CN214678882U - Partitioned atomizing eye protection glasses - Google Patents

Abstract

The utility model discloses a subregion atomizing eye protection glasses, include: spectacle frame, spectacle lens, control center, power; the spectacle lens comprises a plurality of independent subareas, and each independent subarea is independently connected with a power supply; the control center, the power supply and the spectacle lenses are respectively arranged on the spectacle frame; the glasses frame is provided with a distance sensor for acquiring the distance between the glasses and a reading target object; when the distance between the glasses and the reading target object is smaller than the preset minimum using distance, the control center controls the power supply to electrify the glasses, otherwise, the glasses are not electrified; when the power supply supplies current to the eyeglass lens, the haze of the eyeglass lens is increased, and the voltage applied to each zone by the power supply is not completely the same. The utility model discloses a keep watch on user's reading distance, remind the distance of user timely adjustment self through atomizing mode, and then protect user's eyesight, can not make the user receive the frightening on the one hand, lead to user's distraction, on the other hand also can effectual realization to user's warning.

Description

Partitioned atomizing eye protection glasses

Technical Field

The utility model relates to an eyesight protection field, in particular to atomizing eye protection glasses of subregion.

Background

In recent years, with the comprehensive popularization and sinking of 3C electronic products to the children market, the children are provided with convenient and directional lives, and meanwhile, the problems of eye overuse, blue light hazard and the like caused by using an electronic screen are brought, and in addition, the heavy operation pressure and the poor eye using habit of the children lead to the gradual improvement of the myopia rate of the children and the gradual development of the children to be smaller. Parents are increasingly anxious.

In the reason of causing the myopia of children, the distance is too close and the sitting posture is seriously concerned by parents, most of the existing technologies use distance induction and a gyroscope to judge whether the user is too close and the sitting posture is bad, and then the user is reminded by vibration or voice. However, no matter the vibration reminding or the voice reminding is adopted, the functions of the user are not corrected essentially, and the user can still see the contents in the book, the television or the mobile phone even without improving the sitting posture, so that the contents can be completely ignored. If a strong and effective effect is to be achieved, only frequent and repeated harassment reminding is needed, which is not only unfavorable for children to form good sitting habits, but also can lead users to dislike the mind and refuse products to be used no longer.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a protect eye glasses based on distance, specific technical scheme is as follows:

in one aspect, there is provided a segmented atomizing eye-protection eyewear comprising: spectacle frame, spectacle lens, control center, power;

the spectacle lens comprises a plurality of independent subareas, and each independent subarea is independently connected with the power supply;

the control center, the power source and the spectacle lens are respectively arranged on the spectacle frame;

a sensor is arranged on the spectacle frame;

when the sensor detects a bad eye using state, the control center controls the power supply to electrify the spectacle lens, otherwise, the power supply is not electrified;

when the power supply energizes the ophthalmic lens, haze of the ophthalmic lens is increased.

Preferably, the sensor comprises a distance sensor for acquiring the distance between the glasses and the reading target object;

when the distance between the glasses and the reading target object is smaller than the preset minimum using distance, the control center controls the power supply to electrify the glasses, otherwise, the power supply is not electrified;

when the power supply energizes the ophthalmic lens, haze of the ophthalmic lens is increased.

Preferably, the partition is divided into an inner ring partition and a plurality of outer ring partitions which are sequentially surrounded.

Further preferably, when the power supply energizes the eyeglass lens, a power supply voltage of the power supply is gradually increased until the power supply voltage reaches a target voltage.

Further preferably, during the process of gradually increasing the supply voltage of the power supply, the supply voltage of the partition at the inner circle is smaller than or equal to the supply voltage of the partition at the outer circle.

Further preferably, during the process of gradually increasing the supply voltage of the power supply, the supply voltage of the partition at the outer circle is smaller than or equal to the supply voltage of the partition at the inner circle.

Further preferably, when the power supply supplies power to the eyeglass lens, the power supply voltage of the outer ring partition periodically jumps from a first target power supply voltage to a second target power supply voltage, and then jumps from the second target power supply voltage to the first target power supply voltage until the jump duration is longer than the maximum jump and blink duration, the power supply voltage of the outer ring partition is fixed to the first target power supply voltage, and the power supply voltage of the inner ring partition gradually increases to the first target power supply voltage.

