CN110187505B - Intelligent glasses - Google Patents

Abstract

The application provides an intelligent glasses, including glasses body and locking structure, wherein: the glasses body comprises a first body and a second body, the first body is provided with a rotating shaft column, the second body is provided with a rotating shaft sleeve, and the rotating shaft sleeve is clamped on the rotating shaft column to form a rotating shaft structure; the locking structure comprises a first magnetic part and a second magnetic part, the first magnetic part is slidably mounted on the second body, the second magnetic part is mounted on the first body or the second body, the rotating shaft structure is locked under the action of magnetic force between the first magnetic part and the second magnetic part, and the rotating shaft structure is switched from a locking state to an unlocking state when the action of magnetic force between the first magnetic part and the second magnetic part is overcome. This intelligence glasses is folding in order to realize accomodating of glasses body through changing the pivot structure, through addding locking structure, not only can realize the locking when wearing of glasses body, can also carry out quick dismantlement and change the user demand of second body in order to satisfy different users.

Description

Intelligent glasses

Technical Field

The application relates to wearable equipment technical field, especially relates to an intelligent glasses.

Background

Smart glasses, as a wearable device, combine the latest IT technology with the functions of traditional glasses, and have become increasingly popular due to their advantages of portability, ease of use, and rich functionality. Along with the development of the technology, the user no longer satisfies the demand for ordinary intelligent glasses, and the novel intelligent glasses that can be compatible with various consumer headings have become the market focus.

In order to adapt to the objective factor that head circumferences of different consumers are different, the existing intelligent glasses adopt the following two structural modes, namely, the first mode is that different glasses legs are replaced to meet the requirements of different consumers, but most of glasses frames and glasses legs in the current market adopt a hinge structure, the glasses legs and the glasses frames are locked through screws, and the screws are used as the centers of rotating shafts to rotate and store, but the hinge structure is usually difficult to disassemble and can be disassembled only by means of tools, so that the realization is difficult; in a second mode, the form of the glasses legs is changed, the existing Augmented Reality (AR)/Virtual Reality (VR) glasses adopt the adjusting belt to replace the glasses legs, and the adjusting belt is adjusted and fixed in a magic tape mode, but the fastening force of the magic tape is small, the phenomenon of poor adhesion is easy to occur after the glasses are used for a period of time, and the user experience is poor.

Disclosure of Invention

An object of this application is to provide an intelligence glasses for realize the quick dismantlement of mirror leg on guaranteeing that mirror leg rotates and support function.

The application provides intelligent glasses, which comprise a glasses body and a locking structure, wherein the glasses body comprises a first body and a second body, various functional software is additionally arranged on the first body and the second body so that the intelligent glasses are suitable for different man-machine interaction scenes, in order to meet the storage folding of the intelligent glasses, the first body and the second body are rotatably connected through a rotating shaft structure, in order to be compatible with the head circumference requirements of different users, the rotating shaft structure is required to be quickly assembled and disassembled on the basis of the original intelligent glasses function, the application improves the rotating shaft structure, when in specific setting, the first body is provided with a rotating shaft column, the second body is provided with a rotating shaft sleeve, the rotating shaft sleeve is clamped on the rotating shaft column to form a rotating shaft structure, and the rotating shaft structure is in a locking state under the magnetic force of the locking structure, the intelligent glasses are in an unlocking state after overcoming the magnetic force action of a locking structure, the rotating shaft column and the rotating shaft sleeve are in rotating fit in the locking state, the rotating connection between the first body and the second body can be realized, the rotating shaft sleeve and the rotating shaft column can be separated to replace the second body in the unlocking state, in order to realize the switching of the rotating shaft structure between the two states, the locking structure comprises a first magnetic part and a second magnetic part, the first magnetic part is slidably arranged on the second body, the second magnetic part is arranged on the first body or the second body, the magnetic force action is arranged between the first magnetic part and the second magnetic part, the rotating shaft structure is locked by the magnetic force action between the first magnetic part and the second magnetic part when the intelligent glasses are worn, and the distance between the first magnetic part and the second magnetic part is changed by moving the first magnetic part, and then the magnetic force action between the first magnetic part and the second magnetic part is changed, and when the magnetic force action between the first magnetic part and the second magnetic part is overcome, the rotating shaft structure is switched from a locking state to an unlocking state, and at the moment, the second body can be replaced. According to the intelligent glasses, the storage of the glasses body is foldable by changing the rotating shaft structure, the locking of the glasses body during wearing can be realized by adding the locking structure, and the second body can be detached and replaced quickly to meet the use requirements of different users.

