preset position 111 relative to the chassis frame 1, that is, the rotating connection portion 23 slides from the second clamping groove 122 to the first clamping groove 121 along the slide rail 12.

Further, the second holding structure 32 is disposed on the first opposite side 11 of the chassis frame 1, and is configured to abut against the rotating connection portion 23 when the rotating connection portion 23 slides to the first preset position 111 and turns over, so that the host body 2 maintains the second posture relative to the chassis frame 1.

Referring to fig. 9, in the present embodiment, the second holding structure 32 includes a fixing member 321 and a second elastic member 322, where the second elastic member 322 is configured to be connected to the fixing member 321, for providing a force for abutting the fixing member 321 against the rotating connection portion 23. One end of the second elastic member 322 is connected to the chassis bracket 1, and the other end is connected to the fixing member 321. The fixing piece 321 faces the rotation connection portion 23, and the fixing piece 321 is for abutting against the rotation connection portion 23. Preferably, the second elastic member 322 is a spring, which has high flexibility and good extensibility, and the spring has an elastic function to buffer the second elastic member 322 during the overturning process, so as to reduce the vibration of the second elastic member 322 to the intelligent host 2 during the expansion process. In addition, due to the elastic action of the spring, the second holding structure 32 can be firmly abutted against the chassis bracket 1.

Further, in order to enable a more stable lateral sliding movement on the first opposite side 11 of the main body 2 and a better maintenance of the flipped posture, the rotation connection portion 23 is provided with at least a first stop surface 231 and a second stop surface 232 (see fig. 8) disposed at an angle. The first limiting surface 231 and the second limiting surface 232 are disposed on the shaft connection portion 23a of the rotation connection portion 23 engaged with the first opposite side, and the first limiting surface 231 and the second limiting surface 232 may be plural, each of the first limiting surface 231 and the second limiting surface 232 may be disposed at an angle, and in order to realize limiting the host body 2, the areas of the first limiting surface 231 and the second limiting surface 232 may be equal or unequal.

Specifically, the second holding structure 32 is used to abut against the first limiting surface 231 and/or the second limiting surface 232 when the rotary connecting portion 23 turns over relative to the chassis bracket 1, so that the host body 2 obtains different limiting angles relative to the chassis bracket 1. For example, the area of the second limiting surface 232 is larger than that of the first limiting surface 231, when the second holding structure 32 abuts against the first limiting surface 231, the host body 2 may be located at an angle between 30 ° and 80 ° with respect to the chassis support 1, and when the second holding structure 32 abuts against the second limiting surface 232, the host body 2 may be located at an angle between 80 ° and 120 ° with respect to the chassis support 1. Preferably, in order to conform to the operation and viewing habit of the user on the display surface 21, when the second holding structure abuts against the second limiting surface 232, the main body 2 may be located at an angle of 90 ° with respect to the chassis frame 1, and at this time, the display surface 21 is disposed perpendicular to the chassis frame 1.

Further, the chassis bracket 1 includes a bottom plate 13, two side plates 14 connected to two sides of the bottom plate 13 and forming two first opposite sides 11, and the two side plates are separately provided with sliding rails 12. Wherein, all protruding boss 141 that is equipped with on both sides board 14, chassis support 1 still includes fixed plate 15, and fixed plate 15 locates on the curb plate 14, and fixed plate 15 and boss 141 are relative and the interval setting, form slide rail 12 between fixed plate 15 and the boss 141.

In this embodiment, in order to facilitate the sliding of the main body 2 relative to the sliding rail 12, the rotating connection portion 23 of the main body 2 is clamped and axially connected to the corresponding sliding rail 12. Specifically, during the sliding process of the host body 2 relative to the sliding rail 12, the rotating connection portion 23 slides relative to the sliding rail 12. That is, in the first posture, the rotation connecting portion 23 is located at the second preset position 112 of the slide rail 12; when the main body 2 is required to rotate relative to the chassis bracket 1, the rotary connecting portion 23 slides to the first preset position 111 along the second preset position 112 of the slide rail 12, and turns over. That is, when the rotary connecting portion 23 slides to the first preset position 111, the rotary connecting portion 23 is locked in the first locking groove 121, and at this time, the user can apply a force to turn the rotary connecting portion 23, so that after the rotary connecting portion 23 turns, the rotary connecting portion 23 can be substantially fixed at the first preset position 111 during the rotation process due to the arrangement of the first locking groove 121, and cannot slide from the first preset position 111 to the second preset position 112.

