CN113433704B - Glasses, charging method thereof and electronic equipment system - Google Patents

Abstract

The disclosure relates to the technical field of wearable equipment, in particular to glasses, a charging method thereof and an electronic equipment system, wherein the glasses comprise: the glasses comprise glasses main bodies, glasses legs, batteries and a spaced charging antenna module, wherein accommodating parts are arranged on the glasses legs; the battery is arranged on the accommodating part; the space charging antenna module is arranged on the accommodating part and connected with the battery, and is used for carrying out remote wireless charging on the battery. Not only ensures the endurance of the glasses, but also takes account of the weight reduction of the glasses.

Description

Glasses, charging method thereof and electronic equipment system

Technical Field

The disclosure relates to the technical field of wearable equipment, in particular to glasses, a charging method thereof and an electronic equipment system.

Background

With the development and progress of technology, virtual reality/augmented reality glasses are increasingly used. When the virtual reality/augmented reality glasses work, a large amount of image calculation work is needed, so that the virtual reality/augmented reality glasses have larger power consumption, and the capacity of a battery in the virtual reality/augmented reality glasses needs to be increased, so that the endurance time is improved. But the volume and weight of the battery may increase with the increase of the amount of electricity, which is disadvantageous for the weight reduction of the virtual reality/augmented reality glasses.

It should be noted that the information disclosed in the above background section is only for enhancing understanding of the background of the present disclosure and thus may include information that does not constitute prior art known to those of ordinary skill in the art.

Disclosure of Invention

The disclosure aims to provide glasses, a charging method thereof and an electronic device system, and further solve the problem that the endurance time requirement and the light-weight requirement in virtual reality/augmented reality glasses are contradictory at least to a certain extent.

According to a first aspect of the present disclosure, there is provided eyeglasses comprising:

a glasses body;

the glasses legs are provided with accommodating parts;

the battery is arranged on the accommodating part;

the space charging antenna module is arranged on the accommodating part and connected with the battery, and is used for conducting long-distance wireless charging on the battery.

According to a second aspect of the present disclosure, there is provided a method of charging a pair of spectacles, the method comprising:

detecting the residual electric quantity of a battery in the glasses;

when the residual electric quantity is smaller than a preset threshold value, an enabling signal is sent to a charging base, and the enabling signal is used for controlling the wireless charging base to emit a blank charging power supply signal;

and receiving the spaced charging source signal by using the spaced charging antenna module, wherein the spaced charging source signal is used for providing electric energy for the battery.

According to a third aspect of the present disclosure, there is provided an electronic device system including:

the glasses;

the charging base comprises a spaced charging transmitting module, and the spaced charging transmitting module is used for transmitting electromagnetic signals.

According to the glasses provided by the embodiment of the disclosure, the spaced charging antenna module capable of charging the battery remotely and wirelessly is arranged on the glasses leg, so that the glasses can be charged through remote wireless charging, namely, the glasses can be charged remotely when the glasses are in a use state, and therefore, the time for using the glasses with small-capacity batteries is prolonged, and the duration of the glasses is guaranteed, and the weight of the glasses is also reduced.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure. It will be apparent to those of ordinary skill in the art that the drawings in the following description are merely examples of the disclosure and that other drawings may be derived from them without undue effort.

FIG. 1 is a schematic view of a pair of eyeglasses provided in an exemplary embodiment of the present disclosure;

FIG. 2 is an exploded schematic view of a pair of eyeglasses provided in an exemplary embodiment of the present disclosure;

FIG. 3 is an exploded schematic view of another pair of eyeglasses provided in an exemplary embodiment of the present disclosure;

fig. 4 is a schematic diagram of a detection module according to an exemplary embodiment of the present disclosure;

fig. 5 is a flowchart of a method for blank charging of eyeglasses according to an exemplary embodiment of the present disclosure;

fig. 6 is a schematic diagram of an electronic device system according to an exemplary embodiment of the present disclosure.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. However, the exemplary embodiments can be embodied in many forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the example embodiments to those skilled in the art. The same reference numerals in the drawings denote the same or similar structures, and thus detailed descriptions thereof will be omitted.