In a specific embodiment, the pivot post protrusion sets up the one end of first body, including the pivot, set up relatively the roof and the bottom plate of the both sides of pivot, and connect the curb plate of roof and bottom plate, the roof with the bottom plate respectively with the pivot links to each other, first body with the surface that the pivot is relative is first cambered surface, just first cambered surface with the pivot is coaxial, the protruding setting of pivot cover is in the one end of second body, the surface of pivot cover with the pivot is coaxial. The end face of the first body and the outer surface of the rotating shaft sleeve are arranged to be cambered surfaces so as to facilitate the rotating fit between the rotating shaft sleeve and the rotating shaft column, interference can not occur when the rotating shaft sleeve and the rotating shaft column rotate, and the reliability of rotating connection between the first body and the second body is guaranteed.

In a specific embodiment, the inner surface of the rotating shaft sleeve comprises a second cambered surface coaxial with the rotating shaft and a plane tangent to the rotating shaft. The structure of the inner surface of the rotating shaft sleeve is limited to realize the quick assembly and disassembly between the rotating shaft sleeve and the rotating shaft column.

In a specific embodiment, the angle of the second cambered surface is 120-210 degrees. So that the pivot cover can be better cladding on the pivot post, and then guarantee that pivot post and pivot cover are connected reliably, thereby make pivot structural stability better.

In a specific embodiment, the first magnetic member is a shifting piece with one end protruding out of the second body, the shifting piece is slidably disposed in a space where the side plate and the rotating shaft are opposite, the shifting piece is inserted into the space when the rotating shaft structure is in a locked state, and the shifting piece is moved out of the space where the side plate and the rotating shaft are opposite when the rotating shaft structure is in an unlocked state. Just can overcome through stirring the plectrum the magnetic force effect between first magnetic part and the second magnetic part is when switching the pivot structure from the locking state to the unblock state for the pivot cover can shift out from the pivot, and it is convenient to dismantle.

In a specific embodiment, the pick is made of a ferromagnetic material, and the second magnetic member is a magnet. The magnetic force action between the first magnetic member and the second magnetic member is realized by the attractive force between the ferromagnetic substance and the magnet.

In a specific embodiment, a clamping groove is formed in the first body, and the magnet is embedded in the clamping groove to realize the fixed connection of the magnet relative to the first body.

In a specific embodiment, the magnet is embedded in the rotating shaft sleeve and is located on the side of the rotating shaft sleeve opposite to the shifting piece. Thereby realize the fixed connection of magnet relative second body, the structure is simpler.

In a specific embodiment, the second magnetic member is a magnet, another magnet is disposed on the pick and is opposite to the magnet, the two magnets are disposed on the second body oppositely, and the two opposite ends of the two magnets have the same magnetism. The magnetic action between the first magnetic part and the second magnetic part is realized by the repulsive force between the two magnets.

In a specific embodiment, a groove is formed in the second body, and the second magnetic member is embedded in the groove to realize the fixed connection of the second magnetic member relative to the second body.

In a specific embodiment, a sliding groove is formed in the second body, and the shifting piece is slidably mounted in the sliding groove. The shifting piece is matched with the sliding groove relatively to ensure the slidable connection of the shifting piece on the second body.

In one embodiment, the configuration of the pick has various forms, such as that the pick includes a sliding plate and a pick post disposed on the sliding plate, the thickness of the sliding plate is not greater than the width of the sliding slot, the sliding plate is slidably connected with the sliding slot, and the pick post protrudes from the sliding slot.

In one embodiment, the first body is a glasses frame, and the second body is a glasses leg, but the first body may be a glasses leg, and the second body may be a glasses frame.

Drawings

Fig. 1 is a schematic structural diagram of smart glasses according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of smart glasses provided in an embodiment of the present application at a connection position of a temple and a frame;

fig. 3 is another schematic structural diagram of smart glasses provided in another embodiment of the present application at a connection position of a temple and a frame;

FIG. 4 is an exploded view of the smart glasses of FIG. 2 in the temple and frame attachment position;

FIG. 5 is a cross-sectional view of the smart glasses of FIG. 2 in a locked state at a connection position of the temple bars and the frame;

FIG. 6 is a cross-sectional view of the smart glasses of FIG. 2 in an unlocked state with the temple bars and the frame in a connected position;

FIG. 7 is an exploded view of the smart eyewear of FIG. 2 in an attached position with the temple and frame in an alternative attached relationship;

FIG. 8 is a cross-sectional view of the smart eyewear of FIG. 3 in a locked position with the temple arms and frame in an alternative relationship;

FIG. 9 is a cross-sectional view of the smart eyewear of FIG. 3 in an unlocked position with the temple arms and frame in an alternative relationship;

FIG. 10 is a cross-sectional view of the smart glasses of FIG. 3 in a locked state with the temple bars and the frame in a connected position;

fig. 11 is a sectional view of the smart glasses of fig. 3 in an unlocked state at a connecting position of the temple and the frame.