More preferably, the first clamping groove 121 should be a circular groove substantially matching with the rotary connecting portion 23, so as to facilitate clamping of the rotary connecting portion 23. The number of the rotation connecting parts 23 is two and are respectively arranged on two second opposite sides 22 of the main body 2, so that the number of the corresponding second holding structures 32 is also two.

Further, the rotary connecting portion 23 further includes a host connecting portion 23b other than the shaft connecting portion 23a, and the host connecting portion 23b is fixedly disposed on the host body 2, so that the rotary connecting portion 23 and the host body 2 are combined into a whole, that is, the motion postures of the host body 2 and the rotary connecting portion 23 are kept consistent, so that when the rotary connecting portion 23 slides on the slide rail 12 or rotates in the first clamping groove 121, the host body 2 can slide laterally relative to the chassis bracket 1 or overturn relative to the chassis bracket 1. The shaft connection part 23a is clamped and connected in the corresponding slide rail 12 in a shaft way, the first limit surface 231 and/or the second limit surface 232 are/is arranged on the shaft connection part 23a, and the shaft connection part 23a can slide on the slide rail 12 but can not realize overturning, so that the host machine body 2 is ensured to be parallel to the chassis support 1 in the sliding process, and the chassis support 1 is not scraped due to overturning in the sliding process.

The different postures of the host body 2 relative to the chassis bracket 1 further comprise a third posture, when the host body 2 slides to the first preset position 111 relative to the chassis bracket 1, the host body 2 can overturn relative to the chassis bracket 1 so as to enable the host body 2 to overturn from the first posture to the second posture, and when the host body 2 overturns to the second posture, the host body 2 can overturn again relative to the chassis bracket 1 so as to enable the host body 2 to overturn from the second posture to the third posture;

The third posture is a posture that the main body 2 is stacked on the chassis support 1, and when the main body 2 is located in the third posture, the direction of the display surface 21 of the main body 2 for displaying is opposite to the direction of the display surface 21 of the main body 2 located in the first posture.

Further, when the main body 2 slides to the first preset position 111 and the main body 2 is turned over from the first posture to the second posture, the rotating connection portion 23 slides to the first clamping groove 121 and turns over at the first clamping groove 121, and the fastening portion 31a of the first fixing structure 31 is fastened to the second clamping groove 122, at this time, the first fixing structure 31 provides a force for keeping the third posture of the main body 2 stacked on the chassis bracket 1 for the intelligent host. Similarly, when the main body 2 is stacked on the chassis support 1 and is located in the first posture, the rotary connection portion 23 is located in the second clamping groove 122 of the second preset position 112, and the first fixing structure 31 is clamped in the first clamping groove 121 of the first preset position 111, at this time, the first fixing structure 31 provides an acting force for keeping the main body 2 stacked on the first posture of the chassis support 1 for the intelligent host.

The turning process in different turning modes is described in detail below:

as shown in fig. 1 to 4, 11 and 12, taking the example that the shaft portion 23a of the rotary connecting portion 23 is located at the second preset position 112 when the main body 2 is located at the first posture, that is, the rotary connecting portion 23 is clamped in the second clamping groove 122 at the second end portion:

First pose-second pose: the force is applied to push the host body 2 along the direction parallel to the chassis support 1 and perpendicular to the upward direction of the chassis support 1, the shaft connection part 23a of the rotary connection part 23 axially rotates in the second clamping groove 122, at this time, the host body 2 overturns relative to the chassis support 1, the display surface 21 of the host body 2 overturns towards the outer side of the chassis support 1, the display surface 21 overturns from the chassis support 1 to the display surface 21 and is inclined or perpendicular to the chassis support 1, the host body 2 is overturned from a first posture to a second posture, at this time, the second retaining structure 32 in the first clamping groove 121 abuts against the limiting surface of the rotary connection part 23, so that the host body 2 keeps the second posture relative to the chassis support 1, and at this time, the display surface 21 of the host body 2 faces towards the outer side of the chassis support 1.