Further preferably, when the power supply supplies power to the eyeglass lens, the power supply voltage of the outer ring partition is periodically and gradually reduced from a first target power supply voltage to a second target power supply voltage, and then gradually increased from the second target power supply voltage to the first target power supply voltage, until the respiration duration is longer than the maximum respiration duration, the power supply voltage of the outer ring partition is fixed to the first target power supply voltage, and the power supply voltage of the inner ring partition is gradually increased to the first target power supply voltage.

Preferably, the control center does not energize the eyeglass lens when the duration in which the actual use distance is less than the preset minimum use distance is less than a preset distance duration.

Preferably, a plurality of indicator lights are further arranged on the glasses frame and used for displaying the service time of the glasses in a step mode.

Further preferably, the spectacle frame is further provided with a buzzer, and when any one of the indicator lights turns to the working state from the idle state, the buzzer makes a sound.

Preferably, the ophthalmic lens is made using a PNLC material.

Preferably, the glasses further comprise a wearing sensor arranged on the glasses frame and used for detecting whether the glasses are used or not, and when the glasses are not used, the control center is in an idle state.

Preferably, two glasses legs of the glasses frame are respectively provided with a hall switch and a magnet, and when the glasses frame is opened, the hall switch senses the change of a magnetic field generated by the magnet and controls the control center to start working.

Preferably, the charging device further comprises a magnetic attraction charging base used for providing a charging interface for the battery.

Preferably, the control hub, the power source and the wear sensor are provided on the temple of the spectacle frame.

Preferably, the control hub, the power source and the wear sensor are provided on a spectacle frame of the spectacle frame.

The technical effects of the utility model: through a unique subarea atomization reminding mode, subarea atomization is carried out, the lens gradually spreads from the outer ring of the lens to the center of the visual field, a relatively mild reminding mode is provided for a user, a transition and adaptation process is provided for eyeballs, the burden of frequent short and instantaneous adjustment of ciliary muscles of the user is not increased, meanwhile, a good reminding effect can be achieved, atomization is a relatively continuous process, the user is given a chance for correction, and in the subarea gradual change process, once the user relieves the bad eye using state, for example, the user adjusts to a proper distance or corrects a correct sitting posture or stops using glasses and the like, the existing atomization area can be relieved in time, the transparent and visible state can be changed in time, and the reaction is quicker and more convenient. Compared with the prior art, the user is reminded through modes such as vibration and the like and direct atomization, the user cannot be frightened, and meanwhile the user can be effectively reminded and guided to adjust the posture of the user in time.

And the reverse PNLC material is creatively applied to the lens, the reverse PNLC technology is changed into fog when being electrified and is in a transparent state when not being electrified, and the technology applied to the glasses product has quite obvious energy consumption advantage compared with the liquid crystal dimming film which is changed into transparent when being electrified, and is more energy-saving. The reverse PNLC has the characteristic of no electricity and transparency, compared with the traditional liquid crystal dimming film, such as PDLC, the reverse PNLC has obvious haze advantage, the haze of the transparent state of the reverse PNLC can reach about 0.8%, while the transparent state of the PDLC can only be maintained at 3% -5%, and the reverse PNLC is much blurred compared with the reverse PNLC.

Drawings

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

Fig. 1 is a schematic view of the present invention;

FIG. 2 is a schematic view of a two-zone structure of the spectacle lens of the present invention;

FIG. 3 is a schematic view of a four-zone structure of the spectacle lens of the present invention;

fig. 4 is a schematic view of the glasses of the present invention before atomization;

fig. 5 is a reference schematic diagram in the atomization of the glasses according to the present invention;

fig. 6 is a schematic view of the glasses of the present invention after atomization;

FIG. 7 is a schematic view of the operation flow of the present invention;

fig. 8 is a schematic view of the whole structure of the present invention.

(1) A spectacle frame;

(2) an ophthalmic lens;

(3) a distance sensor;

(4) wearing a sensor;

(5) an indicator light;

(6) a power source.