Detailed Description

The terminology used in the following examples is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in the specification of this application and the appended claims, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, such as "one or more", unless the context clearly indicates otherwise. It should also be understood that in the following embodiments of the present application, "at least one", "one or more" means one, two or more. The term "and/or" is used to describe an association relationship that associates objects, meaning that three relationships may exist; for example, a and/or B, may represent: a alone, both A and B, and B alone, where A, B may be singular or plural. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship.

Reference throughout this specification to "one embodiment" or "some embodiments," or the like, means that a particular feature, structure, or characteristic described in connection with the embodiment is included in one or more embodiments of the present application. Thus, appearances of the phrases "in one embodiment," "in some embodiments," "in other embodiments," or the like, in various places throughout this specification are not necessarily all referring to the same embodiment, but rather "one or more but not all embodiments" unless specifically stated otherwise. The terms "comprising," "including," "having," and variations thereof mean "including, but not limited to," unless expressly specified otherwise. For convenience of understanding, first, a few terms mentioned in the following embodiments of the present application are introduced, and the smart glasses refer to a wearable device having an independent operating system by installing a hardware structure carrying various software programs such as music, conversation, game, etc. on a common glasses structure according to the requirements of a user; the rotating shaft structure is a structural form which can realize the connection between two connected components and can enable one component to rotate relative to the other component; the magnetic member may be a magnetic substance or a substance that can be influenced by other magnetic substances; the magnetic action may be an attractive force between the two magnetic members or a repulsive force between the two magnetic members. The application scenes of the intelligent glasses provided by the embodiment of the application are described next, the intelligent glasses can be folded and stored like common glasses, the intelligent glasses can also be suitable for different man-machine interaction scenes, and when a user wears the intelligent glasses, the user can control the intelligent glasses through voice or actions to complete functions of adding schedules, map navigation, interacting with friends, shooting photos and videos, and unfolding video calls with friends.

Aiming at the requirements of how the intelligent glasses are compatible with different head circumferences of consumers, the existing intelligent glasses have different development directions, for example, the adjusting belts are used for replacing the glasses legs of the existing glasses, only the length of the adjusting belts is needed to be adjusted according to different head circumferences, the fixing of the adjusting belts is realized through the magic tapes, but the fixing of the intelligent glasses on the head of a user in the mode is greatly influenced by the fastening force of the magic tapes, the fastening force of the existing magic tapes is smaller, the phenomenon that the magic tapes are not firmly bonded is easy to occur after the intelligent glasses are used for a period of time, the user experience is poorer, the rotating shaft structures of the glasses frame and the glasses legs in the common glasses are not changed by the intelligent glasses of the other part, the glasses frames are separated from the glasses legs by disassembling the rotating shaft structures of the glasses legs, then the screws which are suitable for the user are changed to meet the requirements of different users, but the rotating shaft structures in the mode are used as the screws for locking the glasses legs and the glasses frames, in order to lock the glasses legs and the glasses frame, the screws are connected firmly, the screws are generally difficult to detach, the screws can be detached only by means of tools, and the glasses are difficult to achieve. In the embodiment of the present application, by changing the structural form of the rotating shaft structure and the locking manner of the rotating shaft structure, the smart glasses can be quickly assembled and disassembled to meet the requirements of different users, and the following describes the smart glasses provided in the embodiment of the present application in detail with reference to the accompanying drawings. For the convenience of description, it is inboard that the one side that is close to user's face when setting for intelligent glasses and wearing is intelligent glasses, and the one side of keeping away from user's face is the outside of intelligent glasses, and the one side that is close to user's shoulder is the downside of intelligent glasses, and the one side of keeping away from user's shoulder is the upside of intelligent glasses.

An exemplary embodiment of the application provides an intelligent glasses, including the glasses body, pivot structure and this triplex of locking structure, the glasses body is used for bearing various function software that the relative ordinary glasses of intelligent glasses add so that this intelligent glasses are applicable to different human-computer interaction scenes, and wear user's head, thereby pivot structure is used for realizing the rotation of glasses body and connects the folding demand of accomodating that satisfies intelligent glasses, locking structure is used for locking pivot structure, and unblock pivot structure when needs are changed. Exemplarily, fig. 1 shows a specific structure of smart glasses provided in an embodiment of the present application, and the smart glasses include a first body 100 and a second body 200, where the first body 100 is a glasses frame and the second body 200 is a glasses leg, and of course, the first body 100 may be a glasses leg and the second body 200 may be a glasses frame. It is understood that the specific structural form of the first body 100 does not affect the realization of the functions of the hinge structure 300 and the locking structure 400.