First posture-second posture-third posture-second posture-first posture: the force pushes the host body 2 along the side where the first end is located in the direction parallel to the chassis support 1, the shaft connection part 23a of the rotary connection part 23 slides from the second clamping groove 122 to the first clamping groove 121 along the sliding rail 12 and is clamped in the first clamping groove 121, the force turns the host body 2 upwards, the display surface 21 turns from the chassis support 1 to the display surface 21 to incline or be perpendicular to the chassis support 1, the host body 2 is turned from the first posture to the second posture, at this time, the second retaining structure 32 is abutted against the limiting surface of the rotary connection part 23, so that the host body 2 keeps the second posture relative to the chassis support 1 (at this time, the display surface 21 of the host body 2 faces the inner side of the chassis support 1). The host body 2 is tilted from the display surface 21 or is perpendicular to the chassis support 1 to the state that the host body 2 is overlapped on the chassis support 1 and the display surface 21 faces the chassis support 1 by applying force again, so that the host body 2 is turned from the second posture to the third posture.

The flipping back from the third pose to the first pose includes the following 2 flipping modes:

(1) the force is applied to push the host body 2 along the side where the second end part is located in the direction parallel to the chassis support 1, the shaft connection part 23a of the rotary connection part 23 slides to the second clamping groove 122 along the sliding rail 12 along the first clamping groove 121 corresponding to the first preset position 111, and is clamped in the second clamping groove 122, the force is applied to turn the host body 2 upwards, the display surface 21 turns from the direction towards the chassis support 1 to the direction where the display surface 21 deviates from the chassis support 1 and is inclined/vertical to the chassis support 1, and the host body 2 turns from the third posture to the second posture; the host body 2 is turned from the display surface 21 to the chassis bracket 1 and is inclined or perpendicular to the chassis bracket 1 until the display surface 21 is opposite to and parallel to the chassis bracket 1, and the host body 2 is restored to the first posture from the second posture.

(2) The force is applied to push the host body 2 to the display surface 21 perpendicular to the host body 2 so that the host body 2 overturns from the third posture to the second posture relative to the chassis bracket 1, the force is applied again so that the host body 2 overturns from the second posture to the second posture, the shaft connection part 23a of the rotary connection part 23 is clamped in the first clamping groove 121, the host body 2 is parallel to the posture of the chassis bracket 1, then the force is applied to push the host body 2 along the direction parallel to the chassis bracket 1 to the side where the second end part is located, and the host body 2 returns to the first posture.

As shown in fig. 14, in the present embodiment, the host body 2 further includes a host housing 24 having a receiving cavity, and a cover 26 embedded with a display screen 25 and connected to the host housing 24, the display screen 25 covers an opening of the receiving cavity of the host housing 24. The display surface 21 is a surface of the display screen 25. The face cover 26 is used for connecting the host shell 24 and the display screen 25, the face cover 26 is of an arc structure with a narrow upper part and a wide lower part, the narrower end is provided with a first face cover end 261, the first face cover end 261 is used for embedding the display screen 25, and impact force is prevented from directly acting on the display screen 25 when the side face of the host body 2 is impacted. The wider end is set as the second cover end 262, and the second cover end 262 is connected with the host casing 24, so as to increase the area of the accommodating cavity of the host casing 24, reduce the thickness of the host casing 24, and make the appearance of the host body 2 lighter and thinner.

Further, the display screen 25 is adhered and embedded at the first cover end 261 of the cover 26 through an adhesive layer, the surface of the display screen 21 is slightly lower than the outer edge of the first cover end 261, when the host body 2 is in the first posture, when a user carelessly collides the host body 2 with the outside, the first cover end 261 can be utilized to protrude outside the display screen 21 so as to avoid the direct collision of the display screen 25 with the outside; secondly, when the display surface 21 of the host body 2 is parallel and slides laterally towards the chassis bracket 1, the display surface 21 can be prevented from directly sliding and rubbing with the chassis bracket 1, so as to prevent the display screen 25 from being scratched. The second cover end 262 is adhered and embedded in the main housing 24 through an adhesive layer.

According to the intelligent host for realizing the lateral sliding and overturning provided by the second embodiment of the invention, the main body 2 can laterally slide and overturn relative to the chassis bracket 1 by arranging the fixing structure and the chassis bracket 1 with the slide rail 12 and the clamping groove in the intelligent host, the posture of the main body 2 overlapped on the chassis bracket 1 can be kept under the action of the first fixing structure 31, and the display surface 21 of the main body 2 can be kept to be inclined or vertical to the posture of the chassis bracket 1 under the action of the second fixing structure 32, so that the use of the intelligent watch function is optimized.