Although relative terms such as "upper" and "lower" are used in this specification to describe the relative relationship of one component of an icon to another component, these terms are used in this specification for convenience only, such as in terms of the orientation of the examples described in the figures. It will be appreciated that if the device of the icon is flipped upside down, the recited "up" component will become the "down" component. When a structure is "on" another structure, it may mean that the structure is integrally formed with the other structure, or that the structure is "directly" disposed on the other structure, or that the structure is "indirectly" disposed on the other structure through another structure.

The terms "a," "an," "the," "said" and "at least one" are used to indicate the presence of one or more elements/components/etc.; the terms "comprising" and "having" are intended to be inclusive and mean that there may be additional elements/components/etc. in addition to the listed elements/components/etc.; the terms "first," "second," and "third," etc. are used merely as labels, and do not limit the number of their objects.

The exemplary embodiments of the present disclosure first provide a glasses, as shown in fig. 1 and 2, including: the glasses main body 110, the glasses legs 120, the battery 130 and the spaced charging antenna module 140, wherein the glasses legs 120 are provided with accommodating parts; the battery 130 is arranged at the accommodating part; the space charging antenna module 140 is disposed at the accommodating portion and connected to the battery 130, and the space charging antenna module 140 is used for remotely and wirelessly charging the battery 130.

According to the glasses provided by the embodiment of the disclosure, the spaced charging antenna module 140 capable of charging the battery 130 remotely and wirelessly is arranged on the glasses leg 120, so that the glasses can be charged through remote wireless charging, namely, the glasses can be charged remotely when the glasses are in a use state, and therefore, the time for using the glasses with the small-capacity battery 130 is increased, and not only is the endurance of the glasses ensured, but also the weight of the glasses is reduced.

The following will describe each component of the glasses provided in the embodiments of the present disclosure in detail:

the glasses provided in the embodiments of the present disclosure may be virtual reality glasses or intelligent glasses such as augmented reality glasses. The eyeglass body 110 may include lenses 111 and a frame 112, the lenses 111 being mounted to the frame 112. The lens 111 may be a display device, for example, the lens 111 may be an optical waveguide display device.

The eyeglass body 110 can include a first lens and a second lens, wherein at least one of the first lens and the second lens has an augmented reality function. For example, the first lens is an optical waveguide lens and the second lens is a plain lens; or the first lens and the second lens are both optical waveguide lenses, which is not particularly limited in the embodiments of the present disclosure.

The lens 111 may be embedded in the frame 112, and the frame 112 may be semi-looped around the lens 111 or the frame 112 may be semi-looped around the lens 111. For example, the frame 112 may have a first mounting hole to which the first lens is mounted and a second mounting hole to which the second lens is mounted. The frame 112 may include a front cover 1122 and a rear cover 1121, the front cover 1122 and the rear cover 1121 being snap-fit, and the lens 111 being positioned between the front cover 1122 and the rear cover 1121. A main signal line 113 may be further provided between the front cover 1122 and the rear cover 1121.

The temples 120 are connected to the frame 112, and the temples 120 and the frame 112 may be fixedly connected, for example, the temples 120 and the frame 112 may be connected by bolts; or the temple 120 and the frame 112 may be hinged, for example, the temple 120 and the frame 112 may be connected by a hinge. When the glasses legs 120 and the glasses frames 112 are fixedly connected, the relative positions of the glasses legs 120 and the glasses frames 112 are fixed, so that the projection light on the glasses legs 120 projects light to the lenses 111, and the problem that circuit devices are damaged due to multiple bending of the glasses legs 120 can be avoided. When the glasses legs 120 are hinged to the glasses frame 112, the glasses legs 120 can be bent when not in use, so that the glasses can be conveniently stored.

As shown in fig. 3, the temples 120 include a first case 121 and a second case 122, and the first case 121 is connected to the glasses main body 110; the second casing 122 is connected to the end of the first casing 121 far away from the glasses main body 110, the battery 130 and the spaced charging antenna module 140 are arranged on the second casing 122, a limiting plate 123 is arranged between the first casing 121 and the second casing 122, and the limiting plate 123 is used for limiting the battery 130.

