CN217425845U - Novel glasses with lens frame capable of being turned electrically - Google Patents

Abstract

The utility model is suitable for a glasses technical field. The utility model discloses a novel glasses can electronic upset of lens frame, including the main mirror holder, rotate with the main mirror holder and be connected the rotation actuating mechanism of removable first pair mirror holder, the upset of the first pair mirror holder of drive to and the control circuit of control rotation actuating mechanism work, the during operation is rotated the first pair mirror holder of actuating mechanism drive and is overturned from top to bottom by control circuit control. When the first auxiliary spectacle frame is provided with the sunshade lens frame, the electric sunshade spectacles are used; when the first pair of spectacle frames are provided with the myopia lens frames or the hyperopia lens frames, the glasses are used as vision training glasses, and the turning time of the first pair of spectacle frames is adjusted through the control switch, so that the vision training effect is achieved. Through multiple electric control upset mode, can reach electronic sunshade, when adopting two kinds of different lenses, can realize the visual training function again, protect eyes and improve dual function such as eyesight to improve the convenience of using glasses under different scenes.

Description

Novel glasses with lens frame capable of being turned electrically

Technical Field

The utility model relates to a glasses technical field, in particular to but glasses of electronic upset of lens frame that adapts to different scenes.

Background

The existing glasses usually have two kinds of work, namely, the glasses can protect eyes, such as sunglasses and goggles for riding; secondly, improve vision, such as near or far vision. Usually, the two glasses cannot be integrated into one glasses, and a use scene may exist in the implementation, for example, a myopia patient needs the sunglasses to block part of sunlight when playing outdoors in summer. In order to solve the problem of using such scenes, a temporary sunglass lens is usually added to the glasses for myopia or a pair of sunglasses is worn to achieve the purpose. However, the two sunshade ways bring inconvenience to the user, the lens frame must be manually turned, and the sunshade lens frame is manually turned when one hand leaves the steering wheel or the handlebar in the driving and riding processes, so that the potential safety hazards of driving and riding are caused. And the existing set of glasses can only be turned by an angle of about 90 degrees, and the potential safety hazard that the body of a child is bruised by the lenses of a user holding the child in the hands is caused.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the main technical problem who solves provides a but lens frame electronic upset glasses, and this novel but lens frame electronic upset glasses can improve the convenience that uses under different scenes.

In order to solve the problem, the utility model provides a but lens frame electronic upset glasses, but this lens frame electronic upset glasses include the main mirror holder, rotate with the main mirror holder and be connected the rotation actuating mechanism of removable first pair mirror holder, the upset of the first pair mirror holder of drive to and the control circuit of control rotation actuating mechanism work, the during operation is rotated the first pair mirror holder of actuating mechanism drive and is overturn from top to bottom by control circuit control.

Further, the rotation driving mechanism comprises a rotating shaft arranged on the main lens frame and a motor assembly for driving the rotating shaft to rotate.

Furthermore, the motor assembly comprises a motor and a transmission gear arranged on a rotating shaft of the motor.

Furthermore, the first auxiliary mirror bracket is provided with a rotating bracket fixedly connected with the rotating shaft, the rotating bracket is provided with two parallel clamping arms, one end of each clamping arm is clamped and fixed with the rotating shaft, the other ends of the two clamping arms are respectively connected with the fixed seat, and each clamping arm is provided with a clearance groove.

Further, the first auxiliary spectacle frame is provided with sun-shading lenses, near-sighted lenses or far-sighted lenses.

Furthermore, a detachable second auxiliary spectacle frame is arranged on the main spectacle frame, and a plurality of fixing columns matched with the fixing holes in the main spectacle frame are arranged in a distributed mode on the second auxiliary spectacle frame.

Furthermore, the fixed column is arranged at two ends and the middle part of the second auxiliary spectacle frame.

Furthermore, the main spectacle frame is provided with a control switch which is connected with the control circuit and is used for manually controlling the first auxiliary spectacle frame to turn over, and a light sensor and/or a voice control circuit which is connected with the control circuit through an electric signal and is used for triggering the auxiliary spectacle frame to automatically turn over and control, wherein the light sensor comprises a light guide cover and optical fiber light guide or direct sensing.

Furthermore, the main spectacle frame is also provided with a spectacle leg detection switch which is connected with the control circuit and used for detecting whether the spectacle legs are folded or unfolded, and the spectacle leg detection switch comprises a travel switch.

Furthermore, the main mirror bracket is also provided with a first auxiliary mirror bracket turnover detection switch which is connected with the control circuit and used for detecting the turnover of the first auxiliary mirror bracket.

Further, the rotation angle of the first auxiliary frame can be adjusted to a range of 90 degrees to 180 degrees.

Furthermore, the main spectacle frame is also provided with a working indicator light connected with the control circuit.

Further, the voice control circuit comprises a microphone arranged on the main lens frame.

The utility model provides a novel but glasses of lens frame electronic upset, including the main mirror holder that is equipped with removable first pair mirror holder, the rotation actuating mechanism of the first pair mirror holder upset of drive, the control circuit of control rotation actuating mechanism work and the control switch of control work, and with control switch and control circuit electric signal connection's light sensor and/or speech control circuit, and for the power of control circuit power supply, in operation, by the first pair mirror holder of control circuit according to light sensor and/or speech control circuit signal control rotation actuating mechanism drive upwards or overturn downwards. When the first replaceable auxiliary spectacle frame is provided with the sunshade lens frame, the first replaceable auxiliary spectacle frame is used as the electric sunshade spectacles. When the first replaceable auxiliary spectacle frame is provided with a myopia lens frame or a distant vision lens frame, the glasses are used as eyesight training glasses, and the turning time of the first auxiliary spectacle frame is adjusted through the control switch so as to achieve the best eyesight training and eyesight health care effects. Through multiple electric control mode of overturning, can reach electronic sunshade, when adopting two kinds of different lenses, can realize the visual training function again, the dual function such as protection eyes and improvement eyesight to the improvement uses the convenience of glasses under different scenes.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic circuit diagram of an embodiment of a novel power-flipping eyeglass lens frame.

Fig. 2 is a schematic view of an embodiment of a pair of novel glasses with a lens frame capable of being flipped over electrically.

Fig. 3 is a front view of a novel lens frame of an embodiment of power reversible eyeglasses.

Fig. 4 is a schematic diagram of a right side view structure of an embodiment of a novel electric reversible eyeglass frame.

Fig. 5 is a schematic bottom view of an embodiment of a pair of novel power-flipping eyeglasses with a lens frame.

Fig. 6 is a bottom view of the inner structure of the novel power-flipped eyeglass lens.

Fig. 7 is another schematic bottom view of the novel lens frame of an embodiment of the power-flipping eyeglasses.

Fig. 8 is a schematic top view of a novel lens frame of an embodiment of power-flipped glasses.

Fig. 9 is a schematic top view of an embodiment of a novel power-reversible eyeglass lens frame.

Fig. 10 is a right side view of the inner structure of the novel power reversible eyeglass embodiment.

Fig. 11 is a schematic view of a first auxiliary frame rotation driving structure of the novel electric reversible eyeglasses embodiment.

Fig. 12 is a schematic view of a rotation driving mechanism of an embodiment of a novel power-reversible eyeglass lens frame.

Fig. 13 is a schematic view of a structure of a rotation driving mechanism of an embodiment of a novel power-reversible eyeglass.

Fig. 14 is a schematic view of the assembly of the components of the rotational driving mechanism of the novel power reversible eyeglass embodiment.

Fig. 15 is a schematic view of a linear positioning rotating shaft of the electric reversible eyeglasses with a novel lens frame.

Fig. 16 is a schematic view of a circular retaining rotation shaft of a power-operated flip-flop glasses with a novel lens frame.

Fig. 17 is a schematic view of an internal rotation driving structure of a first auxiliary frame of an embodiment of the novel electric reversible eyeglasses.