Example III

Fig. 15 to 20 are schematic views of an intelligent host for implementing lateral sliding and turning according to a third embodiment of the present invention. The intelligent host for realizing the lateral sliding and turning in the third embodiment of the invention is different from the intelligent host for realizing the lateral sliding and turning in the second embodiment in that:

the camera module on the host body 2 of the embodiment of the present invention may include a front camera module 27 and/or a rear camera module 28. In order to enrich the shooting function and enable the host body 2 to achieve shooting in different postures, the camera module is configured as a dual camera module structure including a front camera module 27 and a rear camera module 28.

Further, the main body 2 includes a display surface 21 and a non-display surface 29 disposed opposite to each other. The front camera module 27 is disposed toward the display surface 21, and the rear camera module 28 is disposed toward the non-display surface 29. Specifically, for the host body 2 of the present embodiment, the display surface 21 is used as the forward direction, the non-display surface 29 is used as the backward direction, and the host body 2 has two camera modules, and the two camera modules are arranged in tandem. Thus, when the main body 2 is in the first posture relative to the chassis bracket 1, the front camera module 27 faces the front direction, and the rear camera module 28 faces the rear direction, so that the front camera module 27 can be used for shooting scenes in the front direction. In the first posture, the rear camera module 28 cannot capture the scene that the user wants to capture due to the shielding of the arm wearing surface, because the smart host can be applied to the smart watch and worn on the arm of the user. Based on this, the present invention can slide the main body 2 to the first preset position 111 relative to the chassis bracket 1 and turn over to the second posture, at this time, the main body 2 is no longer stacked on the chassis bracket 1, at this time, even if the user wears the smart watch, the rear camera module 28 is no longer shielded by the arm wearing surface, and the rear camera module 28 can be applied to shooting as well. Therefore, the purpose of the rotation of the main body 2 relative to the chassis support 1 is to achieve different shooting requirements of users, so that the rear camera module 28 is further added on the basis of the original single camera module, and after the main body 2 slides and overturns relative to the chassis support 1, the double camera modules can respectively achieve different shooting requirements of users. In fact, when the user wears the smart watch to shoot, the functions of self-shooting, video call and the like of the user can be realized through the front camera module 27, and the functions of surrounding scenery shooting, code scanning and the like can be realized through the rear camera module 28, so that the host body 2 provided with the double camera modules can meet different shooting requirements of the user in different occasions and different scenes, and the use experience of the user on the smart watch can be greatly improved.

It should be appreciated that the front camera module 27 may also be used to perform functions such as shooting and scanning surrounding scenes, and the rear camera module 28 may also be used to perform functions such as self-timer shooting and video call. Specifically, the device can be set according to the actual use condition of a user.

Further, since the front camera module 27 is disposed toward the display surface 21, the rear camera module 28 is disposed toward the non-display surface 29. Therefore, the front camera module 27 may be disposed within the display range of the display surface 21 or outside the display range of the display surface 21. Preferably, the projections of the front camera module 27 and the rear camera module 28 on the display surface 21 are located within the display range of the display surface 21.

In this embodiment, the view direction of the front camera module 27 is set in the same direction as the display surface 21, and the view direction of the rear camera module 28 is set in the same direction as the non-display surface 29, wherein the non-display surface 29 is opposite to the display surface 21. The projection position of the rear camera module 28 on the non-display surface 29 corresponds to the projection position of the front camera module 27 on the display surface 21, the display surface 21 and the non-display surface 29 are respectively provided with an opening for the camera module to view, when shooting, the position of the camera module can be found according to the opening for viewing, the camera module is aligned to the scenery required to be shot, and the scenery shot by the focusing camera module is watched on the display surface 21. Because the front camera module 27 is disposed towards the display surface 21, and the rear camera module 28 is disposed towards the non-display surface 29, when we use the front camera module 27 to shoot, because the opening of the view finding is on the same plane as the display surface 21, we can quickly find the position of the camera module and aim at the required shooting object to shoot. However, when the rear camera module 28 is used for shooting, the user needs to watch the display surface 21 to watch or focus the shot scenery during shooting, so that the position of the camera module cannot be mastered in real time and the camera module is aligned to the shot object, which causes inconvenience to the user in shooting. Therefore, the setting position of the rear camera module 28 on the non-display surface 29 can be corresponding to the setting position of the front camera module 27 on the display surface 21, and when the user uses the rear camera module 28 to take a photograph, the user can know the position of the front camera module 27 through the view finding opening of the front camera module 27, so as to know the position of the rear camera module 28, so as to take a photograph for view finding, aligning and adjusting focal length, and the like. Meanwhile, the eyes of the user are generally perpendicular to the display surface 21 during shooting so as to better view the shot scenery, therefore, the shooting direction of the front camera module 27 can be set to be perpendicular to the display surface 21, and the shooting direction of the rear camera module 28 is perpendicular to the non-display surface 29, so that the user can watch the display surface 21 to directly observe the shot object, thereby facilitating shooting.