With continuing reference to fig. 1, fig. 1 shows a connection relationship between a first body 100 and a second body 200, a rotation shaft structure 300 is arranged between the first body 100 and the second body 200, and a rotation fit is realized through the rotation shaft structure 300, and in order to meet head circumference requirements of different users, on the basis of the original intelligent glasses function, the first body 100 and the second body 200 need to be quickly assembled and disassembled, the present application improves the rotation shaft structure in the prior art, and refers to fig. 2 and fig. 3 together, fig. 2 shows a specific structure of the rotation shaft structure 300, fig. 3 shows another specific structure of the rotation shaft structure 300, when specifically setting, a rotation shaft column 110 is arranged at an end of the first body 100, the rotation shaft column 110 and the first body 100 may be of a split structure, and by cutting process molding or by injection molding at one time, the rotation shaft column 110 and the first body 100 may also be of a split structure, connecting through a glue dispensing or embedding process; the end of the second body 200 is provided with a rotating shaft sleeve 210, similarly, the rotating shaft sleeve 210 and the second body 200 can be of an integrated structure, and are formed by a cutting process or injection molding at one time, and the rotating shaft sleeve 210 and the second body 200 can also be of a split structure and are connected by a dispensing or embedding process; the pivot cover 210 joint forms pivot structure 300 on pivot post 110, and the direction of joint has two kinds, as shown in fig. 2, and on pivot cover 210 from the inboard joint of first body 100 to pivot post 110, as shown in fig. 3, pivot cover 210 from the outside joint of first body 100 to pivot post 110, and these two kinds of joint modes are all convenient operation swift, easily realize. The rotating shaft structure 300 is in a locking state under the action of the magnetic force of the locking structure 400, is in an unlocking state after overcoming the action of the magnetic force of the locking structure 400, and when in the locking state, the rotating shaft column 110 is in rotating fit with the rotating shaft sleeve 210, so that the rotating connection between the first body 100 and the second body 200 can be realized, and at the moment, the second body 200 can rotate relative to the first body 100, so that the folding and the storage of the intelligent glasses can be realized; when the rotary shaft column 110 and the rotary shaft sleeve 210 are in the unlocking state, the matching relation between the rotary shaft sleeve 210 and the rotary shaft column 110 is released, the rotary shaft sleeve 210 and the rotary shaft column 110 can be separated, and the second body 200 can be replaced at the moment so as to meet the head circumference requirements of different users.

Referring to fig. 4 together, fig. 4 shows a specific structure of the hinge structure 300, the hinge post 110 is protrudingly disposed at one end of the first body 100, when the first body 100 is a frame, the hinge post 110 is protrudingly disposed at a position where the frame is far away from the lenses, and when the first body 100 is a temple, the hinge post 100 is protrudingly disposed at a position where the temple is close to the lenses. The specific structure of the rotating shaft column 110 includes a rotating shaft 111, a top plate 112, a bottom plate 113 and side plates 114, wherein the top plate 112 and the bottom plate 113 are oppositely disposed, located at the upper and lower sides of the rotating shaft 111 and connected to the upper and lower end faces of the rotating shaft 111, the side plates 114 are connected to the top plate 112 and the bottom plate 113, and the rotating shaft 111 and the side plates 114 have a certain distance therebetween, so that the opening space formed by the bottom plate 112, the side plates 114 and the bottom plate 113 is divided into two parts, one part is used for clamping the rotating shaft sleeve 210, and the other part is used for installing the locking structure 400.

With continued reference to fig. 4, fig. 4 shows a specific structure of the glasses body and the rotation shaft structure 300, the rotation shaft sleeve 210 is protrudingly disposed at one end of the second body 200, the rotation shaft sleeve 210 is a non-closed type sleeve structure, when the second body 200 is a frame, the rotation shaft sleeve 210 is protrudingly disposed at a position where the frame is far away from the lenses, and when the second body 200 is a temple, the rotation shaft sleeve 210 is protrudingly disposed at a position where the temple is close to the lenses. When the rotating shaft structure 300 is specifically arranged, the surface of the first body 100 opposite to the rotating shaft 111 is a first arc surface 120, the first arc surface 120 is coaxial with the rotating shaft 111, and the surfaces of the top plate 112 and the bottom plate 113, which are in contact with the first arc surface 120, are also arc surfaces; the outer surface 211 of the rotating shaft sleeve 210 is an arc surface and is coaxial with the rotating shaft 111, when the rotating shaft sleeve 210 is clamped on the rotating shaft column 110, the outer surface 211 of the rotating shaft sleeve 210 is matched with the first arc surface 120, so that the rotating shaft sleeve 210 cannot interfere with the end surface of the first body 100 when rotating around the rotating shaft 111, the rotating fit between the rotating shaft sleeve 210 and the rotating shaft column 110 is facilitated, and the reliability of the rotating connection between the first body 100 and the second body 200 and the fluency of the movement between the first body 100 and the second body 200 are ensured. Referring to fig. 5, fig. 5 shows a specific structure of the rotating shaft sleeve 210, wherein the inner surface 212 of the rotating shaft sleeve 210 includes two parts, a second arc surface 2121 connected to the second body 200 and a plane surface 2122 connected to the second arc surface, wherein the second arc surface 2121 is coaxial with the rotating shaft 111 so as to achieve the rotating fit between the rotating shaft sleeve 210 and the rotating shaft column 110, and the plane surface 212 is tangent to the rotating shaft 111 so as to achieve the quick assembly and disassembly between the rotating shaft sleeve 210 and the rotating shaft column 110.