Fig. 18 is a schematic view of a control structure of an internal rotation driving mechanism of an embodiment of a novel power-reversible eyeglass lens frame.

Fig. 19 is a schematic view of a first auxiliary frame of a pair of novel power-reversible eyeglasses with a 140-degree upturned configuration.

Fig. 20 is a schematic view of a first auxiliary frame of a pair of novel power-reversible eyeglasses with a 100-degree upward turning structure.

Fig. 21 is a schematic view of a first auxiliary frame and a rotation driving mechanism of an embodiment of a novel electric reversible eyeglass.

Fig. 22 is a schematic view of an exemplary embodiment of an electrically reversible eyeglass with a novel lens frame showing an internal intermediate photosensitive member and a downward-turning limit control structure of a first secondary frame.

Fig. 23 is a top view of a temple closing structure of a pair of novel power-reversible eyeglasses with a lens frame.

Fig. 24 is a top view of a novel power-on power-off control for a temple of a power-on reversible eyeglass embodiment of the present invention.

FIG. 25 is a schematic top view of a power switch closing control for temple extension of a pair of novel power-operated reversible eyeglasses with lens frame

Fig. 26 is a schematic top view of another embodiment of a novel power reversible eyeglass lens frame.

Fig. 27 is a top view of a control switch and indicator light configuration for a novel lens frame power reversible eyeglass embodiment.

Fig. 28 is a schematic view of a novel power reversible eyeglass embodiment sunglass frame that is flipped down into position.

Fig. 29 is a schematic view of a novel electrically reversible eyeglass embodiment sunglass frame that is flipped up into position.

Fig. 30 is a schematic view of a novel glasses frame with an electric turnable first auxiliary frame as a sunshade and wind-proof glasses.

Fig. 31 is a diagram illustrating a structure of a set of novel lens frame of an embodiment of power-operated flip glasses.

Fig. 32 is a schematic view of a second auxiliary frame of a novel power-reversible eyeglass embodiment of a lens frame.

Fig. 33 is a schematic view of a first pair of electrically reversible eyeglass frames of a novel eyeglass frame of an embodiment of the vision training apparatus flipped downward into position.

Fig. 34 is a schematic view of a first pair of eyeglasses frames of the novel power-flipped eyeglasses of the present embodiment being flipped up and down.

Fig. 35 is a schematic view of a nose piece of an embodiment of the novel power-reversible eyeglass lens frame.

Fig. 36 is a schematic view of a nose piece assembly of an embodiment of a novel power-reversible eyeglass frame.

Fig. 37 is a schematic view of a charging interface of an embodiment of a novel power-flipped eyeglass lens frame.

Fig. 38 is a schematic view of an internal structure of a charging interface of an embodiment of a novel power-operated flip glasses lens frame.

Fig. 39 is a schematic view of an assembly structure of a retractable temple hook of a pair of novel power-reversible eyeglasses with a lens frame.

Fig. 40 is a diagram illustrating a structure of a small-sized temple hook of a pair of novel glasses with a lens frame capable of being electrically flipped.

Fig. 41 is a schematic view of a large temple hook of the novel lens frame of the electric reversible eyeglasses.

Fig. 42 is a schematic view of an assembly structure of a motor and a soft rubber sleeve of a novel electric reversible eyeglass frame.

Fig. 43 is a schematic bottom view of another embodiment of a novel power-reversible eyeglass lens frame.

Fig. 44 is a schematic view of an internal structure of a rotation driving mechanism of another embodiment of a pair of novel lens frame electrically reversible eyeglasses.

Fig. 45 is a schematic view of an internal structure of another embodiment of the novel lens frame of the power-operated reversible eyeglasses.

Fig. 46 is a schematic view of an internal rotation driving mechanism of another embodiment of a pair of novel lens frame power-tiltable eyeglasses.

Fig. 47 is a schematic view of a motor and rotating shaft mounting structure of another embodiment of the novel lens frame power-tileable eyeglasses.

The objects, features and advantages of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The following claims are presented in conjunction with the detailed description of the invention and the accompanying drawings, it being understood that the embodiments described are only some embodiments of the invention and not all embodiments. Based on the embodiments of the present invention, those skilled in the art can find out all other embodiments obtained without making creative efforts, which also belong to the protection scope of the present invention.

It should be understood that in the embodiments of the present invention, all directional terms, such as "upper", "lower", "left", "right", "front", "back", etc., are used herein based on the orientation and position shown in the drawings or the orientation and position of the product, and are not intended to limit the present invention, but to simplify the description of the present invention. For the purpose of explaining only the relative positional relationship between the respective components, the movement, and the like, as shown in the drawings, when the specific posture is changed, the directional indication may be changed accordingly.

Furthermore, ordinal numbers such as "first," "second," etc., that may be referred to in the disclosure are for distinguishing purposes only and are not to be construed as indicating or implying any relative importance or implied indication of the number of technical features indicated. The features defining "first" and "second" may be explicit or implicit in at least one of the features. In the description of the present invention, "a plurality" means at least two, i.e., two or more, unless expressly defined otherwise; the meaning of "at least one" is one or both.

In the present invention, unless explicitly specified or limited otherwise, the terms "mounting," "setting," "connecting," "fixing," "screwing" and the like are to be understood in a broad sense, and for example, the positional relationship between the components may be relatively fixed, or the components may be physically fixed and connected, or may be detachably connected, or may be integrated into a single structure; the connection can be mechanical connection or electrical signal connection; either directly or indirectly through intervening media or components; the two elements may be connected with each other or may be in an interaction relationship with each other, and unless otherwise explicitly limited by the specification, the specific meaning of the terms in the present invention can be understood by those skilled in the art according to the specific situation, except that the corresponding function or effect cannot be achieved otherwise.

The controller and the control circuit that the present invention may relate to are conventional control techniques or units for those skilled in the art, and the control circuit of the controller may be implemented by those skilled in the art using conventional techniques, such as simple programming. The power also adopts belong to this field of prior art, and the utility model discloses main utility model technical point lies in improving mechanical device, so the utility model discloses no longer explain in detail concrete circuit control relation and circuit connection.

As shown in fig. 2-5, the present invention provides a structure of a novel lens frame of an embodiment of an electric turnover eyeglasses, the glasses with the lens frame capable of being electrically turned comprise a main glasses frame 1, a first auxiliary glasses frame 2 is arranged on the main glasses frame 1, a left lens 4, a right lens 4' and a light guide cover 6 of a light sensor are arranged on the first auxiliary spectacle frame 2, wherein the first auxiliary spectacle frame 2 is linked with a rotation driving mechanism in the main spectacle frame 1 through a rotation bracket 3, and the left and right sides of the main glasses frame 1 are respectively connected with the left earpiece 5 and the right earpiece 5 'through the left screw rod 37 and the right screw rod 37', a switch combination 7 and a working state indicator light combination 8 which are arranged on the right half part of the main spectacle frame 1, a microphone 11 which is arranged at the bottom of the main spectacle frame 1 and used for voice control and sound collection, a loudspeaker 12 for sound prompt, and a nose pad 14 with adjustable height.

Fig. 1-22 show the structure of a pair of novel electric turnover eyeglasses according to an embodiment of the present invention. The glasses with the lens frame capable of being turned over electrically comprise a main glasses frame 1, wherein a first auxiliary glasses frame 2, a rotation driving mechanism for driving the first auxiliary glasses frame 2 to rotate, a control circuit 15 for controlling the rotation driving mechanism to work, batteries 17 and 17 'for supplying power to the control circuit 15, a control switch combination 7 and a working state indicator lamp combination 8 which are connected with the control circuit 15, a light sensor 6' connected with the control circuit 15, a light guide cover 6 for guiding light to the light sensor 6', a microphone 11 for collecting sound through voice control and a loudspeaker 12 for carrying out voice prompt are arranged on the main glasses frame 1, and the batteries 17' can be arranged as required. When the device works, the control circuit 15 controls the rotation driving mechanism to drive the rotation support 3 to turn upwards or downwards according to the setting of the control switch combination 7, the light sensor 6' and the microphone 11 for collecting sound under the voice control or the setting of automatic light sensing or voice control, so that the first auxiliary spectacle frame 2 is synchronously linked to turn upwards or downwards. Specifically, the face cover 9 on the main frame 1 is provided with a rotating bracket 3 and a first auxiliary frame 2 fixedly connected with the rotating bracket 3, the rotating bracket 3 is provided with two parallel clamping arms, one end of each clamping arm is clamped and fixed with the rotating shaft 25, the other ends of the two clamping arms are respectively connected with a fixed seat 36, and each clamping arm is provided with a clearance groove 36'.