Therefore, the angles of the display surface 21 and the non-display surface 29 relative to the chassis support 1 are changed by the overturning of the host body 2 relative to the chassis support 1, and the overturned postures of the display surface 21 and the non-display surface 29 are maintained under the action of the holding structure, so that the shooting directions of the front camera module 27 and the rear camera module 28 are changed. Because the host body 2 is inclined or vertically arranged relative to the chassis bracket 1 in the second posture, at this time, the host body 2 is far away from the arm of the user, that is, in this posture, the user can use the functions of video call, shooting, reading and the like with larger heating value.

According to the intelligent host for realizing the lateral sliding and overturning provided by the embodiment of the invention, the double-camera module mode comprising the front camera module 27 and the rear camera module 28 is arranged on the intelligent host for realizing the lateral sliding and overturning so as to enrich shooting functions, and the display surface 21 of the host body 2 can be kept inclined and/or perpendicular to the chassis bracket 1 under the action of the fixing structure, so that the shooting directions of the front camera module 27 and the rear camera module 28 are changed so as to meet different shooting demands of users in different occasions and different scenes, and the use experience of the users on the intelligent watch is greatly improved.

Example IV

Referring to fig. 1 to 5 and fig. 11 to 13, a fourth embodiment of the present invention discloses an intelligent host for realizing lateral sliding and turning, which comprises a chassis bracket 1, wherein the chassis bracket 1 comprises two first opposite sides 11, sliding rails 12 are respectively arranged on the two first opposite sides 11, and the sliding rails 12 have a first preset position 111 and a second preset position 112;

the main body 2 is provided with rotary connecting parts 23 corresponding to the two slide rails 12, and the two rotary connecting parts 23 are respectively connected to the corresponding slide rails 12 in a matching way;

the main body 2 is slidably connected to the slide rail 12 of the chassis bracket 1, and the main body 2 can be turned over relative to the chassis bracket 1 when being slid to the first preset position 111 along the second preset position 112 on the slide rail 12 relative to the chassis bracket 1 and/or being slid to the second preset position 112 from the first preset position 111, so that the main body 2 has different postures relative to the chassis bracket 1; and

a holding structure is arranged to connect the main body 2 and the chassis bracket 1, and the holding structure is used for providing a force for keeping the main body 2 at different postures relative to the chassis bracket 1.

The lateral sliding and turning manner in the fourth embodiment is the same as that described in the second embodiment, so the sliding and turning process is not repeated in the fourth embodiment.

Example five

Referring to fig. 21, 22 and 23, in order to disclose a smart watch with a smart host for implementing lateral sliding and turning according to the fifth embodiment of the present invention, fig. 21 is a first posture of the smart watch, fig. 22 is a second posture of the host body 2 of the smart watch when the host body 2 of the smart watch is turned at a first preset position 111, and fig. 23 is a second posture of the host body 2 of the smart watch when the host body 2 is turned at a second preset position 112. The smart watch disclosed in the fifth embodiment of the present invention may include the smart host of the third embodiment described above and the wristband 20. The two watchbands 20 are respectively connected to the outer sides of the two first opposite sides 11 of the chassis support 1, and the watchbands 20 can be fixedly or rotatably connected with the chassis support 1.

