CN115793252B - AR glasses receiver and AR intelligent glasses using same - Google Patents

Abstract

The application discloses an AR glasses storage box and AR intelligent glasses using the same, comprising AR glasses and an AR glasses body; the device comprises a placement unit, a storage unit and a storage unit, wherein the placement unit comprises a shell arranged on the AR glasses, a containing cavity arranged in the shell, a slideway arranged on the inner wall of the containing cavity, a spring telescopic rod arranged on the side surface of the containing cavity and a sliding block arranged in the slideway, and the slideway is connected with the spring telescopic rod in a sliding manner; the mobile phone cleaning device comprises a cleaning unit, wherein the cleaning unit comprises a first spring gear arranged on the side face of a slideway, a second spring gear arranged on the inner wall of a containing cavity, and a transmission rod which is rotatably connected with the inner wall of the containing cavity at two ends and a cleaning component which is slidably connected with the transmission rod.

Description

AR glasses receiver and AR intelligent glasses using same

Technical Field

The application relates to the AR field, in particular to an AR glasses storage box and AR intelligent glasses using the same.

Background

Along with the development of man-machine interaction technology, AR glasses are increasingly applied to daily life of people, such as movie watching, game playing, road condition navigation, etc. The AR glasses in the market at present are limited by the field of view (FOV) of AR display of the product, and most of AR glasses can select to fully utilize limited space based on the preferential field of view, so that the display area is greatly limited and the interactive mode is single;

at present, the AR augmented reality technology is a new technology for integrating real world information and virtual world information in a seamless mode, and is characterized in that entity information which is difficult to experience in a certain time space range of the real world originally is overlapped after simulation through scientific technologies such as a computer, virtual information is applied to the real world and perceived by human senses, so that sense organ experience exceeding reality is achieved. The real environment and the virtual object are superimposed on the same picture or space in real time, so that people feel the existence of the real environment and the virtual object.

With the rapid development of information technology, glasses with information access and display functions such as google glasses and apple glasses display have appeared, and the functions of sound control, navigation, photographing, video chat and the like are primarily provided, so that the application of functions based on the glasses is greatly enhanced; the interaction between the mobile phone and the AR intelligent glasses can be realized by the existing partial AR intelligent glasses, but the mobile phone is embedded in the AR intelligent glasses, so that the AR intelligent glasses and the mobile phone are not firmly matched, and the situation of unclear view can be caused by dirt existing on a mobile phone screen, so that a device capable of firmly fixing the mobile phone on the AR intelligent glasses and realizing the cleaning of the mobile phone screen is needed.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present application has been made in view of the problems occurring in the prior art.

Therefore, the technical problems to be solved by the application are that the interaction mode is single, the AR intelligent glasses and the mobile phone cannot be firmly connected, the mobile phone screen cannot be cleaned in time, and the user experience is seriously affected.

In order to solve the technical problems, the application provides the following technical scheme: an AR glasses display method includes establishing a reference position of the AR glasses;

acquiring a rotation angle of the AR glasses based on the reference position;

based on the rotation angle, controlling the canvas to move towards the direction opposite to the rotation angle;

determining a selected functional module according to the position of an anchor point on a display screen on the canvas;

and recalibrating the positions of the AR glasses after the interaction control as reference positions.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: horizontal rotation angle, vertical rotation angle and deflection angle;

and when the displacement acceleration is within a preset range, executing the functional unit selected by the anchor point to complete the interaction control.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: a view boundary is arranged in the rotation direction of the AR glasses;

and when the AR glasses rotate to the current interface which is the view boundary, reminding, and recalibrating the current position of the AR glasses as a reference position.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: based on the rotation angle, the canvas is controlled to move towards the direction opposite to the rotation angle specifically comprises the following steps: based on the horizontal rotation angle, the canvas is controlled to move towards the direction opposite to the horizontal rotation angle, so that the movement control of the canvas in the horizontal direction is realized;

based on the vertical rotation angle, the canvas is controlled to move towards the direction opposite to the vertical rotation angle, so that the movement control of the canvas in the vertical direction is realized;

and based on the deflection angle, controlling the canvas to rotate towards the direction opposite to the deflection angle, and realizing the movement control of the canvas in the deflection direction.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: and acquiring a display area of the canvas in the vertical direction, and activating movement control of the canvas in the vertical direction when the display area exceeds the display range of the AR glasses.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: and when the canvas is controlled to move towards the direction opposite to the rotation angle based on the rotation angle, filtering the rotation angle generated by fine jitter and signal interference of the AR glasses by adopting a filtering algorithm.