Detailed Description

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular system structures, techniques, etc. in order to provide a thorough understanding of the embodiments of the present application. However, it will be apparent to one skilled in the art that the present application may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, devices, circuits, and methods are omitted so as not to obscure the description of the present application with unnecessary detail.

It will be understood that the terms "comprises" and/or "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

For the sake of simplicity, only the parts relevant to the present invention are schematically shown in the drawings, and they do not represent the actual structure as a product. In addition, in order to make the drawings concise and understandable, components having the same structure or function in some of the drawings are only schematically depicted, or only one of them is labeled. In this document, "one" means not only "only one" but also a case of "more than one".

It should be further understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.

In addition, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not intended to indicate or imply relative importance.

In order to more clearly illustrate embodiments of the present invention or technical solutions in the prior art, specific embodiments of the present invention will be described below with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be obtained from these drawings without inventive effort.

Example 1:

as shown in fig. 1-8, the present embodiment provides a pair of eye protection glasses with partitioned atomization, comprising: the spectacle frame (1), the spectacle lens (2), a control center and a power supply (6);

the spectacle lens (2) comprises a plurality of independent partitions, each independent partition being independently connected to the power source (6);

the control hub, the power source (6) and the spectacle lens (2) are respectively arranged on the spectacle frame (1);

when the eye protection glasses are in a bad eye using state, the control center controls the power supply to electrify the glasses, otherwise, the power supply is not electrified;

when the power supply energizes the ophthalmic lens, haze of the ophthalmic lens is increased.

Preferably, the controller is adopted to detect the poor eye use state, and the sensor comprises a distance sensor (3) for acquiring the distance between the glasses and the reading target object;

when the distance between the glasses and the reading target object is smaller than the preset minimum using distance, the control center controls the power supply (6) to electrify the glasses (2), otherwise, the power supply is not electrified;

when the power source (6) energizes the eyeglass lens (2), the haze of the eyeglass lens (2) is increased.

In the embodiment, the FPC main board is generally used to carry the control center, the control center is generally disposed at the pile head of the glasses frame (1), the power source (6), i.e. the power supply battery, is generally mounted at the pile head of the other side, and the distance sensor (3) is generally disposed at the connection position of the pile head and the glasses frame.

In a specific operation process, when a user wears the glasses, the distance sensor (3) continuously obtains the distance between the glasses and a book or other things read by the user, namely the actual use distance, when the distance between the glasses and a reading target object is smaller than the preset minimum use distance, the distance between the users is considered to be too far, correction is needed, and therefore the glasses (2) are powered on, and after the glasses are powered on, the haze of the glasses (2) can rise, so that the user is reminded to adjust the position in time, and the good reading distance is kept.

Also in the actual operation, the spectacle lens (2) is partitioned for diversity, each partition operating independently, so that the spectacle lens can assume a plurality of different opaque shapes.

Preferably, the subareas are divided into an inner ring subarea and a plurality of outer ring subareas; the partitions are mutually surrounded; the number of the partitions is more than or equal to two, and the partitions can be adaptively selected according to application requirements.

Taking the two-zone spectacle lens (2) as an example, as shown in fig. 2, a is an inner zone and B is an outer zone.

Specifically, the inner circle subarea is positioned at the position of the spectacle lens (2) relative to the center of the visual field, the shape of the inner circle subarea is similar to that of the spectacle lens (2), the position of the inner circle subarea extends outwards for a certain distance to define a range, the original inner circle subarea is removed to form a new outer circle subarea, and then the process is continuously repeated until the edge of the spectacle lens (2) is reached, so that the area division of the spectacle lens (2) is completed.

Preferably, the glasses further comprise a wearing sensor (4), wherein the wearing sensor (4) is arranged on the glasses frame (1) and is used for detecting whether the glasses are used or not, and the control center is in an idle state when the glasses are not used. An integrated timing module in the control hub to time when the glasses are in use; when the time that the glasses are in the used state exceeds the preset maximum use time, the control center controls the power supply (6) to electrify the glasses.