Specifically, since the wristband 20 is attached to the two first opposite sides 11 of the chassis frame 1, the main body 2 slides laterally with respect to the wristband 20 as the main body 2 slides between the first preset position 111 and the second preset position 112 of the first opposite sides 11 with respect to the chassis frame 1. In the process that the main body 2 is turned over from the first posture to the second posture, the main body 2 slides to the first preset position 111 at the second preset position 112 on the opposite side relative to the chassis support 1, the main body 2 slides to the right side (right direction in the paper surface direction of fig. 21) from the left side position relative to the watchband 20, when the main body 2 slides to the first preset position 111, the main body 2 is turned over to obtain the second posture (shown in fig. 22), at this time, the display screen 25 faces the inner side of the chassis support 1, that is, the front camera module 27 faces the inner side of the chassis support 1, and the rear camera module 28 faces the outer side of the chassis support 1.

In addition, the main body 2 may also be turned at the second preset position 112 on the first opposite side 11 with respect to the chassis support 1, at this time, the main body 2 does not move left and right with respect to the watchband 20, and the first posture of the main body 2 stacked on the chassis support 1 is directly turned to the second posture of the main body 2 inclined or vertical with respect to the chassis support 1 (as shown in fig. 23), at this time, the display screen 25 faces the outside of the chassis support 1, i.e. the front camera module 27 faces the outside of the chassis support 1, and the rear camera module 28 faces the inside of the chassis support 1.

Therefore, the sliding direction and the turning direction of the main body 2 relative to the chassis support 1 are different from the connection direction of the watchband 20 and the chassis support 1, so that when the main body 2 slides relative to the chassis support 1, the wearing of the watchband 20 is not affected, the use habit of a user is more met, and the lateral sliding mode is adopted, so that the structural design of the watch is more convenient and reasonable.

In addition, for the design and use of the host structure 10, please refer to the description of the second embodiment and the third embodiment, and the description is omitted here.

According to the smart watch provided by the fifth embodiment of the invention, the fixing structure is arranged, so that the host machine body 2 can keep the smart host machine 10 in different postures after the host machine body 2 slides and overturns laterally relative to the chassis bracket 1, the host machine body 2 can move laterally and overturned relative to the watchband 20, and the overturned posture is kept, namely, when a user wears the smart watch with the smart host machine 10, the host machine body 2 can move and overturned relative to the arm to a required posture, so that the smart watch is convenient to use. Meanwhile, the overturned posture of the host can be used for a function with a part of larger heating value, so that the heating source is not in direct contact with the arm. And the display surface 21 can be turned to be parallel and towards the chassis bracket 1 when the function of the display surface 21 is not needed, so as to protect the display surface 21. In addition, because the chassis support 1 is additionally arranged between the host body 2 and the arm of the user, the chassis support 1 can help heat conduction and quicken heat dissipation of the host body 2 and reduce direct heat transfer quantity of the host body 2 to skin under the daily wearing state that the host body 2 is overlapped on the chassis support 1.

Example six

An embodiment six of the present invention provides a smart watch, which includes the smart host 10 and the watchband 20 for realizing the lateral sliding and turning in the fourth embodiment, and the watchband 20 is connected to the chassis bracket 1 of the smart host 10.

For the smart watch according to the sixth embodiment of the present invention, the structure and the manner of implementing the overturn of the smart host may be described in the third embodiment and the fourth embodiment, and for the structure of the watchband, please refer to the description in the fifth embodiment, which is not repeated here.

The intelligent host and the intelligent watch for realizing the lateral sliding and turning disclosed by the embodiment of the invention are described in detail, and specific examples are applied to the principle and the implementation of the invention, and the description of the above examples is only used for helping to understand the intelligent host and the intelligent watch for realizing the lateral sliding and turning and the core ideas thereof; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present invention, the present description should not be construed as limiting the present invention in view of the above.

Claims

1. An intelligent host for realizing lateral sliding and overturning, which is characterized by comprising:

when the rotary connecting part is positioned at the first preset position or the second preset position, the host body can turn over relative to the chassis bracket so as to enable the host body to have different postures relative to the chassis bracket; and

a holding structure arranged to connect the host body and the chassis support, the holding structure being for providing a force to hold the host body in the different positions relative to the chassis support;

the different postures at least comprise a first posture and a second posture, the holding structure comprises a first holding structure and a second holding structure, the first holding structure is used for providing a force for keeping the main machine body in the first posture relative to the chassis bracket, and the second holding structure is used for providing a force for keeping the main machine body in the second posture relative to the chassis bracket;

The first gesture is a gesture that the host body is overlapped on the chassis bracket, and the second gesture is a gesture that the host body is inclined or vertical relative to the chassis bracket;

the rotary connecting part is at least provided with a first limiting surface and a second limiting surface which are arranged at an angle, and the second fixing structure is used for abutting against the first limiting surface or the second limiting surface when the rotary connecting part overturns relative to the chassis bracket, so that the host body forms different angles relative to the chassis bracket;

the first limiting surface and the second limiting surface are used for limiting the rotary connecting portion to slide on the sliding rail but not turn over.