As a preferable embodiment of the AR glasses displaying method of the present application, the method further includes: setting a minimum rotation angle threshold, and fixing the canvas when the rotation angle of the AR glasses is smaller than the minimum rotation angle threshold;

and setting a minimum rotation time threshold, and fixing the canvas when the rotation time of the AR glasses is smaller than the minimum rotation time threshold.

The application has the beneficial effects that: detecting whether the interaction operation on the functional module and/or the canvas is triggered or not in real time through an interaction module arranged on the AR glasses; if the interactive operation is triggered, carrying out interactive control on the functional module and/or the canvas based on the operation type indicated by the interactive operation; the AR glasses after interactive control are recalibrated to be the reference positions, the purpose that more interactive operations are carried out by adopting an additional interactive module while the head rotation control canvas movement is adopted for interaction is achieved, and therefore the technical effects of increasing the AR display area and enriching the interactive modes of the AR glasses are achieved on the basis of not increasing hardware cost, and further the problems that the AR glasses in the related technologies are limited by view angles, the display area is limited greatly and the interactive modes are single are solved.

In view of the abrasion or loss that the AR glasses are not stored in time during use, a special storage box is needed to provide protection.

In view of the above problems, a preferred embodiment of an AR glasses case is proposed, wherein: including the receiving unit, the receiving unit includes the receiver, sets up in the inside holding chamber of receiver, accomodate the lid and set up in the radiator of receiver bottom terminal surface, the radiator includes the radiator casing, sets up radiator fan in the radiator casing, sets up the fin in radiator casing one side, runs through the circulating water pipe that sets up in the fin and set up the transfer piece in fin one side, radiator intercommunication holding chamber.

The second beneficial effect of the application is that: can effectually accomodate AR glasses, and the receiver still is from taking heat dissipation function, can in time dispel the heat to the AR glasses after the use, prevent that the too high damage inner structure of temperature.

As a preferable scheme of the AR intelligent glasses, the application comprises the following steps: the AR glasses are arranged in the accommodating cavity and are arranged on the outer side of the accommodating cavity;

the device comprises a placement unit, a storage unit and a storage unit, wherein the placement unit comprises a shell arranged on the AR glasses, a containing cavity arranged in the shell, a slideway arranged on the inner wall of the containing cavity, a spring telescopic rod arranged on the side surface of the containing cavity and a sliding block arranged in the slideway, and the slideway is connected with the spring telescopic rod in a sliding manner;

the cleaning unit comprises a first spring gear arranged on the side surface of the slideway, a second spring gear arranged on the inner wall of the accommodating cavity, a transmission rod with two ends rotatably connected with the inner wall of the accommodating cavity and a cleaning assembly connected with the transmission rod in a sliding manner; the AR glasses are recessed from the top end face to form a groove, and the placement unit is embedded into the groove; the top end surface of the shell is concavely provided with a placing groove, a straight groove and a stop block, the placing groove is communicated with the straight groove to accommodate a cavity (the top end surface of the slideway is convexly provided with a poking column, the poking column penetrates through the straight groove to extend out of the shell, the poking column is provided with a baffle column, and one side of the placing groove is provided with an arc edge;

the inner wall of the slideway is also provided with a chute, the side surface of the sliding block is provided with a lug, the lug is slidably embedded into the chute, the top end surface of the slideway is concavely provided with a paying-off groove, the bottom end surface of the paying-off groove is provided with a first wire hole, the first wire hole is communicated with the chute, the bottom end surface of the sliding block is also provided with a spring, and the lug is provided with a second wire hole; the side of slide is provided with the round hole, first round bar, the first spring of fixed connection first round bar one end and the fixed cover of coaxial center are established the first gear on first spring including the first dwang of coaxial center rotation connection round hole, fixedly connected with nylon rope on the first dwang, nylon rope runs through first line hole fixed connection second line hole.