Certainly, in order to avoid the equipment from working without reason and causing the waste of electric power, a wearing sensor (4) is arranged on eyes to detect whether a user wears glasses, generally arranged at the bridge of the nose of the glasses, after the user wears the glasses, the wearing sensor (4) arranged at the bridge of the nose of the glasses frame (1) naturally detects that the user wears the glasses, and then informs a control center to work to control the operation of each part.

Preferably, the ophthalmic lens (2) is made using a PNLC material.

Meanwhile, generally, the spectacle lens (2) is made of PNLC materials, on one hand, the reverse PNLC technology is electrified to change fog and is not electrified to be in a transparent state, and the technology is applied to spectacle products and has quite obvious energy consumption advantage compared with a liquid crystal dimming film which is electrified to be transparent, and is more energy-saving.

On the other hand, the reverse PNLC has obvious haze advantage compared with PDLC due to the characteristic of no electricity for transparency, the haze of the transparent state of the reverse PNLC can reach about 0.8%, while the transparent state of the PDLC can only be maintained at 3% -5%, and the haze is much less compared with that of the reverse PNLC.

Preferably, the control centre does not energize the ophthalmic lens (2) when the duration of the actual use distance being smaller than a preset minimum use distance is smaller than a preset distance duration.

In the actual use process, the user can not directly atomize and shield the visual field, and the gesture of the user can be adjusted in the use process, so that the sensor detects that the actual use distance of the user is too close, but the prompting is not needed at the time.

Preferably, a plurality of indicator lamps (5) are further arranged on the glasses frame (1) and are used for displaying the service time of the glasses in a stepped mode; the glasses frame (1) is further provided with a buzzer, and when any indicator light (5) turns to a working state from an idle state, the buzzer makes a sound.

Specifically, three time display indicator lamps (5) are provided on the opposite side of the charged temple, representing 3 h. A light is lit whenever the user wears more than 1 h. 3 were not counted after all lit up. When the first lamp is lightened, the buzzer rings once and then rings once every hour, the buzzer rings once when the second lamp is lightened, and the second lamp emits 'clattering and clattering' when the third lamp is lightened. The three lamps are not reminded after being fully lighted.

Preferably, the glasses lens is provided with a blue light prevention coating for preventing blue light and protecting eyes.

Further preferably, two glasses legs of the glasses frame are respectively provided with a hall switch and a magnet, and when the glasses legs are opened, the hall switches sense the change of a magnetic field generated by the magnet and control the control center to start working.

At actual operation in-process, can not let glasses be under long-term operating condition, so can make duration step-down, so be provided with corresponding hall switch and magnet on two mirror legs respectively, when the mirror leg is in fold condition, hall switch can sense the produced magnetic field of magnet, and then closes power (6) to the stop work of control centre.

Further preferably, still include magnetism and inhale the charging base for the battery provides the interface that charges.

Preferably, the control centre, the power source (6) and the wear sensor are arranged on the temple of the spectacle frame (1).

Preferably, the control hub, the power source (6) and the wear sensor are arranged on a spectacle frame of the spectacle frame (1).

In this embodiment, by monitoring the reading distance of the user, when the distance of the user exceeds a certain specific value, the user is considered that the posture of the user needs to be corrected, and then the user is reminded of timely adjusting the distance of the user in an atomizing manner, so that the eyesight of the user is protected.

Example 2:

as shown in fig. 1 to 8, this embodiment provides a pair of partitioned atomizing eye protection glasses, based on embodiment 1, when the power supply (6) supplies power to the eyeglass lenses (2), the power supply voltage of the power supply (6) is gradually increased until the power supply voltage reaches a target voltage.

In the embodiment, the reminding manner for the user is generally performed in a gradual manner, that is, the haze of the spectacle lens (2) is slowly increased by raising the voltage.

Preferably, during the gradual increase of the supply voltage of the power supply (6), the supply voltage of the sectors at the inner circle relative to the partition at the outer circle is less than or equal to the supply voltage of the sectors at the outer circle relative to the partition;

or:

in the process of gradually increasing the supply voltage of the power supply (6), the supply voltage of the subarea at the outer circle is smaller than or equal to the supply voltage of the subarea at the inner circle.