In particular arrangements of second cambered surface 2121, the angle of second cambered surface 2121 may range between 120 ° -210 °. Preferably, the angle of the second cambered surface 2121 is 120 °, 130 °, 140 °, 150 °, 160 °, 170 °, 180 °, 190 °, 200 °, 210 °. It can be understood that factors such as the size of the smart glasses, the application scenario, or the installation space of the rotating shaft structure 300 need to be considered comprehensively when the angle of the second cambered surface 2121 is specifically selected. With continued reference to fig. 5, the second arc surface 2121 is tangent to the plane 2122, the plane 2122 is connected to the outer surface 211 of the spindle sleeve 210 to cover the spindle 111, and the outer surface 211 of the spindle sleeve 210 is matched with the first arc surface 120 to enable the spindle sleeve 210 to be well clamped on the spindle post 110, so as to ensure that the spindle post 110 and the spindle sleeve 210 are reliably connected, thereby enabling the spindle structure 300 to have good stability.

With continuing reference to fig. 2, 3, 4 and 5, fig. 2 shows one position of the locking structure 400, fig. 3 shows another position of the locking structure 400, fig. 4 shows a specific structure of the locking structure 400, fig. 5 shows a specific installation structure of the locking structure 400, the locking structure 400 includes a first magnetic member 410 and a second magnetic member 420, a magnetic force action is provided between the first magnetic member 410 and the second magnetic member 420, a magnitude of the magnetic force action between the first magnetic member 410 and the second magnetic member 420 is changed due to a change of a distance between the first magnetic member 410 and the second magnetic member 420, when the smart glasses are assembled, the distance between the first magnetic member 410 and the second magnetic member 420 is fixed, the magnetic force action between the first magnetic member 410 and the second magnetic member 420 is fixed, and the magnetic force action at this time locks the rotating shaft structure 300, at this time, the smart glasses can be worn, and the rotating shaft structure can be locked by the magnetic action, Folding and accommodating the intelligent glasses; referring to fig. 6 together, fig. 6 shows a specific position of the first magnetic member 410, the first magnetic member 410 is slidably mounted on the second body 200, the distance between the first magnetic member 410 and the second magnetic member 420 is changed by moving the first magnetic member 410, and the magnetic force action between the first magnetic member 410 and the second magnetic member 420 is further changed, when the magnetic force action between the first magnetic member 410 and the second magnetic member 420 is overcome, the rotating shaft structure 300 is switched from the locked state to the unlocked state, and at this time, the connection state of the rotating shaft structure 300 is released, the rotating shaft sleeve 210 and the rotating shaft column 110 can be disengaged, and the second body 200 can be replaced. As can be seen from the above description, the intelligent glasses can be quickly disassembled and replaced with the second body 200, so that the use requirements of different users are met.

With continuing reference to fig. 2 and 3, fig. 2 shows one mounting position of the first magnetic element 410, fig. 3 shows another mounting position of the first magnetic element 410, and when the specific arrangement is performed, the first magnetic element 410 is a pick with one end protruding out of the second body 200, as shown in fig. 2, the first magnetic element 410 protrudes out of the upper side of the second body 200, as shown in fig. 3, the first magnetic element protrudes out of the inner side of the second body 200, although the specific position of the first magnetic element 410 is not limited to the above two, and may also be disposed at the lower side of the second body 200 or the outer side of the second body 200. In order to realize that the first magnetic element 410 is slidably mounted on the second body 200 when the first magnetic element 410 is specifically arranged, with reference to fig. 3, 4, 5, 6 and 7, fig. 3 shows one position of the first magnetic element 410 on the second body 200, fig. 4 shows a specific structure of the second body 200, fig. 5 shows another position of the first magnetic element 410 on the second body 200, fig. 6 shows still another position of the first magnetic element 410 on the second body 200, the second body 200 is provided with a sliding slot 220, and the dial is slidably mounted in the sliding slot 220. As shown in fig. 3, the sliding slot 220 is opened on the end surface of the second body 200 at the same end as the rotating shaft sleeve 210 and the inner side surface of the second body 200, and extends toward the inside of the second body 200, as shown in fig. 4 and 7, the sliding slot 220 is opened on the end surface of the second body 200 at the same end as the rotating shaft sleeve 210 and the upper side surface of the second body 200, and extends toward the inside of the second body 200, and the sliding connection of the poking piece on the second body 200 is ensured by the relative fit of the poking piece and the sliding slot 220. In the specific arrangement, the sliding slot 220 and the rotating shaft sleeve 210 can be manufactured and molded at one time, or two partition plates can be added in the slot on the second body 200 after the rotating shaft sleeve 210 and a slot are cut out, and the two partition plates are matched with the second body 200 to form the sliding slot 220.