As a preferable scheme of the AR intelligent glasses, the application comprises the following steps: the second spring gear comprises a second gear movably connected with the inner wall of the accommodating cavity, a second spring arranged on one side of the second gear and a second rotating rod fixedly connected with the second gear, one end of the first spring gear is also provided with a convex rod, one end of the second rotating rod is provided with a rotating tube, a square groove is formed in the rotating tube, the convex rod is coaxially embedded into the square groove, one end of the second spring is fixedly connected with the second rotating rod, and the other end of the second spring is fixedly connected with the inner wall of the accommodating cavity; the transmission rod comprises a worm and a track rod arranged at one end of the worm, the worm is meshed with the second gear, and a spiral groove is formed in the track rod; the cleaning assembly comprises a sleeve block sleeved on the track rod and a cleaning piece arranged on one side of the sleeve block, a first convex column is arranged on one side of the sleeve block, a first track is arranged on the inner wall of the accommodating cavity, the first convex column is embedded into the first track, a second convex column is arranged on one side of the cleaning piece, a second track is arranged on the inner wall of the accommodating cavity, and the second convex column is embedded into the second track; a round rod is formed on the inner wall of the sleeve block in a protruding mode, one end of the round rod is connected with an embedded block in a rotating mode, and the embedded block is embedded into the spiral groove in a sliding mode; one end of the first rotating rod extending out of the round hole is provided with a wafer.

The third beneficial effect of the application is: the mobile phone can be effectively and firmly fixed on the AR intelligent glasses through the placement unit, meanwhile, the mobile phone can also play a role in shock absorption, and the cleaning unit can timely clean the mobile phone screen embedded into the AR intelligent glasses, so that the definition of the mobile phone screen is guaranteed.

Drawings

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

Fig. 1 is an overall expanded view of the device in a second embodiment.

Fig. 2 is a schematic diagram of a radiator in a second embodiment.

Fig. 3 is a schematic view of a housing in a third embodiment.

Fig. 4 is a schematic view of the interior of the housing in a third embodiment.

Fig. 5 is a diagram showing the positional relationship between the first spring gear and the second spring gear in the third embodiment.

Fig. 6 is a schematic view of a cleaning assembly in a third embodiment.

Fig. 7 is a schematic top view of a housing in a third embodiment.

Fig. 8 is a schematic view of a slider in a third embodiment.

Fig. 9 is a schematic diagram of a jacket block in a third embodiment.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

A first embodiment of the present application provides an AR glasses display method including,

establishing a reference position of the AR glasses; recalibrating the positions of the AR glasses after the interaction control to be reference positions;

specifically, it should be noted that, after the wearer adopts the interaction module to implement interaction control on the AR glasses, the reference position of the AR glasses needs to be recalibrated. For example, when the wearer slides the canvas using the interactive module or changes the positions of the respective functional modules in the canvas, and the wearer needs to control the canvas with head movements, the position of the current AR glasses may be calibrated to a new reference position using the three-axis gyroscope sensor, and then as the wearer's head rotates, a rotation angle of the AR glasses based on the new reference position is acquired, so that the new canvas moves again in response to the rotation angle,

when the reference position of the AR glasses is recalibrated, the wearer's head may be in a state after rotation or in a state in front of the front view. When the head of the wearer rotates to select a needed view, the interaction module intervenes to perform interaction control on the AR glasses, and at the moment, the canvas can not move along with the rotation of the head of the wearer, namely, the head of the wearer can rotate back to the position in front of the front view, so that the wearer can more comfortably experience the current view. In this state, the head control canvas movement may continue to be achieved by recalibrating the reference position of the AR glasses. It can be understood that when the head of the wearer rotates to select the needed view, the interaction module intervenes to perform interaction control on the AR glasses, and after the interaction control opens a new menu, the reference position of the AR glasses can be immediately recalibrated, so that the movement of the canvas through the head control in the new menu is realized;

acquiring a rotation angle of the AR glasses based on the reference position;

based on the rotation angle, controlling the canvas to move towards the direction opposite to the rotation angle;

determining a selected functional module according to the position of an anchor point on a display screen on the canvas;

and recalibrating the positions of the AR glasses after the interaction control as reference positions.

The rotation angle is specifically as follows: horizontal rotation angle, vertical rotation angle and deflection angle;

and when the AR glasses rotate to the current interface which is the view boundary, reminding, and recalibrating the current position of the AR glasses as a reference position.