The first housing 121 includes a first inner housing section 1212 and a first outer housing section 1211, the first outer housing section 1211 and the first inner housing section 1212 being connected to form a hollow first housing 121. The first outer shell segment 1211 may be coupled to the frame 112 and the first outer shell segment 1211 is provided with a notch on the inside, where the first inner shell segment 1212 is mounted. The gap in the first outer housing segment 1211 may facilitate installation of devices within the first housing 121, the first inner housing segment 1212 may close off the gap, and a bead of sealing glue may be provided between the first inner housing segment 1212 and the first outer housing segment 1211 to increase sealing performance.

The second housing 122 includes a second inner housing section 1222 and a second outer housing section 1221, the second outer housing section 1221 and the second inner housing section 1222 being joined to form the hollow second housing 122. The second outer housing section 1221 may be connected to the first outer housing section 1211, and the second outer housing section 1221 is provided with a notch on the inside, where the second inner housing section 1222 is mounted. The notch in the second outer housing section 1221 may facilitate mounting of the device within the second housing 122, the second inner housing section 1222 sealing the notch, and a sealing strip may be provided between the second inner housing section 1222 and the second outer housing section 1221 to increase sealing performance.

The limiting plate 123 may be disposed between the first inner housing section 1212 or the second inner housing section 1222. For example, a limiting plate 123 is disposed at one end of the first inner housing segment 1212 near the second inner housing segment 1222, and the limiting plate 123 may be integrally formed with the first inner housing segment 1212, or the limiting plate 123 and the first inner housing segment 1212 may be separately formed and then connected together. Alternatively, the second inner casing section 1222 is provided with a limiting plate 123 near one end of the first inner casing section 1212, and the limiting plate may be integrally formed with the second inner casing section 1222, or the limiting plate 123 and the second inner casing section 1222 may be separately formed and then connected together, which is not specifically limited in the embodiment of the present disclosure.

The battery 130 and the spaced charging antenna module 140 are arranged at the accommodating part, and the spaced charging antenna module 140 is arranged at the outer side of the battery 130, wherein the outer side of the battery 130 is the side, away from the user, of the battery 130 when the glasses are in the wearing state. The spaced charging antenna module 140 is disposed on the outer side of the battery 130, so that the spaced charging antenna module 140 can receive electromagnetic waves.

The battery 130 in the embodiment of the present disclosure may be a secondary battery 130 such as a lithium ion battery 130, a lithium iron phosphate battery 130, or the like. The battery 130 has a rectangular parallelepiped structure, and the thickness of the battery 130 is smaller than a preset thickness, for example, the preset threshold may be 5 mm, 4.5 mm, 4 mm, 3 mm, 2 mm, etc. The thickness of the battery 130 refers to the dimension of the battery 130 in the direction from the inside to the outside of the temple 120.

The spaced charging antenna module 140 may include an antenna radiator for receiving electromagnetic waves emitted from the charging base and a receiving circuit. The receiving circuit is connected with the antenna radiator, and the receiving circuit is used for converting a signal received by the antenna radiator into a charging signal (converting an alternating current signal into a direct current signal).

The antenna radiator may be disposed at an outer side of the battery 130 module, and the antenna radiator is disposed at an outer side of the battery 130, so that the spaced charging antenna module 140 is convenient to receive electromagnetic waves. The antenna radiator may be provided inside the temples 120 or on the surface of the temples 120.

For example, when the material of the second housing 122 is a conductive material, the antenna radiator may be provided at an outer surface of the second housing 122 or the antenna radiator may be embedded in the second housing 122 and exposed to the outer surface of the second housing 122. When the material of the second housing 122 is an insulating material, the antenna radiator may be disposed inside the second housing 122.

Further, in order to install the electrical components, the glasses provided in the embodiments of the present disclosure may further include an auxiliary board 150, the auxiliary board 150 is disposed on the accommodating portion, and the auxiliary board 150 is located on a side of the battery 130 near the glasses main body 110, and the battery 130 and the spaced charging antenna module 140 are respectively connected to the auxiliary board 150.