The structural form of the pick can be various, as shown in fig. 4, the pick includes a pick column 411 and a sliding plate 412, the pick column 411 is convexly disposed on the sliding plate 412, the pick column 411 is disposed above the sliding plate 412 in fig. 4, and the arrangement direction of the pick column 411 on the sliding plate 412 can be changed according to the position of the sliding slot 220 on the second body 200. In order to enable the sliding plate 412 to slide well in the sliding groove 220, it is necessary to define a dimensional relationship between the sliding plate 41 and the sliding groove 220, and when the sliding plate 412 is specifically set, the thickness of the sliding plate 412 is not larger than the width of the sliding groove 220, and when the sliding plate 412 is slidably connected with the sliding groove 220, the sliding plate 412 slides in the sliding groove 220, and the column dial 411 protrudes outside the sliding groove 220. The shifting column 411 and the sliding plate 412 can be of an integrated structure and are integrally formed through cutting, stamping and other processes, the shifting column 411 and the sliding plate 412 can also be of a split structure, and then the shifting column 41 is fixed on the sliding plate 412 through welding and other processes.

When the shifting piece is selected specifically, the shifting piece can be made of ferromagnetic substances, and can be made of metals such as iron, nickel or cobalt, or alloys and compounds of iron, nickel or cobalt, and the second magnetic part 420 can be a magnet which has strong adsorption force on the ferromagnetic substances. The magnetic force between the first magnetic member 410 and the second magnetic member 420 can be realized by the adsorption force between the ferromagnetic substance and the magnet, and the distance between the ferromagnetic substance and the magnet increases when the pick is moved toward the direction away from the magnet, the adsorption force decreases, and the external force overcomes the magnetic force between the first magnetic member 410 and the second magnetic member 420. Of course, the further pick may be a magnet, and the opposite end of the magnet has the same polarity, so as to enhance the magnetic force between the first magnetic member 410 and the second magnetic member 420, and ensure the stability of the rotating shaft structure 300 in the locked state.

When the magnetic force acting between the first magnetic element 410 and the second magnetic element 420 is defined as an attraction force, the second magnetic element 420 has a plurality of arrangements, and two preferred arrangements will be described below with emphasis on the arrangement, but the arrangement of the second magnetic element 420 is not limited to these two arrangements.

In a first mode, the second magnetic member 420 is disposed on the first body 100, with continuing reference to fig. 4, 5 and 6, fig. 4 shows a specific structure of the smart glasses, fig. 5 and 6 show a specific structure of the second magnetic member 420, the first body 100 is provided with the slot 130, the second magnetic member 420 is a magnet, the second magnetic member 420 is inserted into the slot 130 from a space where the side plate 114 and the rotating shaft 111 are opposite, and then is fitted with the slot 130, so that the second magnetic member 420 is fixedly connected to the first body 100, at this time, the change of the magnetic effect between the first magnetic member 410 and the second magnetic member 420 can be adjusted only by moving the dial, and the structure is simple and easy to operate.

With continuing reference to fig. 5 and fig. 6, fig. 5 shows one position of the first magnetic member 410, fig. 6 shows another position of the first magnetic member 410, and the pick is slidably disposed in the space between the side plate 114 and the rotating shaft 111, as shown in fig. 5, when the second body 200 does not need to be replaced, the rotating shaft structure 300 is in a locked state, the sliding plate 412 is attracted by the second magnetic member 420 positioned in the slot 130 of the first body 100, the sliding plate 412 is inserted into the space where the side plate 114 and the rotating shaft 111 are opposite, at this time, one end of the rotating shaft sleeve 210 and one end of the second magnetic member 420 are positioned on the second body 200, the other end of the rotating shaft sleeve is positioned on both sides of the rotating shaft 111, the rotating shaft sleeve 210 cannot be separated from the rotating shaft column 110 due to the attraction force between the sliding plate 412 and the first magnetic member 410, moreover, the rotating shaft sleeve 210 is in rotating fit with the rotating shaft column 110, so that the second body 200 can rotate relative to the first body 100, and the intelligent glasses can be folded and stored; when the second body 200 needs to be replaced, by moving the pick in a direction away from the first body 100, the user applies a force to the sliding plate 412 to overcome the magnetic force between the first magnetic member 410 and the second magnetic member 420, so that the sliding plate 412 slides towards the inside of the sliding slot 220 in a direction away from the first body 100, as shown in fig. 6, the sliding plate 412 exits from the space where the side plate 114 and the rotating shaft 111 are opposite, the rotating shaft structure 300 is switched from the locking state to the unlocking state, at this time, the user can move the rotating shaft sleeve 210 out of the rotating shaft 111, and thus the second body 200 can be separated from the first body 100 to replace the second body 200.