Specifically, it should be noted that, when the wearer rotates the angle of the AR glasses too much to reach the view boundary of the canvas, the view contents on the canvas are completely displayed, and at this time, an explicit prompt is given to inform the wearer that the current angle has no content displayed. If the wearer rotates in the direction with the content, the current angle, that is, the current position of the AR glasses is taken as a datum point, the datum point is recalibrated, view boundaries are arranged at the left end and the right end of the canvas for the horizontal movement and the deflection movement of the canvas, and the view boundaries are arranged at the upper end and the lower end of the canvas for the vertical movement of the canvas.

Further, the rotation angle is specifically: horizontal rotation angle, vertical rotation angle and deflection angle. It will be appreciated that in the cartesian coordinate system, the horizontal rotation angle is the rotation angle around the Z axis, the vertical rotation angle is the rotation angle around the Y axis, and the yaw angle is the rotation angle around the X axis.

Based on the rotation angle, the canvas is controlled to move towards the direction opposite to the rotation angle specifically comprises the following steps:

based on the horizontal rotation angle, the canvas is controlled to move towards the direction opposite to the horizontal rotation angle, so that the movement control of the canvas in the horizontal direction is realized;

based on the vertical rotation angle, the canvas is controlled to move towards the direction opposite to the vertical rotation angle, so that the movement control of the canvas in the vertical direction is realized;

based on the deflection angle, the canvas is controlled to rotate towards the direction opposite to the deflection angle, so that the movement control of the canvas in the deflection direction is realized, and specifically, it is to be noted that the head movement includes movements in three directions, namely, rotation around a Z axis (i.e., a horizontal rotation angle), rotation around a Y axis (i.e., a vertical rotation angle), rotation around an X axis (i.e., a deflection angle), so that in order to fully utilize the head movement to realize various interaction modes, the horizontal rotation angle, the vertical rotation angle and the deflection angle of the head are utilized in the embodiment.

And when the displacement acceleration is within a preset range, executing the functional unit selected by the anchor point to complete the interaction control.

The canvas is provided with a view boundary in the rotation direction of the AR glasses;

and when the AR glasses rotate to the current interface which is the view boundary, reminding, and recalibrating the current position of the AR glasses as a reference position.

Based on the rotation angle, the canvas is controlled to move towards the direction opposite to the rotation angle specifically comprises the following steps: based on the horizontal rotation angle, the canvas is controlled to move towards the direction opposite to the horizontal rotation angle, so that the movement control of the canvas in the horizontal direction is realized;

based on the vertical rotation angle, the canvas is controlled to move towards the direction opposite to the vertical rotation angle, so that the movement control of the canvas in the vertical direction is realized;

and based on the deflection angle, controlling the canvas to rotate towards the direction opposite to the deflection angle, and realizing the movement control of the canvas in the deflection direction.

And acquiring a display area of the canvas in the vertical direction, and activating movement control of the canvas in the vertical direction when the display area exceeds the display range of the AR glasses.

When the canvas is controlled to move towards the direction opposite to the rotation angle based on the rotation angle, a filtering algorithm is adopted to filter out the rotation angle generated by fine jitter and signal interference of the AR glasses.

Setting a minimum rotation angle threshold, and fixing the canvas when the rotation angle of the AR glasses is smaller than the minimum rotation angle threshold;

and setting a minimum rotation time threshold, and fixing the canvas when the rotation time of the AR glasses is smaller than the minimum rotation time threshold.

Example 2

Referring to fig. 1 and fig. two, in a second embodiment of the present application, the embodiment is based on the previous embodiment, and includes a storage unit 400, where the storage unit 400 includes a storage box 401, a storage cavity B disposed inside the storage box 401, a storage cover 402, and a radiator 403 disposed on a bottom end surface of the storage box 401, the radiator 403 includes a heat dissipation housing 403a, a heat dissipation fan 403B disposed in the heat dissipation housing 403a, a heat dissipation fin 403c disposed on one side of the heat dissipation housing 403a, a circulating water pipe 403d penetrating the heat dissipation fin 403c, and a transfer block 403e disposed on one side of the heat dissipation fin 403c, and the radiator 403 is communicated with the storage cavity B, after the AR glasses are used, the storage cover 402 is opened, the AR glasses are placed in the storage cavity B, then the storage cover 402 is covered, the radiator 403 is driven to operate, and a water pump disposed in the transfer block 403e drives the water flow in the circulating water pipe 403d to continuously circulate, so as to finally transport heat generated by the AR glasses out, thereby achieving the purpose of cooling.