The rotation driving mechanism comprises a motor 20 arranged on a face cover 9, a motor pinion 201 arranged on the shaft core of the motor 20, a rotating shaft 25 which is arranged on the face cover 9 and is linked with a rotating bracket 3, and a gearwheel 24 arranged on the shaft core 253 of the rotating shaft 25, wherein the motor pinion 201 arranged on the shaft core of the motor 20 and the gearwheel 24 arranged on the shaft core 253 of the rotating shaft 25 are tightly meshed to form a linkage relation, the motor cover 19 locks the motor 20 on the face cover 9 through 4 screws 19', the other end of the motor pinion 201 is fixed on a hole position of the face cover 9 through a fixing ferrule 202 to ensure that the motor pinion 201 can rotate smoothly, a rotating shaft buckle 26 is locked on the face cover 9 through two screws 26 ' to clamp a clamping groove 252 in the middle of the rotating shaft 25, so that the rotating shaft 25 cannot move left and right, the gearwheel 24 is arranged on the shaft core 253 of the rotating shaft 25 through a central hole 241 and is locked on the rotating shaft 25 through the screws 24', the two hexagonal bayonets 31 of the rotating bracket 3 are inserted into the two corresponding hexagonal bayonets 251 of the rotating shaft 25 and fixed, and the first auxiliary spectacle frame 2 is locked on the rotating bracket 3 by the two screws 32 on the rotating bracket 3. During operation, the control circuit 15 is manually triggered by the switch assembly 7 to provide corresponding electric energy to the motor 20 for forward rotation or reverse rotation. The light sensor 6' can also be used for sensing light and automatically triggering the control circuit 15 to provide corresponding electric energy for the motor 20 to rotate forwards or backwards. And the microphone 11 is used for carrying out voice control and collecting sound to carry out voice trigger, and the control circuit 15 is used for providing corresponding electric energy for the motor 20 to rotate forwards or reversely. The motor 20 is linked with the motor pinion 201 to drive the gearwheel 24 to rotate reversely or rotate positively, the gearwheel 24 is linked with the rotating shaft 25 to rotate reversely or rotate positively, and the rotating support 3 is driven to rotate upwards or downwards by the rotating shaft 25, so that the rotating support 3 drives the first auxiliary spectacle frame 2 to rotate upwards or downwards, namely sunglass lenses or myopia lenses or hyperopia lenses 4 and 4' arranged on the first auxiliary spectacle frame 2 and sun-shading wind-shielding lenses arranged on the rotating support 3 are electrically turned upwards or downwards. Whether the rotating bracket 3 is turned downwards to be in place or not is detected through a rotating bracket lower turning limit switch 29 arranged on the middle circuit board 27, when the rotating bracket 3 is turned downwards to be in place, as shown in a figure that the first auxiliary mirror bracket 2 is turned downwards to be in place, a press button 34 arranged on the rotating bracket 3 is pressed to the limit switch 29, so that the limit switch 29 is closed, the control circuit 15 is triggered to stop supplying electric energy to the motor 20, the motor 20 stops rotating, and the first auxiliary mirror bracket 2 is turned downwards. When the control circuit 15 provides electric energy to the motor 20 to drive the rotation driving mechanism to drive the rotation bracket 3 to turn upwards to a proper position, the rotation bracket is blocked and does not turn any more, the motor 20 is blocked and generates instant overcurrent pulse due to the blockage of the rotation bracket 3, the control circuit 15 immediately stops providing the electric energy to the motor 20 after detecting the pulse, and the motor 20 stops rotating to enable the first auxiliary mirror bracket 21 to keep an upturning state of about 140 degrees as shown in the figure that the first auxiliary mirror bracket 2 turns upwards to a proper position in figure 19, so that the action of upturning the first auxiliary mirror bracket 2 is completed. In the embodiment, in order to reduce the volume of the main mirror holder 1 without providing a switch for detecting the upturning position of the rotating bracket 3, the switch for detecting the upturning position of the rotating bracket 3 can be added as required to reduce the instantaneous overcurrent power loss caused by the blocking of the motor 20, or the time for providing the electric power to the motor 20 by the control circuit 15 is set by measuring the length of the upturning position time of the rotating bracket 3, for example, it takes about 0.5 second for the rotating bracket 3 to upturn to about 140 degrees from the starting position of the downturning position in the downturning state, the control program of the control circuit 15 is set to stop when the time reaches 0.5 second for supplying the electric power to the motor 20 to upturning each time, so that the rotating bracket 3 stops overturning every time when being upturning to about 140 degrees, and the loss of the battery power caused by the instantaneous overcurrent due to the blocking of the motor 20 caused by the upturning position of the rotating bracket 3 is avoided, thereby increasing the stability of the control circuit 15 and the driving rotation drive mechanism and the service time of the battery 17. The closed state of limit switch 29 plays the detection that first pair mirror holder 2 upset down targets in place and the dual function such as detection of initial position for control circuit 15 can drive and rotate actuating mechanism and drive the first pair mirror holder 2 and make progress or overturn downwards accurate, reach electronic sunshade or eyesight training function, play the protection eyes not by the strong light shine with carry out dual function such as eyesight health care, thereby improve the convenience of using glasses under different scenes. Meanwhile, in the present embodiment, in order to reduce the volume of the main frame 1, the turning support 3 is turned upward to the proper position by an angle of about 140 degrees, or the turning support 3 may be turned upward to the proper position by an angle of 180 degrees as required. The shapes of the switch press button 34 on the rotating bracket 3 and the hole position of the limit switch 29 arranged on the main mirror frame surface cover 9 are not limited, and can be set to be circular, rectangular or other shapes as required for convenient use and production. Because this glasses are worn and are used on head, can't see the condition of pilot lamp during the operation, just the operation and the settlement state of switch button are distinguished to the sound that accessible speaker 12 sent, let the use this glasses that the user can be more convenient.

As shown in fig. 15 and 16, the two locking portions 251 of the rotating shaft 25 can be configured in a shape of a double-groove straight line and a circle as required, or can be configured in other shapes as required, and the shaft core 253 can also be configured in other shapes to achieve the best assembling effect and rotational stability.

As shown in fig. 19 and 20, the first auxiliary frame 2 is turned upwards by about 140 degrees, the viewing angle of the glasses is relatively large, and the glasses are suitable for outdoor use, for example, the sunglasses mode and the sun-visor mode, but if the glasses are used in the eyesight training mode, because the first auxiliary frame 2 is turned upwards by about 140 degrees, the turning time is long, the power consumption of the battery 17 is relatively large, and the battery power use time is affected, therefore, a structural diagram of turning the first auxiliary frame 2 upwards by about 100 degrees as shown in fig. 20 is added, by measuring that it takes about 0.4 seconds to turn the rotating bracket 3 upwards from the initial position where the downward turning state is in place to about 100 degrees, and then the program of the control circuit 15 is set to stop turning the rotating bracket 3 every time of supplying power to the motor 20 for turning upwards for 0.4 seconds, so that the rotating bracket 3 stops turning every time of turning upwards to about 100 degrees, thereby shortening the time that the runing rest 3 upwards overturns, playing simultaneously and avoiding causing the loss of the battery electric energy that the instantaneous that motor 20 stalling produced overflows and arouses because first secondary mirror holder 2 upwards overturns about 140 degrees and blocks to increase control circuit 15 and the stability of whole rotation drive mechanism and the live time of battery 17.