Secondly, the second magnetic member 420 is disposed on the rotating shaft sleeve 210, and referring to fig. 7, 8 and 9 together, fig. 7 shows a specific structure of the smart glasses, fig. 8 and 9 show another specific structure of the second magnetic member 420, the second magnetic member 420 is a magnet, the second magnetic member 420 is embedded on the rotating shaft sleeve 210, and the second magnetic member 420 is located on a side of the rotating shaft sleeve 210 opposite to the plectrum, when the specific arrangement is performed, a part of the side of the rotating shaft sleeve 21 opposite to the sliding slot 220 can be cut off, and then the second magnetic member 420 is embedded in the cut, at this time, the second magnetic member 420 is flush with the plane 2122 of the rotating shaft sleeve 210 or is lower than the plane 2122 of the rotating shaft sleeve 210, so as to ensure that the rotating shaft sleeve 210 can still cooperate with the rotating shaft column 110 to form a rotating shaft structure after the second magnetic member 420 is embedded in the rotating shaft sleeve 210, thereby realizing the fixed connection of the second magnetic member 420 with the first body 100, at this time, the change of the magnetic action between the first magnetic member 410 and the second magnetic member 420 can be adjusted only by shifting the shifting piece, and the structure is simpler and the operation is easier.

With continuing reference to fig. 8 and 9, fig. 8 shows one position of the first magnetic member 410, fig. 9 shows another position of the first magnetic member 410, and the pick is slidably disposed in the space between the side plate 114 and the rotating shaft 111, as shown in fig. 8, when the second body 200 does not need to be replaced, the rotating shaft structure 300 is in a locked state, the sliding plate 412 is attracted by the second magnetic member 420 on the rotating shaft sleeve 210, the sliding plate 412 is inserted into the space where the side plate 114 and the rotating shaft 111 are opposite, at this time, one end of the rotating shaft sleeve 210 and one end of the second magnetic member 420 are located on the second body 200, the other end is located on both sides of the rotating shaft 111, the rotating shaft sleeve 210 cannot be separated from the rotating shaft column 110 due to the attraction force between the sliding plate 412 and the first magnetic member 410, meanwhile, the rotating shaft sleeve 210 is in rotating fit with the rotating shaft column 110, so that the second body 200 can rotate relative to the first body 100, and the intelligent glasses can be folded and stored; when the second body 200 needs to be replaced, by moving the pick in a direction away from the first body 100, the user applies a force to the sliding plate 412 to overcome the magnetic force between the first magnetic member 410 and the second magnetic member 420, so that the sliding plate 412 slides towards the inside of the sliding slot 220 in a direction away from the first body 100, as shown in fig. 8, the sliding plate 412 exits from the space where the side plate 114 and the rotating shaft 111 are opposite, the rotating shaft structure 300 is switched from the locking state to the unlocking state, at this time, the user can move the rotating shaft sleeve 210 out of the rotating shaft 111, and thus the second body 200 can be separated from the first body 100 to replace the second body 200.

When the plectrum is specifically selected, as shown in fig. 3, 10 and 11, fig. 3 shows the overall structure of the smart glasses, fig. 10 shows the specific structure of the locking structure 400, and unlike the above-mentioned magnetic force between the first magnetic member 410 and the second magnetic member 420, which is the adsorption force, the second magnetic member 420 is a magnet in the embodiment of the present application, and the other structural form of the plectrum, in which the magnet is the first magnet, is that a second magnet 413 opposite to the first magnet is provided on the end surface of one end of the plectrum facing away from the rotating shaft sleeve 210. The second body 200 is provided with a groove 230, and the second magnetic member 420 is embedded in the groove 230 to realize the fixed connection of the second magnetic member 420 relative to the second body 200.

At this time, the material of the pick has many choices, and may be a metal material or a plastic material, and the pick and the second magnet 413 may have an integrated structure, that is, the pick and the second magnet 413 have the same material, and are formed at one time through processes such as cutting, and when the first magnet and the second magnet 413 are specifically arranged, the first magnet and the second magnet 413 are oppositely arranged on the second body 200, and the magnetism of the opposite end of the first magnet and the opposite end of the second magnet 413 are the same. The magnetic force action between the first magnetic member 410 and the second magnetic member 420 is achieved by the repulsive force between the first magnet and the second magnet 413. When the pick is moved away from the first magnet, the distance between the first magnet and the second magnet 413 increases, the attraction force decreases, and the user applies an external force to overcome the magnetic force between the first magnetic member 410 and the second magnetic member 420.