The sub-board 150 is provided with a charge management circuit, and the charge management circuit is respectively connected with the battery 130 and the spaced charge antenna module 140. The receiving circuit may be provided in the sub-board 150.

The auxiliary plate 150 is arranged on the first shell 121; the battery 130 and the spaced charging antenna module 140 are disposed in the second housing 122, and a limiting plate 123 is disposed between the first housing 121 and the second housing 122, where the limiting plate 123 is used for limiting the battery 130.

One side of the antenna radiator facing the auxiliary board 150 is provided with a connection piece, which extends to the auxiliary board 150 through the limiting board 123, so as to realize the electrical connection between the antenna radiator and the auxiliary board 150. A board-to-board connector may be provided between the battery 130 and the sub-board 150, through which the electrical connection of the sub-board 150 and the battery 130 is achieved.

In practical applications, the earpiece 120 may further integrate devices such as a speaker, a projection light machine, and a motherboard 190. The speaker is used to generate sound, and a speaker may be provided on one or both of the temples 120 or 120. The projection light machine is used for transmitting display light to the lens 111 to realize augmented reality display, and the projection light machine can be arranged on one glasses leg 120 or two glasses legs 120. The main board 190 may be disposed on either of the two temples 120, and a processor, a memory, various sensors, and the like may be integrated on the main board 190.

For example, the glasses provided in the embodiments of the present disclosure may include a first glasses leg 21 and a second glasses leg 22, the first glasses leg 21 is connected to one end of the glasses main body 110, and the battery 130 and the spaced charging antenna module 140 are disposed on the first glasses leg 21; the first glasses leg 21 is connected to the other end of the glasses main body 110, and the second glasses leg 22 is provided with a main board 190 and an optical machine module 180.

The first earpiece 21 may further be provided with a first speaker 160, where the first speaker 160 may be disposed in the second housing 122 of the first earpiece 21, and the first speaker 160 is disposed on a side of the battery 130 away from the first housing 121. The second earpiece 22 may further be provided with a second speaker 170, and the second speaker 170 may be disposed in the second housing 122 of the second earpiece 22, and the second speaker 170 is disposed on a side of the main board 190 away from the first housing 121. Of course, in practical applications, other devices may be integrated into the temple 120, which is not specifically limited in the embodiments of the present disclosure.

In the glasses with functions provided in the embodiments of the present disclosure, electrical connection between the main board 190 and the auxiliary board 150 is required, the auxiliary board 150 is disposed on the first glasses leg 21, and when the main board 190 is disposed on the second glasses leg 22, a routing channel may be disposed on the glasses frame 112, where the routing channel is used to accommodate the main signal line 113, and two ends of the main signal line 113 are respectively connected with the main board 190 and the auxiliary board 150. The wiring path on the frame 112 is provided from the contact portion of the frame 112 and the first temple 21 to the contact portion of the frame 112 and the second temple 22.

It should be noted that, the spaced charging in the embodiment of the disclosure refers to long-distance wireless charging, that is, the glasses are not in contact with the charging base, and the spaced charging antenna module 140 on the glasses is wirelessly charged by the electromagnetic wave emitted by the charging base. However, in practical applications, the spaced charging antenna module 140 may also be used for contact wireless charging of glasses.

In the space charge process, the space charge antenna module 140 receives the electromagnetic wave emitted from the charge base and converts the electromagnetic wave into an electrical signal to charge the battery 130. The battery 130 may generate heat during the charging process, and when the user wears the glasses to charge, the battery 130 generates too high heat, which may reduce the comfort of wearing by the user. Therefore, as shown in fig. 4, the glasses provided in the embodiments of the present disclosure may further include a detection module 210, where the detection module 210 is disposed on the glasses leg 120, and the detection module 210 is configured to detect a distance between the glasses and the human body, and determine the spaced charging power of the glasses according to the distance between the glasses and the human body.