As shown in fig. 23-25, the power supply of the electric reversible glasses of the present invention can perform the automatic power-off and power-on functions according to the closing and unfolding of the glasses legs, wherein the detection switch 30, the battery 17 and the control circuit 15 are electrically connected, as shown in fig. 24, when the left glasses leg 5 is closed by the left screw 37 as the origin, the surface of the short top 52 disposed on the left glasses leg 5 cannot push the push rod 30' nor push the movable button of the detection switch 30 disposed on the charging plate 28 to move to the switch center point, that is, when the left glasses leg 5 is closed, the detection switch 30 is not actuated, and the state of the detection switch 30 is closed, so that the detection switch 30 directly disconnects the connection between the battery 17 and the control circuit 15 or triggers the control circuit 15 to stop the power-off operation, thereby performing the automatic power-off function as soon as the left glasses leg 5 is closed, so as to save the power consumption of the battery and increase the service time of the battery power. Wherein the charging plate 28 is locked to the main frame face cover 9 by a set screw 28'. As shown in fig. 25, after the left earpiece 5 is unfolded by taking the left screw 37 as the origin, the long top 53 disposed on the left earpiece 5 protrudes by a length of about 0.5mm from the surface of the short top 52, so as to push the push rod 30' to push the movable button of the detection switch 30 disposed on the charging board 28 to move toward the center of the switch, so as to actuate the detection switch 30, and the state of the detection switch 30 at this time is closed, so that the detection switch 30 directly connects the battery 17 and the control circuit 15 to power on or triggers the control circuit 15 to power on to start working or enter a standby state, thereby playing a function of automatically powering on as soon as the left earpiece 5 is closed, and increasing the intelligent use of the glasses. The lengths of the short top position 52 and the long top position 53 of the earpiece 5 can be set to be proper lengths according to requirements so as to achieve the best use effect and stability.

Referring to fig. 19, 20 and 27, an embodiment of adjusting the upward turning angle of the first secondary spectacle frame 2 of the electric turnable spectacle of the present invention is shown, after the left and right temples 5 and 5' are opened and the trigger detection switch 30 is closed, the battery 17 starts to supply power to the control circuit 15 to enter a standby state, the indicator lamp 81 is turned on, the system enters a manual control turning program, after the switch 73 is pressed for two seconds, the indicator lamp 87 is turned on, the speaker 12 sends out a sound of two sounds, the upward turning angle of the first secondary spectacle frame 2 at each time is changed from 140 degrees to about 140 degrees as shown in fig. 19, the upward turning angle of the first secondary spectacle frame 2 at each time is changed from about 100 degrees as shown in fig. 20, the upward turning angle of the first secondary spectacle frame 2 at each time is set to about 100 degrees, after the switch 73 is pressed for two seconds again, the indicator lamp 87 is turned off, the speaker 12 sends out a sound of B, the upward turning angle of the first secondary spectacle frame 2 at each time is changed from about 100 degrees to about 140 degrees as shown in fig. 20 Control, also set up the angle of first pair mirror holder 2 upturning through holding switch 73 two seconds, the angle of first pair mirror holder 2 upturning can all be set for as required to arbitrary embodiment such as manual control upset and the automatic upset of sensitization and speech control upset and eyesight training function of novel lens frame can electronic upset glasses, the effect of sunshade and windshield is played mainly to manual control upset and the automatic upset of sensitization and this three embodiment of speech control upset, and first pair mirror holder 2 upwards and downward upset frequency is less, so the angle of first pair mirror holder 2 upturning sets up in advance to 140 degrees and can make eyes have bigger field of vision to and can not scrape child's health easily behind the first pair mirror holder 2 upturning 140 degrees when user holds child in the hands, it is safer like this. In the vision training embodiment, the vision training device is basically used indoors alone, the requirement on the visual field of eyes is not high outdoors, but the frequency of the upward and downward turning of the first auxiliary frame 2 is higher, so that the upward turning angle of the first auxiliary frame 2 is set to about 100 degrees, the upward turning time of the first auxiliary frame 2 can be reduced, the power consumption of the battery 17 can be saved, and the service time of the battery 17 can be increased. The angle and the setting of the angle at which the first sub-frame 2 is turned upward will not be described in the following embodiments.

As shown in fig. 21, the groove 13 of the first sub-frame 2 is used to reduce the weight of the first sub-frame 2 and to scrape off excess material, so that the first sub-frame 2 is made lighter for portability and portability.

The implementation of 4 major functions such as manual control turning, photosensitive automatic turning, voice control turning, vision training and the like of the novel lens frame capable of electrically turning the glasses is described in detail below.

Fig. 1-29 show a manually-controlled reversible embodiment of the present invention, and in particular, a manually-controlled reversible sunglasses, and fig. 28 shows a first auxiliary frame 21 of the present embodiment in a starting position and in a downward reversed position. The position of a first auxiliary spectacle frame 2 is provided with a sunglass frame 21, the left and right lenses 4 and 4 'of the sunglass frame 21 are respectively provided with sunglass lenses, the color and specification of the sunglass lenses are determined according to requirements, when the glasses are used, the left and right earpieces 5 and 5' are opened to trigger a detection switch 30 to be closed, a battery 17 starts to supply power to a control circuit 15 to enter a standby state, an indicator lamp 81 is lightened to enter a manual control overturning program, after the glasses are worn, when sunlight or ambient light is weak, a switch 71 arranged on a main spectacle frame surface cover 9 is pressed once, a loudspeaker 12 emits a sound B, and simultaneously the control circuit 15 is triggered to provide electric energy to a motor 20 to rotate forwards, so that a rotation driving mechanism is driven to link a rotation support 3 to drive the first auxiliary spectacle frame 21 to overturn upwards, when the first auxiliary spectacle frame 21 overturns upwards to about an angle of about 140 degrees, the rotation support 3 is clamped and does not overturn any more, the control circuit 15 stops supplying electric energy to the motor 20 immediately after detecting the pulse, and the motor 20 stops rotating immediately so that the first auxiliary spectacle frame 2 keeps an upturning state of about 140 degrees, as shown in fig. 29, the first auxiliary spectacle frame 2 is upturned to a proper position, and the glasses worn at this time do not have a sun-shading function of sunglasses, that is, the eyes are not shielded and directly look ahead. When the sunlight or the ambient light is strong, the switch 71 is pressed once again, the speaker 12 emits a sound of B, and the control circuit 15 is triggered to provide electric energy to the motor 20 to perform reversal, so as to drive the rotation driving mechanism to link the rotation bracket 3 to drive the first auxiliary spectacle frame 21 to turn downwards, when the first auxiliary spectacle frame 2 turns downwards to a proper position, as shown in the diagram in fig. 28, the first auxiliary spectacle frame 2 turns downwards to a proper position, the switch press button 34 arranged on the rotation bracket 3 presses the limit switch 29 arranged on the main spectacle frame surface cover 9, the limit switch 29 is closed to trigger the control circuit 15 to stop providing electric energy to the motor 20, and meanwhile, the left and right sunglass lenses 4 and 4' arranged on the first auxiliary spectacle frame 2 respectively shield the left and right eyes from strong light, and the pair of the glasses worn at this time has the sun-shading function of the sunglasses. When the power switch 71 is pressed once again, the speaker 12 emits a sound B, and at the same time, the trigger control circuit 15 provides electric energy to the motor 20 to rotate forward and drive the rotation driving mechanism to drive the first auxiliary spectacle frame 2 to rotate upwards by about 140 degrees in a linkage manner, and the power switch 71 is circularly pressed in this way to trigger the control circuit 15 to provide electric energy to the motor 20 to rotate forward or reversely so as to drive the rotation driving mechanism to drive the first auxiliary spectacle frame 2 to rotate upwards or downwards as required, wherein the principle is the same as that described above, and is not explained again. That is, the first auxiliary glasses frame 2 is turned upwards by pressing the switch 71 once, and the first auxiliary glasses frame 2 is turned downwards by pressing the switch 71 once again, so that the function of manually controlling the first auxiliary glasses frame 2 to be turned upwards or downwards according to the requirement is achieved, and the best eye protection and the best visual effect are achieved.