Example 3

Referring to fig. 3 to 9, in a third embodiment of the present application, based on the previous embodiment, an AR smart glasses with an automatic cleaning function is provided, which is characterized in that: including, AR glasses 100, and; the AR glasses 100 adopted by the application can be matched with a mobile phone to realize 3D film viewing;

the placement unit 200 comprises a shell 201 arranged on the AR glasses 100, a containing cavity A arranged in the shell 201, a slideway 202 arranged on the inner wall of the containing cavity A, a spring telescopic rod 203 arranged on the side surface of the containing cavity A and a sliding block 204 arranged in the slideway 202, wherein the slideway 202 is in sliding connection with the spring telescopic rod 203;

the cleaning unit 300 comprises a first spring gear 301 arranged on the side surface of the slideway 202, a second spring gear 302 arranged on the inner wall of the accommodating cavity A, a transmission rod 303 with two ends in rotary connection with the inner wall of the accommodating cavity A and a cleaning component 304 in sliding connection with the transmission rod 303, wherein the mobile phone slides along the direction of the slideway 202 to drive the first spring gear 301 to rotate, the first spring gear 301 rotates to drive the second spring gear 302 to rotate, the second spring gear 302 rotates to drive the transmission rod 303 to rotate, and finally the cleaning component 304 can reciprocate on the transmission rod 303 to clean the screen of the mobile phone.

The AR glasses 100 are concavely formed with the groove 101 from the top end surface, the placement unit 200 is embedded into the groove 101, and the groove 101 is arranged to facilitate the installation of the mobile phone without increasing the volume of the AR glasses 100, thereby facilitating the use of the AR glasses 100.

Further, a placing groove 201a, a straight groove 201b and a stop block 201c are concavely formed on the top end surface of the shell 201, the placing groove 201a is communicated with the straight groove 201b to form a containing cavity A, a stirring column 202a is formed on the top end surface of the slideway 202 in a protruding mode, the stirring column 202a is rotationally connected with the slideway 202, the stirring column 202a penetrates through the straight groove 201b to extend out of the shell 201, a blocking column 202a-1 is arranged on the stirring column 202a, an arc edge 201a-1 is arranged on one side of the placing groove 201a, the placing groove 201a is used for inserting a mobile phone, when the mobile phone is completely inserted into the containing cavity A, the stirring column 202a is pushed to enable the mobile phone to move in a direction far away from the placing groove 201a, at the moment, a spring telescopic rod 203 is compressed, the arc edge 201a-1 can reduce resistance of mobile phone movement, the stirring column 202a and the mobile phone move synchronously, when the distance of the stirring column 202a moves beyond the stop block 201c, the moving column 202a is rotated, the blocking column 202a-1 is clamped at the stop block 201c, and the mobile phone is fixed in the containing cavity A.

Further, the inner wall of the slideway 202 is further provided with a chute 202b, the side surface of the sliding block 204 is provided with a bump 204a, the bump 204a is slidably embedded into the chute 202b, the top end surface of the slideway 202 is concavely provided with a paying-off groove 202c, the bottom end surface of the paying-off groove 202c is provided with a first wire hole 202c-1, the first wire hole 202c-1 is communicated with the chute 202b, the bottom end surface of the sliding block 204 is further provided with a spring 204b, the bump 204a is provided with a second wire hole 204a-1, the sliding block 204 is limited in the slideway 202 to move up and down through the bumps 204a arranged on two sides of the sliding block, the nylon rope 301a-1 passes through the wire hole, the well-stored nylon rope 301a-1 is placed in the paying-off groove 202c, and the spring 204b can play a certain damping role when a mobile phone is inserted.

Preferably, a round hole 202d is formed on a side surface of the slide 202, the first bar gear 301 includes a first rotating rod 301a coaxially connected to the round hole 202d, a first bar 301b fixedly connected to one end of the first rotating rod 301a, and a first gear 301c coaxially fixedly sleeved on the first bar 301b, a nylon rope 301a-1 is fixedly connected to the first rotating rod 301a, the nylon rope 301a-1 penetrates through the first wire hole 202c-1 and is fixedly connected to the second wire hole 204a-1, and when the slider 204 moves downward, the nylon rope 301a-1 is pulled, so that the first rotating rod 301a rotates and the first bar 301b contracts.