When the detection module 210 detects that the distance between the glasses and the human body is smaller than the preset threshold, the glasses can be charged with first power, and when the detection module 210 detects that the distance between the glasses and the human body is larger than or equal to the preset threshold, the glasses can be charged with second power, and the second power is larger than the first power. Of course, in practical applications, the charging power may be divided into more types, which is not limited to the embodiment of the disclosure.

It should be noted that, the above-mentioned spaced charging power of the glasses refers to the power received by the spaced charging antenna module 140, and is not the power emitted by the charging base.

The detection module 210 may include a detection capacitive plate 211, a capacitive sensor 212, and a controller 213, the capacitive sensor 212 being connected to the detection capacitive plate 211, the controller 213 being connected to the capacitive sensor 212.

The human body belongs to a conductor, when the human body is close to the conductor on the electronic equipment, the capacitance value sensed by the conductor in the electronic equipment changes, and the approaching degree of the human body is detected by detecting the capacitance change of the conductor of the electronic equipment.

When the human body approaches the electronic equipment, the human body part and the conductor on the electronic conductor form a capacitor, wherein the parts of the human body opposite to the conductor are respectively capacitive plates. The capacitance values of the two capacitive plates are shown in the following formula:

d is the distance between the two plates, S is the opposite area of the two capacitance plates, k is the static constant, and according to the capacitance formula, when d is smaller, the capacitance value C is larger; when d becomes larger, the capacitance C becomes larger, and thus the distance between the human body and the electronic device can be detected by the conductor portion on the electronic device.

The capacitance sensor 212 is connected to the detection capacitance plate 211, so that the capacitance value of the capacitor formed by the human body and the detection capacitance plate 211 can be detected, and the distance between the human body and the detection capacitance plate 211 is determined according to the capacitance value of the capacitor.

The detection capacitor plate 211 is a conductive plate, and the detection capacitor plate 211 may be disposed on the inner side of the glasses leg 120, for example, the detection capacitor plate 211 is disposed on the inner side of the first housing 121 or the inner side of the second housing 122. When the detection capacitor plate 211 is disposed on the first housing 121 and the material of the first housing is a conductive material, the detection capacitor plate 211 may be embedded in the first housing 121 and exposed on the surface of the first housing 121. When the detection capacitor plate 211 is disposed on the first housing 121 and the material of the first housing 121 is an insulating material, the detection capacitor plate 211 may be embedded in the first housing 121 or disposed inside the first housing 121. When the detection capacitor plate 211 is disposed on the second housing 122 and the material of the first housing is a conductive material, the detection capacitor plate 211 may be embedded in the second housing 122 and exposed on the surface of the second housing 122. When the detection capacitor plate 211 is disposed on the second housing 122 and the material of the second housing 122 is an insulating material, the detection capacitor plate 211 may be embedded in the second housing 122 or disposed inside the second housing 122.

The detection capacitance plate 211 may be a conductor plate for detecting capacitance value provided separately on the glasses, or the detection capacitance plate 211 may be a conductor member common to other devices in the glasses. For example, the detection capacitor plate 211 may be a conductive member such as a power-on key, a volume key, a main board bracket, or a sub board bracket.

When the detection capacitor plate 211 is a volume key, the volume key is made of a conductive material, for example, the volume key may be made of an aluminum alloy, stainless steel, copper, or the like. The volume key may be provided on the temple 120 or the frame 112. An insulating coating can be arranged at the contact part of the volume key and the frame so as to suspend the volume key.

Here, a through hole may be provided in the temple 120 or the glasses frame 112, through which a volume key enters the inside of the glasses, and is connected to a volume adjusting circuit. To isolate the volume key from the temple 120 or the eyeglass frame 112, an insulating material may be coated on the volume key surface. Of course, in practical application, the inner wall of the through hole on the temple 120 or the glasses frame 112 may be coated with an insulating material.

When the detection capacitor plate 211 is a power-on key, the power-on key is made of a conductive material, for example, the power-on key may be made of an aluminum alloy, stainless steel, or the like. The power on key may be provided on the temple 120 or the frame 112. An insulating coating may be provided at the contact between the power-on key and the temple 120 or the frame 112 to provide a suspension of the power-on key.