As shown in fig. 1-29, in the embodiment of photosensitive automatic turning of the present invention, when the present invention is used, after the left and right earpieces 5 and 5' are turned on and the trigger detection switch 30 is turned off, the battery 17 starts to supply power to the control circuit 15 to enter a standby state, the indicator 81 is turned on, and a manual control turning program is started, and the switch 74 is pressed for two seconds, the indicator 81 is turned off, the indicator 82 is turned on, the speaker 12 sends out two sounds to prompt the system to enter a photosensitive automatic turning mode, after wearing the present invention, when the sunlight or the ambient light is weak, the light collected by the light guide cover 6 of the light sensor disposed on the main frame cover 9 is guided to the surface of the light sensor 6', and when the light sensor 6' senses the sunlight or the ambient light, the trigger control circuit 15 simultaneously provides electric energy for the motor 20 to turn forward, so as to drive the rotation driving mechanism to link the rotation bracket 3 to drive the first auxiliary frame 2 to turn upward, when the first auxiliary glasses frame 2 is turned upwards to a position of about 140 degrees, the rotating support 3 is clamped and does not turn any more, instant overcurrent pulse is caused by the blocking of the motor 20 due to the clamping of the rotating support 3, the control circuit 15 immediately stops supplying electric energy to the motor 20 after detecting the pulse, the motor 20 immediately stops rotating to enable the first auxiliary glasses frame 2 to keep an upwards turning state of about 140 degrees, as shown in a diagram that the first auxiliary glasses frame 2 is turned upwards to a position shown in fig. 29, the glasses worn at the moment do not have the sun-shading function of sunglasses, namely, the eyes are not shielded to directly look ahead. When the sunlight or the ambient light is strong, the strong light collected by the light guide cover 6 of the light sensor arranged on the main mirror frame cover 9 is guided to the surface of the light sensor 6', when the light sensor 6' senses the sunlight or the ambient light is strong, the control circuit 15 is triggered to provide electric energy for the motor 20 to rotate reversely, so that the rotary driving mechanism is driven to link the rotary bracket 3 to drive the first auxiliary mirror frame 2 to turn downwards, when the first auxiliary mirror frame 2 turns downwards to the proper position, as shown in the figure 28, the first auxiliary mirror frame 2 turns downwards to the proper position, the switch press button 34 arranged on the rotary bracket 3 is pressed to the limit switch 29 arranged on the main mirror frame cover 9, the limit switch 29 is closed, so that the control circuit 15 is triggered to stop providing the electric energy for the motor 20 immediately, and the left and right sunglass lenses 4 and 4' arranged on the first auxiliary mirror frame 2 respectively shield the left and right eyes from the strong light, the glasses worn at this time serve as a sun-shading function of sunglasses. When sunlight or ambient light are weak again, light sensor 6 'senses sunlight or ambient light weak again and triggers control circuit 15 simultaneously and provides the electric energy and carry out the corotation for motor 20, thereby the drive rotates actuating mechanism linkage rotation support 3 and drives first vice mirror holder 2 and upwards overturn, light sensor 6' triggers control circuit 15 repeatedly through the power of sensing sunlight or ambient light repeatedly and provides the electric energy and carry out corotation or reversal for motor 20 thereby the drive rotates actuating mechanism and drives first vice mirror holder 2 and upwards or overturn downwards, wherein the principle is unanimous with the aforesaid, no longer describe. That is first vice mirror holder 2 is automatic upwards upset when solar ray or ambient light are on the verge of weak, and first vice mirror holder 2 is automatic downwards upset when solar ray or ambient light are on the verge of strong, plays the function that first vice mirror holder 2 of light induction automatic control upwards perhaps overturns downwards to reach best eye protection and best visual effect.

Fig. 1-29 show a voice-controlled flip embodiment of the present invention, which can be used for turning over the sunglasses frame in different environments, such as turning over the near-sighted frame and turning over the far-sighted frame, and can be used for a plurality of purposes, and suitable frames and lenses can be installed on the first pair of frames 2 according to the requirement. Firstly, a voice recognition instruction is collected through a microphone 11 for voice control sound collection arranged on a main spectacle frame face cover 9 and then is recorded into a voice recognition module in a control circuit 15, for example, setting voice to be turned up is to trigger the control circuit 15 to supply electric energy to a motor 20 to rotate forwards, and setting voice to be turned down is to trigger the control circuit 15 to supply electric energy to the motor 20 to rotate backwards, other voices such as English, Japanese, German or language voices of other countries, local language voices or digital voices and the like can be used, and the voice recognition method is determined according to design requirements and the voice recognition capability of the voice recognition module. When the glasses are used, after the left and right glasses legs 5 and 5' are opened and the trigger detection switch 30 is closed, the battery 17 starts to supply power to the control circuit 15 to enter a standby state, the indicator lamp 81 is lightened to enter a manual control overturning program, the switch 74 is pressed for two seconds, the indicator lamp 81 is extinguished, the indicator lamp 83 is lightened, the loudspeaker 12 sends out a B three-tone prompt system to enter a voice control overturning mode, after the glasses are worn, when sunlight or ambient light is weak, upturning voice is spoken, the microphone 11 for voice control sound collection arranged on the main glasses frame surface cover 9 collects the upturning voice, the control circuit 15 is triggered to provide electric energy to the motor 20 to rotate forwards, so as to drive the rotation driving mechanism to link the rotation support 3 to drive the first pair of glasses frames 2 to overturn upwards, and when the first pair of glasses frames 21 overturn upwards to about 140 degrees, the rotation support 3 is clamped and does not overturn any more, the control circuit 15 stops supplying electric energy to the motor 20 immediately after detecting the pulse, and the motor 20 stops rotating immediately so that the first auxiliary spectacle frame 2 keeps an upturning state of about 140 degrees, as shown in fig. 29, the first auxiliary spectacle frame 2 is upturned to a proper position, and the glasses worn at this time do not have a sun-shading function of sunglasses, that is, the eyes are not shielded and directly look ahead. When the sunlight or the ambient light is strong, the voice of turning down is spoken, the microphone 11 for voice control and sound collection arranged on the main spectacle frame face cover 9 collects the voice of turning down and triggers the control circuit 15 to provide electric energy for the motor 20 to rotate reversely, thereby driving the rotation driving mechanism to link the rotation bracket 3 to drive the first auxiliary spectacle frame 2 to turn downwards, when the first auxiliary spectacle frame 2 turns downwards to a proper position, as shown in fig. 28, when the first sub-frame 2 is turned down to a position, the switch button 34 provided on the turning bracket 3 is pressed to the limit switch 29 provided on the main frame cover 9, the limit switch 29 is closed to trigger the control circuit 15 to immediately stop supplying the electric power to the motor 20, meanwhile, the left and right sunglass lenses 4 and 4' arranged on the first auxiliary spectacle frame 2 respectively shield the left and right eyes from being irradiated by strong light, and the glasses worn at the moment have the sun-shading function of the sunglasses. When the sunlight or the ambient light is weak again, the voice of turning up is spoken again, the microphone 11 for voice control sound collection arranged on the main mirror frame face cover 9 collects the voice of turning up and triggers the control circuit 15 to provide electric energy for the motor 20 to rotate forward, so that the rotation driving mechanism is driven to link the rotation support 3 to drive the first auxiliary mirror frame 2 to turn up, the voice of turning up or turning down is spoken when the sunlight or the ambient light is weak or strong repeatedly, and the control circuit 15 is triggered repeatedly to drive the first auxiliary mirror frame 2 to turn up or down through the driving mechanism, wherein the principle is consistent with the principle and is not explained any more. That is to say "upturning" first secondary mirror holder 2 and upwards overturn when solar ray or ambient light are on the weak side, say "down turn over" first secondary mirror holder 2 and overturn downwards automatically when solar ray or ambient light are on the strong side, play the function that first secondary mirror holder 2 of speech control upwards or overturn downwards to reach best eye protection and best visual effect.