2. The intelligent host for realizing lateral sliding and overturning according to claim 1, wherein the second fixing structure is arranged at the first preset position of the chassis bracket;

3. The intelligent host for realizing lateral sliding and overturning according to claim 2, wherein two second opposite sides of the host body are further provided with second positions which are arranged at intervals from the first positions, and the rotary connecting part is arranged at the second positions;

4. The intelligent host for realizing lateral sliding and overturning according to claim 1, wherein the first fixing structure comprises a first fastener and a first elastic piece, the first fastener comprises a buckling part and a connecting part, and the first elastic piece is connected between the buckling part and the connecting part and is used for providing an acting force for buckling the buckling part and the chassis bracket.

5. The intelligent host for realizing the lateral sliding and overturning according to claim 1, wherein the second fixing structure comprises a fixing piece and a second elastic piece, and the fixing piece is used for abutting against the first limit surface or the second limit surface when the rotary connecting part overturns relative to the chassis bracket so as to enable the host body to form different angles relative to the chassis bracket;

the second elastic piece is arranged to be connected with the fixing piece and is used for providing acting force for abutting the fixing piece with the rotary connecting part.

6. The intelligent host machine according to any one of claims 1 to 5, wherein the slide rail comprises a first end portion and a second end portion which are disposed opposite to each other, the first end portion and the second end portion are provided with a first clamping groove and a second clamping groove, the first clamping groove forms the first preset position, and the second clamping groove forms the second preset position.

7. The intelligent host for realizing the lateral sliding and overturning according to claim 1, wherein,

the different gestures at least comprise a first gesture, a second gesture and a third gesture;

8. The intelligent host machine according to any one of claims 1 to 5, wherein the chassis support comprises a bottom plate and two side plates connected to two sides of the bottom plate and forming the two first opposite sides, and the two side plates are separately provided with the sliding rails.

9. The intelligent host for realizing the lateral sliding and overturning of the intelligent host according to claim 8, wherein the side plate is convexly provided with a boss, the chassis bracket further comprises a fixing plate, the fixing plate is arranged on the side plate, the fixing plate is opposite to the boss and is arranged at intervals, and the sliding rail is formed between the fixing plate and the boss.

10. The intelligent host machine for realizing the lateral sliding and turning according to any one of claims 1 to 5, wherein the host machine body comprises a host machine shell with a containing cavity and a surface cover embedded with a display screen and connected with the host machine shell, and the display screen covers an opening of the containing cavity of the host machine shell.

11. The intelligent host for realizing lateral sliding and overturning according to any one of claims 1 to 5, wherein the host body is provided with a camera module, the camera module comprises a front camera module and a rear camera module, the view finding direction of the front camera module is arranged in the same direction as the display surface of the host body for displaying, the view finding direction of the rear camera module is arranged in the same direction as the non-display surface, and the non-display surface is arranged opposite to the display surface.

12. The intelligent host for realizing lateral sliding and overturning according to claim 11, wherein the projection position of the rear camera module on the display surface corresponds to the projection position of the front camera module on the display surface.

13. An intelligent host for realizing lateral sliding and overturning, which is characterized by comprising:

The main body can be connected to the sliding rail of the chassis bracket in a sliding manner, and can turn over relative to the chassis bracket when sliding to the first preset position along the second preset position on the sliding rail or sliding to the second preset position from the first preset position, so that the main body has different postures relative to the chassis bracket; and

14. A smart watch comprising a wristband and a smart host for effecting lateral sliding and flipping according to any one of claims 1 to 12, said wristband being connected to said two first opposite sides of said chassis support; or alternatively

The smart watch includes a wristband and the smart host for implementing lateral slip flip as claimed in claim 13, the wristband being connected to the two first opposite sides of the chassis support.