Meanwhile, in the actual use process, a zone atomization mode can be adopted, so that the spectacle lens (2) is continuously atomized from the inner ring to the outer ring, and the spectacle lens (2) can be continuously atomized from the outer ring to the inner ring.

Specifically, when the user is too close, the user can directly and instantaneously atomize, and the user experience is affected. Although this method has a strong and intuitive effect, the direct atomization and the definition can make the ciliary muscle of the user frequently and instantly adjust, but can aggravate the visual fatigue, on the other hand, the design can frequently interrupt the visual field of the user, reduce the working efficiency of the user, and also can make the user dislike. And the subarea atomization or slow atomization has a relatively continuous process, the continuous process gives a chance for the user to correct, once the user adjusts to a proper distance or corrects a correct sitting posture, the subarea atomization or slow atomization can be timely changed into a transparent and visible state, and the reaction is quicker and more convenient.

In a specific operation process, taking a four-zone lens as an example, when the distance detected by the distance sensor is 5-25cm, if the state lasts for 5s, it is determined that the distance is too close, and at this time, the two lenses gradually turn black at the same time. And completely blackened within the next 6s to make a strong reminder that the haze per second varies as follows:

time of day	Area and haze
		6s	a：65％、b:90％、c:90％、d：90％
7s	a：40％、b:65％、c:90％、d：90％
		8s	a：15％、b:40％、c:65％、d：90％
9s	a：8％、b:15％、c:40％、d：65％
		10s	a：8％、b:8％、c:15％、d：40％
11s	a：8％、b:8％、c:8％、d：8％

Example 3:

as shown in fig. 1 to 8, this embodiment provides a pair of distance-based eye protection glasses, based on embodiment 1, when the power supply (6) supplies power to the glasses lenses (2), the power supply voltage of the outer zone periodically jumps from a first target power supply voltage to a second target power supply voltage, and then jumps from the second target power supply voltage to the first target power supply voltage, until after the jump duration is longer than the maximum jump duration, the power supply voltage of the outer zone is fixed to the first target power supply voltage, and the power supply voltage of the inner zone gradually increases to the first target power supply voltage.

In this embodiment, being equivalent to jump atomizing, the user is when using, and the last complete atomizing of glasses for a while resumes normal for a while again to remind and be used for in time carrying out the adjustment of distance.

Specifically, when a user looks near, the outermost zones of the left and right lenses become fog and change between two endpoint values of the maximum voltage and the minimum voltage to realize a flicker prompt, if the user is not corrected after a period of time, the outer zone keeps atomizing and stops flickering, the inner zone is at the maximum voltage and becomes fog, so that the visual field of the user is fuzzy, and a forced reminding effect is achieved.

Example 4:

as shown in fig. 1 to 8, this embodiment provides a pair of distance-based eye protection glasses, based on embodiment 1, when the power supply (6) supplies power to the glasses lenses (2), the power supply voltage of the outer zone gradually decreases from a first target power supply voltage to a second target power supply voltage periodically, and then gradually increases from the second target power supply voltage to the first target power supply voltage;

if the distance between the glasses and the reading target object is still smaller than the minimum using distance after the preset time, the power supply voltage of the outer ring partition is fixed to the first target power supply voltage, and the power supply voltage of the inner ring partition is gradually increased to the first target power supply voltage.

In this embodiment, a manner similar to breathing is adopted for reminding, specifically, when a user looks near, peripheral zones of left and right lenses reciprocate from gradually changing fog and gradually changing zones to be in a breathing state, namely, the first target power supply voltage → the minimum power supply voltage → the first target power supply voltage continuously and repeatedly change, so that the user is reminded, if the user is not corrected after a period of time, the outer zone keeps atomizing and stops breathing, the inner zone gradually changes fog until the first target power supply voltage is reached, the user has a blurred vision, and a forced reminding effect is achieved.