The second spring gear 302 comprises a second gear 302a movably connected with the inner wall of the accommodating cavity a, a second spring 302b arranged on one side of the second gear 302a, and a second rotating rod 302c fixedly connected with the second gear 302a, one end of the first spring gear 301 is further provided with a protruding rod 301d, one end of the second rotating rod 302c is provided with a rotating tube 302d, a square groove 302d-1 is formed in the rotating tube 302d, the protruding rod 301d is coaxially embedded into the square groove 302d-1, one end of the second spring 302b is fixedly connected with the second rotating rod 302c, the other end of the second spring 302b is fixedly connected with the inner wall of the accommodating cavity a, the first rotating rod 301a rotates to drive the protruding rod 301d to rotate, and the protruding rod 301d is embedded into the square groove 302d-1, so that the second spring 302c is driven to rotate, and the second spring 302b and the second gear 302a are further driven to rotate.

Further, the transmission rod 303 includes a worm 303a and a track rod 303b disposed at one end of the worm 303a, the worm 303a engages with the second gear 302a, a spiral groove 303b-1 is disposed on the track rod 303b, when the mobile phone moves away from the placement groove 201a, the convex rod 301d is disengaged from the square groove 302d-1, the second spring 302b is released in the contracted state, so that the second gear 302a engages with the worm 303a to rotate, the track rod 303b rotates synchronously with the worm 303a, the spiral groove 303b-1 is in a double-spiral structure, and the rotation of the spiral groove 303b-1 causes the sleeve block 304a to reciprocate on the track rod 303 b.

In detail, the cleaning assembly 304 includes a sleeve block 304a sleeved on the track rod 303b and a cleaning member 304b disposed on one side of the sleeve block 304a, a first protruding column 304a-1 is disposed on one side of the sleeve block 304a, a first track a-1 is disposed on an inner wall of the accommodating cavity a, the first protruding column 304a-1 is embedded into the first track a-1, a second protruding column 304b-1 is disposed on one side of the cleaning member 304b, a second track a-2 is disposed on an inner wall of the accommodating cavity a, and the second protruding column 304b-1 is embedded into the second track a-2.

Further, a circular rod 304a-2 is formed on the inner wall of the sleeve block 304a in a protruding manner, one end of the circular rod 304a-2 is rotatably connected with a fitting block 304a-3, the fitting block 304a-3 is slidably inserted into the spiral groove 303b-1, and when the track rod 303b rotates, the fitting block 304a-3 moves along the track of the spiral groove 303b-1, so that the reciprocating cleaning and wiping action of the cleaning member 304b is realized.

Finally, a circular disc 301a-2 is arranged at one end of the first rotating rod 301a extending out of the circular hole 202d, and the circular disc 301a-2 is equivalent to a limiting block to prevent the first strip-emitting gear 301 from falling off.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (2)

1. AR intelligent glasses, characterized by: the storage unit (400) comprises a storage box (401), a containing cavity (B) arranged in the storage box (401), a containing cover (402) and a radiator (403) arranged on the end face of the bottom of the storage box (401), wherein the radiator (403) comprises a radiating shell (403 a), a radiating fan (403B) arranged in the radiating shell (403 a), radiating fins (403 c) arranged on one side of the radiating shell (403 a), circulating water pipes (403 d) penetrating through the radiating fins (403 c) and a transfer block (403 e) arranged on one side of the radiating fins (403 c), and the radiator (403) is communicated with the containing cavity (B);

the AR glasses (100) are arranged in the accommodating cavity (B), and the AR glasses (100) are arranged in the accommodating cavity (B);

the device comprises a placement unit (200), wherein the placement unit (200) comprises a shell (201) arranged on an AR (AR) glasses (100), a containing cavity (A) arranged in the shell (201), a slide way (202) arranged on the inner wall of the containing cavity (A), a spring telescopic rod (203) arranged on the side surface of the containing cavity (A) and a sliding block (204) arranged in the slide way (202), and the slide way (202) is connected with the spring telescopic rod (203) in a sliding manner;