Wherein, a through hole can be arranged on the glasses leg 120 or the glasses frame 112, and the starting key enters the inside of the glasses through the through hole and is connected to the starting circuit. To isolate the power key from the temple 120 or the eyeglass frame 112, an insulating material may be applied to the surface of the power key. Of course, in practical application, the inner wall of the through hole on the temple 120 or the glasses frame 112 may be coated with an insulating material.

When the detection capacitor plate 211 is a motherboard bracket, the material of the motherboard bracket may be a conductive material, for example, the material of the motherboard bracket is an aluminum alloy, copper, stainless steel, or the like. The main board support may be provided on the temple 120, and the main board 190 is mounted on the main board support.

When the detection capacitor plate 211 is a sub-plate holder, the material of the sub-plate holder may be a conductive material, such as aluminum alloy, copper, or stainless steel. The sub-panel support may be provided on the temple 120 and the platelet is mounted to the sub-panel support.

The controller 213 may be a processor of the glasses, the controller 213 is connected to the capacitance sensor 212, the controller 213 determines a distance between the glasses and the human body according to a capacitance value detected by the capacitance sensor 212, and controls the charging power of the battery 130 according to the distance between the glasses and the human body.

The controller 213 controls the charging power of the battery 130 by determining the charging power required by the battery 130 according to the distance between the glasses and the human body; the distance between the glasses and the charging base is obtained, the transmitting power of the charging base is determined according to the distance between the glasses and the charging base and the charging power required by the battery 130, and the charging base is controlled to transmit a wireless charging signal with the transmitting power.

According to the glasses provided by the embodiment of the disclosure, the spaced charging antenna module 140 capable of charging the battery 130 remotely and wirelessly is arranged on the glasses leg 120, so that the glasses can be charged through remote wireless charging, namely, the glasses can be charged remotely when the glasses are in a use state, and therefore, the time for using the glasses with the small-capacity battery 130 is increased, and not only is the endurance of the glasses ensured, but also the weight of the glasses is reduced.

The exemplary embodiments of the present disclosure also provide a method of charging a space for glasses, as shown in fig. 5, the method including the steps of:

step S510, detecting the residual electric quantity of the battery in the glasses;

step S530, when the residual electric quantity is smaller than a preset threshold value, an enabling signal is sent to the charging base, and the enabling signal is used for controlling the wireless charging base to emit a blank charging power supply signal;

in step S550, the spaced charging antenna module receives the spaced charging source signal, and the spaced charging source signal is used for providing electric energy to the battery.

The method for charging the glasses at intervals provided by the embodiment of the disclosure can be used for the glasses provided by the embodiment of the disclosure, and the glasses comprise: the glasses main body 110, the glasses legs 120, the battery 130 and the spaced charging antenna module 140, wherein the glasses legs 120 are provided with accommodating parts; the battery 130 is arranged at the accommodating part; the space charging antenna module 140 is disposed at the accommodating portion and connected to the battery 130, and the space charging antenna module 140 is used for remotely and wirelessly charging the battery 130.

In order to ensure comfort and safety of a user wearing the glasses provided by the embodiment of the disclosure, the glasses may further include a detection module 210, the detection module 210 is disposed on the glasses leg 120, and the detection module 210 is configured to detect a distance between the glasses and a human body and determine a space charging power of the glasses according to the distance between the glasses and the human body.

The method for charging the glasses at intervals provided by the embodiment of the disclosure detects the residual electric quantity of the battery 130 in the glasses; when the residual electric quantity is smaller than a preset threshold value, an enabling signal is sent to the charging base; the space charge antenna module 140 is utilized to receive the space charge source signal, the space charge source signal is used for providing electric energy for the battery 130, and long-distance wireless charging for the battery 130 when the electric quantity of the glasses is smaller than a preset threshold value is achieved, so that the time for using the glasses with the small-capacity battery 130 is prolonged, and not only is the endurance of the glasses ensured, but also the weight reduction of the glasses is considered.

The following will describe in detail each step of the method for charging the glasses at intervals according to the embodiment of the present disclosure:

in step S510, the remaining power of the battery 130 in the glasses may be detected.