While the preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the appended claims be interpreted as including the preferred embodiment and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (14)

1. A zoned atomizing eye-protection eyewear, comprising: spectacle frame, spectacle lens, control center, power;

the spectacle lens comprises a plurality of independent subareas, and each independent subarea is independently connected with the power supply;

the spectacle lens is arranged on the spectacle frame;

when the eye protection glasses are in a bad eye using state, the control center controls the power supply to electrify the glasses, otherwise, the power supply is not electrified;

when the power supply energizes the ophthalmic lens, haze of the ophthalmic lens is increased.

2. The sectional atomizing eye protection glasses according to claim 1, wherein the eye protection glasses detect the bad eye condition through a sensor arranged on a glasses frame, the sensor comprises a distance sensor for acquiring the distance between the glasses and a reading target object;

when the distance between the glasses and the reading target object is smaller than the preset minimum using distance, the control center controls the power supply to electrify the glasses, otherwise, the power supply is not electrified.

3. A sectional atomizing eye-protection spectacles according to claim 1, wherein the sections are divided into an inner section and a plurality of successively surrounding outer sections.

4. The sectional-atomizing eye-protection glasses according to claim 3, wherein when the power supply supplies power to the glasses lenses, the power supply voltage of the power supply is gradually increased until the power supply voltage reaches a target voltage, and in the course of the gradual increase of the power supply voltage of the power supply, the power supply voltage of the sections at the relatively inner circle is less than or equal to the power supply voltage of the sections at the relatively outer circle.

5. The sectional-atomizing eye-protection glasses according to claim 3, wherein when the power supply supplies power to the glasses lenses, the power supply voltage of the power supply is gradually increased, and in the process of gradually increasing the power supply voltage of the power supply, the power supply voltage of the section at the outer circle is smaller than or equal to the power supply voltage of the section at the inner circle.

6. The sectional-fogging eye protection glasses according to claim 3 wherein when the power supply supplies power to the glasses lenses, the power supply voltage of the outer section periodically jumps from a first target power supply voltage to a second target power supply voltage and then jumps from the second target power supply voltage to the first target power supply voltage until after a jump duration is greater than a maximum jump duration, the power supply voltage of the outer section is fixed to the first target power supply voltage and the power supply voltage of the inner section gradually increases to the first target power supply voltage.

7. The sectional-atomizing eye-protection glasses according to claim 3, wherein when the power source supplies power to the glasses lenses, the power supply voltage of the outer-ring section is periodically gradually decreased from a first target power supply voltage to a second target power supply voltage, and then gradually increased from the second target power supply voltage to the first target power supply voltage, until the breathing duration is longer than the maximum breathing duration, the power supply voltage of the outer-ring section is fixed to the first target power supply voltage, and the power supply voltage of the inner-ring section is gradually increased to the first target power supply voltage.

8. The zone atomizing eye-protection glasses according to claim 2, wherein the control center does not energize the glasses lenses when a duration of actual use distance less than a preset minimum use distance is less than a duration threshold.

9. The sectional atomizing eye-protection glasses according to claim 8, wherein a plurality of indicator lights are further provided on the glasses frame for displaying the using time of the glasses in a stepwise manner.

10. The zoned atomizing eye-protection glasses according to claim 1, wherein the ophthalmic lenses are made using a reverse PNLC material.

11. The sectional atomizing eye-protection glasses according to claim 1, further comprising a wearing sensor disposed on the glasses frame for detecting whether the glasses are used, wherein the control center is in an idle state when the glasses are not used.

12. The zoned atomizing eye-protection glasses according to claim 11, wherein the control hub is timed when the glasses are in use;

when the time that the glasses are in the used state exceeds the preset maximum use time, the glasses are judged to be in the bad eye use state, and the control center controls the power supply to electrify the glasses.

13. The sectional atomizing eye-protection glasses according to claim 1, wherein two glasses legs of the glasses frame are respectively provided with a Hall switch and a magnet for judging whether the glasses legs are opened or not, so as to control the control center to start or stop working.

14. The zone atomizing eye-protection glasses according to claim 11, wherein the control hub, the power source and the wear sensor are disposed on a temple of the glasses frame;

or:

the control hub, the power source and the wear sensor are disposed on a spectacle frame of the spectacle frame.

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