the cleaning unit (300) comprises a first spiral gear (301) arranged on the side surface of the slideway (202), a second spiral gear (302) arranged on the inner wall of the accommodating cavity (A), a transmission rod (303) with two ends rotatably connected with the inner wall of the accommodating cavity (A) and a cleaning assembly (304) connected with the transmission rod (303) in a sliding manner; the AR glasses (100) are recessed from the top end face to form a groove (101), and the placement unit (200) is embedded into the groove (101); a placing groove (201 a), a straight groove (201 b) and a stop block (201 c) are formed in the concave mode on the top end face of the shell (201), the placing groove (201 a) is communicated with the straight groove (201 b) to accommodate a cavity (A), a stirring column (202 a) is formed in the convex mode on the top end face of the slideway (202), the stirring column (202 a) penetrates through the straight groove (201 b) to extend out of the shell (201), a baffle column (202 a-1) is arranged on the stirring column (202 a), and an arc edge (201 a-1) is arranged on one side of the placing groove (201 a);

the novel sliding block is characterized in that a sliding groove (202 b) is further formed in the inner wall of the sliding rail (202), a protruding block (204 a) is arranged on the side face of the sliding block (204), the protruding block (204 a) is embedded into the sliding groove (202 b) in a sliding mode, a paying-off groove (202 c) is formed in the top end face of the sliding rail (202) in a recessed mode, a first wire hole (202 c-1) is formed in the bottom end face of the paying-off groove (202 c), the first wire hole (202 c-1) is communicated with the sliding groove (202 b), a spring (204 b) is further arranged on the bottom end face of the sliding block (204), and a second wire hole (204 a-1) is formed in the protruding block (204 a); the side face of the slideway (202) is provided with a round hole (202 d), the first winding gear (301) comprises a first rotating rod (301 a) which is coaxially connected with the round hole (202 d) in a rotating mode, a first spring (301 b) fixedly connected with one end of the first rotating rod (301 a) and a first gear (301 c) which is coaxially sleeved on the first winding gear (301 b) in a fixed mode, the first rotating rod (301 a) is fixedly connected with a nylon rope (301 a-1), and the nylon rope (301 a-1) penetrates through the first wire hole (202 c-1) and is fixedly connected with a second wire hole (204 a-1);

the mobile phone slides along the direction of the slideway (202) to drive the first spiral gear (301) to rotate, the first spiral gear (301) rotates to drive the second spiral gear (302) to rotate, the second spiral gear (302) rotates to drive the transmission rod (303) to rotate, and finally the transmission rod (303) rotates to realize the reciprocating motion of the cleaning assembly (304) on the transmission rod (303), so that the screen of the mobile phone is cleaned.

2. The AR smart glasses according to claim 1, wherein: the second spiral spring gear (302) comprises a second gear (302 a) movably connected with the inner wall of the accommodating cavity (A), a second spiral spring (302 b) arranged on one side of the second gear (302 a) and a second rotating rod (302 c) fixedly connected with the second gear (302 a), one end of the first spiral spring gear (301) is further provided with a protruding rod (301 d), one end of the second rotating rod (302 c) is provided with a rotating tube (302 d), a square groove (302 d-1) is formed in the rotating tube (302 d), the protruding rod (301 d) is coaxially embedded into the square groove (302 d-1), one end of the second spiral spring (302 b) is fixedly connected with the second rotating rod (302 c), and the other end of the second spiral spring (302 b) is fixedly connected with the inner wall of the accommodating cavity (A); the transmission rod (303) comprises a worm (303 a) and a track rod (303 b) arranged at one end of the worm (303 a), the worm (303 a) is meshed with the second gear (302 a), and a spiral groove (303 b-1) is formed in the track rod (303 b); the cleaning assembly (304) comprises a sleeve block (304 a) sleeved on the track rod (303 b) and a cleaning piece (304 b) arranged on one side of the sleeve block (304 a), a first convex column (304 a-1) is arranged on one side of the sleeve block (304 a), a first track (A-1) is arranged on the inner wall of the accommodating cavity (A), the first convex column (304 a-1) is embedded into the first track (A-1), a second convex column (304 b-1) is arranged on one side of the cleaning piece (304 b), a second track (A-2) is arranged on the inner wall of the accommodating cavity (A), and the second convex column (304 b-1) is embedded into the second track (A-2); a round rod (304 a-2) is formed on the inner wall of the sleeve block (304 a) in a protruding mode, one end of the round rod (304 a-2) is rotatably connected with a jogged block (304 a-3), and the jogged block (304 a-3) is slidingly embedded into the spiral groove (303 b-1); one end of the first rotating rod (301 a) extending out of the round hole (202 d) is provided with a circular disc (301 a-2).