With continuing reference to fig. 3, 10 and 11, fig. 3 shows a specific structure of the smart glasses, fig. 10 shows one position of the sliding plate 412, fig. 11 shows another position of the sliding plate 412, the poking plate is slidably disposed in the space where the side plate 114 and the rotating shaft 111 are opposite, as shown in fig. 10, when the second body 200 does not need to be replaced, the rotating shaft structure 300 is in a locked state, the sliding plate 412 is inserted into the space where the side plate 114 and the rotating shaft 111 are opposite under the action of the repulsive force between the first magnet and the second magnet 413, at this time, one end of the rotating shaft sleeve 210 and the first magnetic member 410 is located on the second body 200, the other end is located on both sides of the rotating shaft 111, the attractive force between the sliding plate 412 and the second magnetic member 420 makes the rotating shaft sleeve 210 unable to be separated from the rotating shaft column 110, and the rotating shaft sleeve 210 is rotatably engaged with the rotating shaft column 110, so that the second body 200 can rotate relative to the first body 100, thereby realizing the folding and the storage of the intelligent glasses; when the second body 200 needs to be replaced, by moving the pick in a direction away from the first body 100, the user applies a force to the sliding plate 412 to overcome the magnetic force between the first magnetic member 410 and the second magnetic member 420, so that the sliding plate 412 slides towards the inside of the sliding slot 220 in a direction away from the first body 100, as shown in fig. 11, the sliding plate 412 exits from the space where the side plate 114 and the rotating shaft 111 are opposite, the rotating shaft structure 300 is switched from the locking state to the unlocking state, at this time, the user can move the rotating shaft sleeve 210 out of the rotating shaft 111, and thus the second body 200 can be separated from the first body 100 to replace the second body 200.

The above description is only for the 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 conceive of the changes or substitutions within the technical scope of the present application, and shall 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 (11)

1. The utility model provides an intelligent glasses, its characterized in that, includes glasses body and locking structure, wherein:

the glasses body comprises a first body and a second body, the first body is provided with a rotating shaft column, the second body is provided with a rotating shaft sleeve, and the rotating shaft sleeve is clamped on the rotating shaft column to form a rotating shaft structure;

the locking structure comprises a first magnetic part and a second magnetic part, the first magnetic part is slidably mounted on the second body, the second magnetic part is mounted on the first body or the second body, the rotating shaft structure is locked under the action of magnetic force between the first magnetic part and the second magnetic part, and the rotating shaft structure is switched from a locking state to an unlocking state when the action of magnetic force between the first magnetic part and the second magnetic part is overcome;

the rotating shaft column is convexly arranged at one end of the first body and comprises a rotating shaft, a top plate and a bottom plate which are oppositely arranged at two sides of the rotating shaft, and a side plate for connecting the top plate and the bottom plate, the top plate and the bottom plate are respectively connected with the rotating shaft, the surface of the first body, which is opposite to the rotating shaft, is a first cambered surface, the first cambered surface is coaxial with the rotating shaft, the rotating shaft sleeve is convexly arranged at one end of the second body, and the outer surface of the rotating shaft sleeve is coaxial with the rotating shaft;

the first magnetic part is a shifting piece with one end protruding out of the second body, the shifting piece is slidably arranged in a space where the side plate and the rotating shaft are opposite, the shifting piece is inserted into the space where the side plate and the rotating shaft are opposite when the rotating shaft structure is in a locking state, and the shifting piece is moved out of the space where the side plate and the rotating shaft are opposite when the rotating shaft structure is in an unlocking state.

2. The smart eyewear of claim 1, wherein the inner surface of the swivel sleeve comprises a second arcuate surface coaxial with the swivel axis and a plane tangent to the swivel axis.

3. The smart eyewear of claim 2, wherein the angle of the second arcuate surface is between 120 ° and 210 °.

4. The smart eyewear of claim 1, wherein the paddle is made of a ferromagnetic material and the second magnetic member is a magnet.

5. The smart eyewear of claim 4 wherein the first body defines a slot, and the magnet is embedded in the slot.

6. The pair of smart glasses of claim 4 wherein the magnet is embedded in the shaft sleeve and located on a side of the shaft sleeve opposite to the paddle.

7. The pair of smart glasses according to claim 1, wherein the second magnetic member is a magnet, another magnet is disposed on the pick opposite to the magnet, the two magnets are disposed on the second body opposite to each other, and the two magnets have the same magnetism at opposite ends.

8. The smart eyewear of any of claims 1-7, wherein the second body defines a channel, and the paddle is slidably mounted within the channel.

9. The smart eyewear of claim 7, wherein the second body defines a recess, and the second magnetic member is embedded in the recess.

10. The smart eyewear of any one of claims 1-7 wherein the second body defines a slot, the paddle includes a slider and a paddle disposed on the slider, the slider has a thickness not greater than a width of the slot, the slider is slidably coupled to the slot, and the paddle protrudes from the slot.

11. The smart eyewear of any of claims 1-7, wherein the first body is a frame and the second body is a temple.

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