Fig. 30 shows an embodiment of the present novel lens frame electric turnable glasses, which is a sunshade wind-proof lens, wherein the sunshade wind-proof lens 22 is mounted at the position of the first pair of glasses frames 2, the sunshade wind-proof lens 22 is locked on the rotary bracket 3 through two fixing screws 33, the glasses function as manual control turning, photosensitive automatic turning and voice control turning sunshade wind-proof glasses, wherein the principle is consistent with the above description, and is not further explained.

Fig. 31 shows an embodiment of the set of electric reversible glasses of the present novel lens frame, which is generally not able to directly wear sunglasses for people with short-sighted eyes, because the short-sighted eyes will affect the eyesight if the short-sighted glasses are not worn, and thus the object in front of the short-sighted eyes cannot be clearly seen. So when using this glasses, can wear this glasses again on the myopia glasses that the user originally wore, so both can not influence user's eyesight and vision, can bring the convenience of using sunshade sunglasses and sunshade lens again through wearing this glasses to good protection eyes are not shone by the intense light. As shown in fig. 31, the user wears the glasses 39 used originally and then wears the glasses, the glasses are stacked above the glasses 39 worn originally by the user, the glasses frame of the glasses 39 supports the bottom cover 10 of the main glasses frame, the left glasses leg 391 of the glasses 39 supports the left glasses leg 5, the right glasses leg 392 of the glasses 39 supports the right glasses leg 5', the left and right lenses 393 and 394 of the glasses 39 are provided with the glasses configured by the user, and the nose support 14 with adjustable height and the nose support 395 of the glasses can be comfortably attached to the nose. When the glasses are used, the eyes of a user see through the left and right lenses 393 and 394 of the pair of glasses 39 worn by the user and then see the front through the left and right lenses 4 and 4' mounted on the first pair of spectacle frames 2 or the sun-shading wind-shielding lens 22, so that a myopia glasses crowd can normally use the glasses, and the glasses are used as set glasses. Wherein the control principle of the manual control turning and the photosensitive automatic turning and the voice control turning of the sun-shading windshield lens 22 of the first auxiliary spectacle frame 2 of the embodiment is the same as that of the above description, and will not be described.

Fig. 32 shows an embodiment of the electric reversible glasses with the novel lens frame, which is generally not able to directly wear sunglasses for people with short-sighted eyes, because the short-sighted eyes may affect the vision and may obscure the object in front if the short-sighted glasses are not worn. The user does not wear original myopia glasses and wants more convenient use this glasses, neither can influence user's eyesight and vision, can just bring the convenience of using sunshade sunglasses and sunshade lens that keeps out the wind again, and protection eyes that can be good are not by the highlight, and such requirement can be satisfied to this embodiment.

As shown in fig. 32, the main frame is provided with a detachable second sub-frame 35, and the second sub-frame 35 is provided with a plurality of fixing pins 353, 354, 355 which are respectively engaged with the fixing holes 101, 102, etc. of the main frame. The fixed posts 353, 354, 355 are provided at both ends and in the middle of the second secondary frame 35.

First, lenses with corresponding myopia degrees are configured at the positions of the left and right lenses 351 and 352 of the second auxiliary glasses frame 35 according to the myopia degrees of the left and right eyes of a user, a column 355 on the middle beam of the second auxiliary glasses frame 35 is inserted into a nose support insertion rod through hole 104 in the middle of the main glasses frame bottom cover 10, a left column 353 of the second auxiliary glasses frame 35 is inserted into a deep screw hole 101 in the left of the main glasses frame bottom cover 10, a right column 354 of the second auxiliary glasses frame 35 is inserted into a deep screw hole 102 in the right of the main glasses frame bottom cover 10, and therefore the three columns and the three holes in the corresponding positions are inserted and matched to enable the second auxiliary glasses frame 35 to be closely arranged on the main glasses frame bottom cover 10, and the glasses can be used. Wherein the second auxiliary spectacle frame 35 replaces the above mentioned glasses for myopia 39, when in use, the eyes of the user see through the left and right lenses 351 and 352 of the second auxiliary spectacle frame 35 and see through the sunglass lenses or the sun-shading and wind-shielding lenses 22 installed on the left and right lenses 4 and 4' of the first auxiliary spectacle frame 2 to watch the front, so that the people with myopia can also use the glasses normally, and at this time, the people can be more light and relaxed because the glasses for myopia 39 are not needed. The control principle of the manual control turning and the photosensitive automatic turning and the voice control turning of the sunglass lenses or the sun-shading and wind-shielding lenses 22 mounted on the first sub-frame 2 in this embodiment is the same as that described above, and will not be described.