The remaining power of the battery 130 can be detected in real time during the use process, and the detection of the remaining power of the battery 130 can be performed after the glasses are started. The remaining capacity of the battery 130 may be characterized by a percentage of the remaining capacity, and a circuit for detecting the remaining capacity is generally provided in the glasses, so that the remaining capacity information may be obtained from the circuit for detecting the remaining capacity in real time.

In step S530, when the remaining power is smaller than the preset threshold, an enable signal may be sent to the charging base, where the enable signal is used to control the wireless charging base to transmit the spaced charging power signal.

When the remaining power of the battery 130 is less than the preset threshold, it is considered that the battery 130 needs to be charged in order to keep the glasses capable of being used continuously. The preset threshold may be 10%, 20%, 30%, 35%, 40%, or the like. The enabling signal is a signal for indicating the charging base to start working, and the enabling signal can comprise a charging request signal and an identification signal, wherein the identification signal is used for being matched with the charging base, and the charging request signal is used for requesting the charging base to charge. Of course, in practical applications, the enable signal may also include other signals, which is not limited in this disclosure.

The enable signal is sent to the charging base by wireless transmission, for example, the enable signal may be sent to the charging base through the spaced charging antenna module 140. Or the enabling signal may be sent to the charging base by bluetooth or the like.

When the glasses further include the detection module 210, the enable signal may further include a charging power control signal, where the charging power control signal is used to control the transmitting power of the charging base. On this basis, step S530 may be implemented as follows: detecting the distance between the glasses and the human body; and sending an enabling signal to the charging base according to the distance between the glasses and the human body, wherein the enabling signal is used for controlling the wireless charging base to emit a spaced charging power supply signal and controlling the power of the power supply signal.

When the electric quantity of the battery 130 is lower than the preset threshold, the detection module 210 starts to work, the detection module 210 detects the distance between the human body and the glasses, and sends an enabling signal to the charging base according to the distance between the human body and the glasses. The enable signal at this time includes at least a charge request signal, an identification signal, and a charge power control signal. The charging base transmits a spaced charging source signal in response to the enable signal, which may be transmitted in the form of electromagnetic waves.

In step S550, the spaced charging source signal may be received by the spaced charging antenna module 140, and the spaced charging source signal is used to provide the electric power to the battery 130.

When the charging base receives the enabling signal, an electromagnetic signal (a blank charging source signal) is emitted according to the enabling signal. The spaced charging antenna module 140 in the glasses receives the electromagnetic signal and converts the electromagnetic signal into an electrical signal to charge the battery 130.

The method for charging the glasses at intervals provided by the embodiment of the disclosure detects the residual electric quantity of the battery 130 in the glasses; when the residual electric quantity is smaller than a preset threshold value, an enabling signal is sent to the charging base; the space charge antenna module 140 is utilized to receive the space charge source signal, the space charge source signal is used for providing electric energy for the battery 130, and long-distance wireless charging for the battery 130 when the electric quantity of the glasses is smaller than a preset threshold value is achieved, so that the time for using the glasses with the small-capacity battery 130 is prolonged, and not only is the endurance of the glasses ensured, but also the weight reduction of the glasses is considered.

The exemplary embodiments of the present disclosure also provide an electronic device system, as shown in fig. 6, including: the glasses 100 and the charging base 200 described above, the charging base 200 includes a spaced charging transmitting module, and the spaced charging transmitting module is used for transmitting electromagnetic signals.

Wherein, glasses include: the glasses main body 110, the glasses legs 120, the battery 130 and the spaced charging antenna module 140, wherein the glasses legs 120 are provided with accommodating parts; the battery 130 is arranged at the accommodating part; the space charging antenna module 140 is disposed at the accommodating portion and connected to the battery 130, and the space charging antenna module 140 is used for remotely and wirelessly charging the battery 130.

The charging base 200 may include a transmitting antenna, a converting circuit for connecting to a power source, and converting a power signal into an ac signal of a preset frequency, and a control module. The transmitting antenna and the converting circuit are connected with the transmitting circuit to receive the alternating current signal output by the converting circuit and transmit the electromagnetic signal through excitation of the alternating current signal.