Referring to fig. 1-27 and 31-34, the vision training function of the present invention is illustrated in an embodiment of the power-driven reversible eyeglasses, which takes the vision training of a myope as an example, and takes the myopic degree of both the left and right eyeglasses of a user as an example to facilitate the explanation of the working principle of the embodiment, and the left and right lenses 393 and 394 of the myopic eyeglasses 39 worn by the user are necessarily the myopic lenses with 200 degrees, or the left and right lenses 351 and 352 of the second auxiliary frame 35 installed at the corresponding position of the bottom shell 10 are also necessarily the myopic lenses with 200 degrees. If necessary, an optical lens frame 23 is installed at the position of the first sub-frame 2, and 100-degree far vision lenses are installed on the left and right lenses 4 and 4' of the optical lens frame 23, respectively, and the actual power of the far vision lenses should be configured with the proper power for the best vision training effect under the guidance of the professional ophthalmologist. Meanwhile, the first auxiliary frame 2 is turned upwards by an angle of 100 degrees by default, and then the glasses are put on, as shown in fig. 33, the first auxiliary frame 2 of the present embodiment is in the initial position and turned downwards to the position. When the glasses frame is used, the left and right glasses legs 5 and 5' are opened, the trigger detection switch 30 is closed, the battery 17 starts to supply power to the control circuit 15 to enter a standby state, the indicator lamp 81 is lightened, a manual control overturning program is started, the switch 74 is pressed for two seconds, the indicator lamp 81 is extinguished, the indicator lamp 84 is lightened, the loudspeaker 12 emits B four-tone prompt system to enter a vision training function mode, the indicator lamp 85 is lightened simultaneously, and the system is automatically shut down to stop vision training after the time length for training vision every time is 10 minutes. After the time length of the vision training is set, the user wears the glasses, presses the switch 71 once, the system starts to operate the vision training program and simultaneously triggers the control circuit 15 to provide electric energy for the motor 20 to rotate forwards, so that the rotation driving mechanism is driven to link the rotation support 3 to drive the first auxiliary spectacle frame 2 to turn upwards, when the first auxiliary spectacle frame 2 turns upwards for about 0.4 second or about 100 degrees, the control circuit 15 immediately stops providing the electric energy for the motor 20, the first auxiliary spectacle frame 2 keeps the upward turning state at about 100 degrees, as shown in fig. 34, at the moment, the user reads books or watches pictures at a safety distance of 30-40 CM through the myopia lenses of the normally worn myopia glasses 39 or the second auxiliary spectacle frame 35, and at the moment, the intraocular lenses of the user are the thickness when the user wears the 200-degree myopia glasses at ordinary times. Meanwhile, the system starts to time, after about 4 seconds, the control circuit 15 automatically supplies electric energy to the motor 20 for reverse rotation, so as to drive the rotation driving mechanism to link the rotation bracket 3 to drive the first auxiliary spectacle frame 2 to turn downwards, when the first auxiliary spectacle frame 2 turns downwards to a proper position, as shown in fig. 33, the switch pressing button 34 arranged on the rotation bracket 3 is pressed to the limit switch 29 arranged on the main spectacle frame surface cover 9, the limit switch 29 is closed to trigger the control circuit 15 to immediately stop supplying electric energy to the motor 20, at this time, the eyes of a user can read books or watch pictures by superposing the 200-degree myopia lenses of the user through the myopia glasses 39 worn by the user or the myopia lenses of the second auxiliary spectacle frame 35 on the 100-degree hyperopia lenses of the first auxiliary spectacle frame 2 respectively by superposing the left and right lenses 4' and the 100-degree hyperopia lenses of the first auxiliary spectacle frame 2, because the obtained degree of the myopia of the 200-degree myopia lenses of the myopia glasses 39 or the second auxiliary spectacle frame 35 is 100-degree hyperopia lenses of the first auxiliary spectacle frame 2 is 100 degrees, the user's intra-ocular lens is now forcibly thinned. Meanwhile, the system starts to time, after about 4 seconds, the control circuit 15 automatically supplies electric energy to the motor 20 to rotate forwards, so that the rotation driving mechanism is driven to link with the rotation bracket 3 to drive the first auxiliary spectacle frame 2 to turn upwards again to a proper position, and as shown in fig. 34, the thickness of the user when the lens in the eyeball recovers to wear 200-degree myopia glasses at ordinary times. Thus, the first auxiliary frame 2 regularly and automatically supplies electric energy to the motor 20 at intervals of 4 seconds through the control circuit 15 to regularly rotate forwards and backwards to drive the rotation driving mechanism to drive the first auxiliary frame 2 to regularly turn upwards or downwards, so that a user can alternately read books or watch pictures at the timing of 4 seconds when the myopia degree obtained by the user through the 200-degree myopia lenses of the glasses 39 or the second auxiliary frame 35 and the 100-degree hyperopia lenses superposed on the first auxiliary frame 2 is 100-degree myopia degree, namely the user can read the books or watch the pictures by using the 200-degree myopia lenses or watch the pictures for 4 seconds and then read the books or watch the pictures by using the 100-degree myopia lenses for 4 seconds, the 200-degree myopia lenses and the 100-degree myopia lenses are cyclically and alternately used for reading the books or watching the pictures in such a way that the crystalline lens inside the eyeball of the user is regularly thickened and thinned, the inner lens of the eyeball of the user gradually recovers to the elasticity of normal vision, thereby reducing and improving the myopia degree and achieving the effects of correcting and improving the vision of the eyes. The switch 72 is pressed once, the stay time of 4 seconds after the first auxiliary spectacle frame 2 is turned up and down each time is reduced by 0.5 second, namely, the frequency of turning up and down the first auxiliary spectacle frame 2 is increased, namely, the speed of turning up and down is increased, the stay time of the first auxiliary spectacle frame 2 after turning up and down each time is reduced by 0.5 second after the switch 72 is pressed once, and the stay time is adjusted according to the requirement, so that the optimal vision training effect is achieved. The switch 73 is pressed once, the staying time of 4 seconds after the first auxiliary spectacle frame 2 is turned up and down each time is increased by 0.5 second, namely, the frequency of turning up and down of the first auxiliary spectacle frame 2 is reduced, namely, the turning up and down speed is reduced, the staying time of the first auxiliary spectacle frame 2 after turning up and down each time is increased by 0.5 second after the switch 73 is pressed once, and the time is adjusted according to the requirement, so that the optimal vision training effect is achieved. When the switch is pressed for 72 seconds, the indicator lamp 85 is turned off, the indicator lamp 86 is turned on, and the loudspeaker 12 gives out sound B two times, so that the time length of each eyesight training is adjusted from 10 minutes to 20 minutes, and then the system is automatically turned off to stop the eyesight training. The switch 72 is pressed again for two seconds, the indicator lamp 86 is turned off, the indicator lamp 85 is turned on, and the loudspeaker 12 gives out a prompt to adjust the time length of vision training each time from 20 minutes to 10 minutes, and then the system is automatically shut down to stop vision training. That is, the switch 72 is pressed for two seconds to adjust the time length of each vision training for 10 minutes or 20 minutes so as to achieve the optimal vision training effect. The staying time of the first auxiliary frame 2 after the upward turning and the downward turning each time is 4 seconds and the time length of training the eyesight each time is 10 minutes or 20 minutes, and the staying time can be set in advance according to actual needs when a program of the control circuit 15 is programmed so as to achieve the optimal eyesight training effect.

Further, taking the visual training of the hyperopia person as an example, for convenience of explaining the working principle of the present embodiment, taking the hyperopia powers of the left and right eyes of the user as 200 degrees as an example, the left and right lenses 393 and 394 of the pair of hyperopic glasses 39 worn by the user in normal use are necessarily equipped with 200 degrees hyperopic lenses, or the left and right lenses 351 and 352 of the second pair of glasses frames 35 mounted at the corresponding positions of the bottom case 10 are necessarily equipped with 200 degrees hyperopic lenses. According to the requirement, the optical lens frame 23 is installed at the position of the first sub-frame 2, and the near vision lens of 100 degrees is installed on the left and right lenses 4 and 4' of the optical lens frame 23, respectively, and the actual degree of the near vision lens should be configured with the proper degree under the guidance of the professional ophthalmologist to achieve the best vision training effect. The using method and the working principle are similar to the embodiment of the eyesight training of the myopia patients, namely, a user reads books by using a 200-degree far vision lens or watches pictures for 4 seconds and then reads the books by using a 100-degree far vision lens or watches the pictures for 4 seconds, the 200-degree far vision lens and the 100-degree far vision lens are circularly and alternately used in this way to read the books or watch the pictures, the inner crystalline lens of the eyeball of the user is forced to be regularly thickened and thinned, the inner crystalline lens of the eyeball of the user gradually recovers to the elasticity of normal eyesight, the myopia degree is reduced and improved, the effect of correcting and improving the eyesight of the eye is achieved, and the detailed working principle is not explained any more.

Fig. 35 and 36 show an embodiment of charging the internal battery of the electric reversible glasses with the lens frame, in which the charging port waterproof plug 18 disposed on the left side of the main frame cover 9 plays a role of dust-proof and waterproof, when in use, the waterproof plug 18 is buckled out from the right, the charging plug is inserted into the charging seat 181 and inserted in place, the charging indicator 182 on the right is turned on to start charging the batteries 17 and 17' through the charging circuit disposed on the charging board 28, when the charging is fully performed, the indicator 182 is turned off to pull out the charging plug, and then the charging plug is plugged into the waterproof plug 18 to complete the charging.

When the glasses do not need to be worn, the glasses are taken off, the detection switch 30 is switched off after the left and right earpieces 5 and 5' are closed, the battery 17 stops supplying power to the control circuit 15, the indicator lamp 81 is turned off, and the glasses enter a power-off state. In this embodiment, a programmable processing MCU 15 'with shutdown and power-off memory functions can be adopted as required, when shutdown or automatic shutdown is performed after the battery 17 is completely consumed, the programmable processing MCU 15' can simultaneously memorize the settings of the running programs and functions, and when the glasses are used in next startup, the programs and functions do not need to be reset, and the system directly enters the set programs and functions before shutdown to operate, so that the glasses can be used more humanized and intelligent.