In the embodiment of the disclosure, the glasses 100 and the charging base 200 may be remotely and wirelessly charged, and the glasses 100 and the charging base 200 need to be positioned during remote wireless charging, so that, on one hand, the distance between the glasses 100 and the charging base 200 is determined, and on the other hand, the orientation of the glasses 100 relative to the charging base 200 is determined. By way of example, the positioning of the glasses and charging base may be achieved by UWB positioning.

The electronic equipment system that this disclosed embodiment provided, including glasses 100, through set up in glasses that can be to battery 130 remote wireless charging's sky antenna module 140 that charges at glasses leg 120 for the glasses can charge through remote wireless charging, that is can charge the glasses when glasses are in the state of use remote distance, so, make the time that glasses that use low-capacity battery 130 can use increase, both guaranteed the duration of glasses and also considered the lightweight of glasses.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any adaptations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

Claims (9)

1. An eyeglass, the eyeglass comprising:

a glasses body;

the glasses legs are provided with accommodating parts;

the battery is arranged on the accommodating part;

the space charging antenna module is arranged on the accommodating part and connected with the battery, and is used for carrying out long-distance wireless charging on the battery;

the detection module comprises a detection capacitor plate, a capacitance sensor and a controller, wherein the detection capacitor plate is arranged on the inner side of each glasses leg, the capacitance sensor is connected with the detection capacitor plate, the controller is connected with the capacitance sensor, the detection capacitor plate is used for detecting the distance between the glasses and a human body and determining the spaced charging power of the glasses according to the distance between the glasses and the human body, and the spaced charging power refers to the power received by the spaced charging antenna module;

when the distance between the glasses and the human body is larger than or equal to the preset threshold value, the controller controls the glasses to be charged with second power, and the second power is larger than the first power.

2. The pair of eyeglasses of claim 1, wherein the spaced charging antenna module is disposed on an outer side of the battery, the outer side of the battery being a side of the battery away from the user when the pair of eyeglasses is in a worn state.

3. The eyewear of claim 2, further comprising:

the auxiliary plate is arranged on the containing part, the auxiliary plate is positioned on one side, close to the glasses main body, of the battery, and the battery and the spaced charging antenna module are respectively connected to the auxiliary plate.

4. The pair of spectacles of claim 3, wherein the secondary board is provided with a charge management circuit, and the charge management circuit is respectively connected with the battery and the spaced charge antenna module.

5. The eyewear of claim 3, wherein said temples comprise:

the first shell is connected with the glasses main body, and the auxiliary plate is arranged on the first shell;

the second casing, the second casing is connected in first casing keep away from the one end of glasses main part, the battery with separate empty antenna module that charges and locate the second casing, first casing with be provided with the limiting plate between the second casing, the limiting plate is used for right the battery is spacing.

6. The eyewear of claim 1, wherein said eyewear comprises:

the first glasses leg is connected to one end of the glasses main body, and the battery and the spaced charging antenna module are arranged on the first glasses leg;

the first glasses leg is connected to the other end of the glasses main body, and the second glasses leg is provided with a main board and an optical machine module.

7. A method for the spaced charging of eyeglasses, characterized in that it is for eyeglasses according to any one of claims 1 to 6, said method comprising:

detecting the residual electric quantity of a battery in the glasses;

when the residual electric quantity is smaller than a preset threshold value, an enabling signal is sent to the charging base, and the enabling signal is used for controlling the wireless charging base to emit a blank charging power supply signal;

and receiving the spaced charging power supply signal by using the spaced charging antenna module, wherein the spaced charging power supply signal is used for providing electric energy for the battery.

8. The method of claim 7, wherein the sending an enable signal to the charging dock comprises:

detecting the distance between the glasses and the human body;

and sending an enabling signal to the charging base according to the distance between the glasses and the human body, wherein the enabling signal comprises a charging power control signal.

9. An electronic device system, the electronic device system comprising:

the eyewear of any one of claims 1-6;

the charging base comprises a spaced charging transmitting module, and the spaced charging transmitting module is used for transmitting electromagnetic signals.