When a user needs to adjust the first auxiliary spectacle frame 2 of the pair of spectacles to a state of upturning 140 degrees or 100 degrees and turning down to the proper position, but does not start functions of manual turning, photosensitive automatic turning, voice control turning, eyesight training and the like, namely the control circuit 15 is completely closed to do no action, so that the first auxiliary spectacle frame 2 is used in a state of single upturning proper position or downturning proper position so as not to be interfered by the control circuit 15 when the first auxiliary spectacle frame 2 is electrically controlled to turn over, the switch 71 is pressed for three seconds, the system is shut down, the electronic function is temporarily closed, the first auxiliary spectacle frame 2 is electrically turned off, if other switches are pressed again, no reaction is caused, the switch 71 is pressed for two seconds, the system runs programs stored during shutdown, and simultaneously recovers the functions of all switches to start the control circuit 15 to electrically control the first auxiliary spectacle frame 2 to turn over again, thus, the glasses can be used more variously. The switch 71 is pressed to turn on and off, and the length of the time for pressing the switch 71 is set according to actual needs, so that the switch is convenient to use and can not be mistakenly operated to set the time, and the best use state and the best use feeling are achieved.

In the using process, if the set programs and functions are disordered or the default settings in factory shipment need to be used, the speaker 12 sends out the B three-voice control circuit 15 to restore the default settings in factory shipment after pressing the power control switch 71 for ten seconds.

As shown in fig. 37 and 38, in the embodiment of the height-adjustable nose pad of the novel glasses with lens frame capable of being turned electrically, the nose pad insertion rod 103 is disposed on the bottom cover 10 of the main frame, protruding points 105 are disposed on two sides of the nose pad insertion rod 103, wherein grooves 14 'are also disposed on two inner sides of the nose pad 14, the nose pad 14 is inserted into the nose pad insertion rod 103, the protruding points 105 disposed on two sides of the nose pad insertion rod 103 and the grooves 14' disposed on two inner sides of the nose pad 14 are tightly matched to form a step-type damping and a height-adjustable gear, the nose pad 14 is pushed upwards or pulled downwards as required to find a proper height, so that the nose pad 14 is tightly attached to the nose of a user, and an optimal wearing comfort level is achieved.

Fig. 39-41 show an embodiment of the novel lens frame of the power-driven reversible eyeglasses with adjustable length and capable of changing the temple bars with different sizes, and fig. 39 shows an embodiment of the length of the temple bar 38 'disposed on the right temple bar 5' and capable of changing different sizes. Be provided with bump 51' in the right earpiece 5' afterbody below, wherein be provided with recess 381' in right earpiece colludes 38' inboard below, insert right earpiece collude 38' on the 5' afterbody of right earpiece, carry out inseparable cooperation through setting up bump 51' of the right earpiece 5' afterbody below and the recess 381' of setting in right earpiece collude 38' inboard below, form the damping of stage formula and form the gear of adjusting length, it advances forward or extracts backward in order to find suitable length to collude 38' with right earpiece as required, thereby let right earpiece collude 38' just hug closely user's head, in order to reach best comfort level of wearing. Fig. 40 shows the small-sized right earpiece hook 38' being attached. Fig. 41 shows the installation of the large-sized right earpiece hook 38'. Can design several different sizes of earpiece of style as required and collude and be fit for the not crowd of equidimension of head and wear this glasses. The length adjustment and the exchange of the earpiece hook 38 on the left earpiece 5 are identical to the previous embodiments with different dimensions and are not described again.

Fig. 42 shows an embodiment of the present novel lens frame with an additional soft rubber sleeve for the electric turnover glasses motor, when in use, if the operation noise of the motor 20 is too large, the motor 20 is sleeved with a soft rubber sleeve 20' with a proper size and a proper thickness and then mounted on the main glasses frame surface cover 9, so that the noise generated during the operation of the motor 20 can be reduced, and the best use comfort can be achieved.

Fig. 43 and 44 show another embodiment of the present novel lens frame of electric reversible glasses, which is suitable for the people who are used to the left hand operation and driving a right gyro, and the difference of the structure is that the switch button and the indicator light are arranged on the left side of the main frame 1, the internal structure thereof is correspondingly mirrored, the operation principle and the implementation method thereof are similar to the previous embodiment, and will not be further explained.

As shown in fig. 45-47, this embodiment of the present invention is a further embodiment of the glasses with the lens frame capable of being turned over electrically, in which the rotation driving mechanism structure of the present embodiment directly inserts the shaft core of the motor 20 into the shaft hole of the rotation shaft 25 for linkage rotation, the structure of the rotation driving mechanism is simpler than that of the previous embodiment, and the present embodiment is suitable for designing a first sub-frame 2 which is lighter, and the first sub-frame 2 can directly drive the rotation driving mechanism linkage rotation support 3 to drive the first sub-frame 2 to turn over upwards and downwards without requiring a large torque motor 20, so that the components for amplifying the torque of the motor 20, such as the motor pinion 201, the fixed collar 202, and the large gear 24, are eliminated, and the rest of the internal structure, the operation principle, and the implementation method are similar to those of the previous embodiment and will not be described again.

All the embodiments are mentioned, wherein the first auxiliary frame 2 is not limited to be provided with lenses of sunglasses, optical lenses, sun-shading goggles, vision training glasses and the like, and other types of lenses can be provided according to specific requirements to facilitate the operation, for example, corresponding protective lenses can be provided during laser and radiation protection, and protective lenses in other fields can be provided, and the working principle and the implementation method thereof are similar to those of the foregoing embodiments and are not described again.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: it is to be understood that modifications may be made to the above-described arrangements in the embodiments or equivalents may be substituted for some of the features of the embodiments described above, and such modifications or substitutions may be made without departing from the spirit and scope of the present invention in its aspects.

Claims (10)

1. The novel glasses with the lens frame capable of being electrically turned is characterized by comprising a main glasses frame, a rotation driving mechanism and a control circuit, wherein the main glasses frame is provided with a replaceable first auxiliary glasses frame; the first auxiliary mirror bracket is provided with a rotating bracket fixedly connected with the rotating shaft, the rotating bracket is provided with two parallel clamping arms, one end of each clamping arm is clamped and fixed with the rotating shaft, the other ends of the two clamping arms are respectively connected with the fixed seat, each clamping arm is provided with a clearance groove, and the main mirror bracket is provided with an accommodating groove matched with the clamping arms.

2. The novel pair of electrically reversible eyeglasses with lens frames as defined in claim 1, wherein said rotational drive mechanism comprises a rotary shaft disposed in said main frame and a motor assembly for driving said rotary shaft.

3. The novel lens frame of power-flipping eyeglasses according to claim 2, wherein said motor assembly comprises a motor and a transmission gear disposed on a shaft of said motor.

4. The new lens frame power flip-flop eyeglasses of claim 1, wherein said first pair of eyeglasses frames have a sun-shading lens, a near-sighted lens or a far-sighted lens.

5. The novel pair of electrically reversible eyeglasses with lens frames as claimed in claim 1, wherein said main frame has a second removable auxiliary frame, said second auxiliary frame having a plurality of fastening posts distributed thereon for engaging with fastening holes of said main frame.

6. The novel pair of electrically reversible eyeglasses with a lens frame as claimed in claim 1, wherein said primary frame comprises a control switch connected to said control circuit for manually controlling the first secondary frame to turn and a light sensor and/or a voice control circuit electrically connected to said control circuit for triggering the secondary frame to turn automatically, said light sensor comprising a light guide cover, a fiber optic light guide or a direct sensor.

7. The pair of electrically reversible eyeglasses having a lens frame as in claim 6, wherein said main frame further comprises a temple detection switch connected to said control circuit for detecting whether said temple is closed or open, said temple detection switch comprising a travel switch.

8. The pair of electrically flipped glasses of claim 7 wherein the primary frame further comprises a first secondary frame flipping detection switch connected to the control circuit for detecting the flipping of the first secondary frame.

9. The novel pair of electrically reversible eyeglasses according to claim 1, wherein said first secondary frame is adjustable in rotation through an angle ranging from 90 to 180 degrees.

10. The novel eyeglasses with the power-driven turnover lens frame as claimed in claim 1, wherein the main frame further comprises a working indicator light and a speaker for sound prompt, the working indicator light and the speaker being connected to the control circuit.

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