CN216248657U - Photovoltaic automatic acquisition power supply intelligent glasses - Google Patents

Abstract

The utility model discloses intelligent glasses with photovoltaic automatic acquisition power supply, which comprise a glasses frame body, a glasses beam wiring groove connected with the upper edge of the glasses frame body, a glasses nose bridge cavity arranged in the middle of the glasses frame body and communicated with the inside of the glasses beam wiring groove, a photovoltaic acquisition unit embedded in the glasses nose bridge cavity, a glasses leg cavity connected with the glasses frame body and communicated with the inside of the glasses beam wiring groove, and a photovoltaic conversion module, a controller, a rechargeable energy storage unit and an intelligent device arranged in the glasses leg cavity. According to the intelligent device, solar energy is converted into electric energy through the photovoltaic acquisition unit, the photovoltaic conversion module boosts and amplifies weak electric energy under the action of the controller, and then the output power supply charges the rechargeable energy storage unit, so that the power utilization requirement of the intelligent device is guaranteed, and the defect that the battery has limited power storage capacity and cannot support enough working time due to short endurance time is overcome.

Description

Photovoltaic automatic acquisition power supply intelligent glasses

Technical Field

The utility model belongs to the technical field of power supply of intelligent wearable equipment, and particularly relates to intelligent glasses with photovoltaic automatic acquisition power supply.

Background

Along with the rapid development of science and technology, more and more intelligent wearable electronic products are applied to our lives, and people can enjoy the convenience and fun of the intelligent electronic products at any time and any place, through intelligent wearable equipment, people can better sense external and self information, and can process information more efficiently under the assistance of computers, networks and even other people, so that more seamless communication is realized, wherein intelligent glasses are gradually known and used by people, the intelligent glasses generally refer to a glasses equipment which is provided with an electronic device on the basis of conventional glasses to realize one or more functions, is one of the most looked wearable intelligent equipment, and is widely considered to be convenient for people's lives due to the characteristics of personal wearing, convenient use, small size and the like, is regarded as an important growth point of future intelligent technology products. The intelligent glasses have very wide application prospects in the fields of traffic, marketing, management, training, entertainment, education, art, sports, travel, shopping, social contact and the like.

The intelligent glasses industry is still in the initial development stage at the present stage, and is continuously researched and explored in many application fields, but the development speed is rapid, the market scale is rapidly expanded in the future, and the experience effect of the intelligent glasses is greatly improved along with the arrival of the 5G era. Currently, smart glasses products with functions of positioning, photographing, playing music and the like have appeared, and in these products, a power supply part of the smart glasses products generally adopts a built-in battery for power supply, but the power supply part is limited by the size of the glasses and the wearing comfort, and the volume and the weight of the battery are not too large, so that the power storage capacity of the battery is limited, the endurance time of the smart glasses is generally short, and the smart glasses cannot support enough working hours.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, the utility model provides the intelligent glasses with the photovoltaic automatic acquisition power supply, which can be used for widely acquiring photovoltaic energy through the photovoltaic acquisition unit and converting the photovoltaic energy into electric energy to charge the rechargeable energy storage unit.

In order to achieve the purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a photovoltaic automatic acquisition power supply intelligence glasses, including the picture frame body, with along the mirror crossbeam trough of connecting on the picture frame body, set up in the middle of the picture frame body locate and with the mirror nose bridge chamber of the inside intercommunication of mirror crossbeam trough, inlay in photovoltaic acquisition unit in the mirror nose bridge chamber, with this body coupling of picture frame and with the mirror leg chamber of the inside intercommunication of mirror crossbeam trough, and set up in photovoltaic conversion module, controller, chargeable energy storage unit, the intelligent device of mirror leg intracavity, wherein, photovoltaic acquisition unit with photovoltaic conversion module links to each other, photovoltaic conversion module respectively with controller and chargeable energy storage unit link to each other, the intelligent device respectively with chargeable energy storage unit and controller link to each other.

Furthermore, the photovoltaic conversion module comprises a photovoltaic conversion chip with the model of ADP5090, and an acquisition circuit, a wake-up circuit and a bridge circuit which are connected with the photovoltaic conversion chip, wherein the photovoltaic conversion chip is connected with the rechargeable energy storage unit, the acquisition circuit is connected with the photovoltaic acquisition unit, and the wake-up circuit is connected with the controller.

Further, the acquisition circuit includes one end with the SW pin of photovoltaic conversion chip links to each other and the other end with the inductance L1 that the VIN pin of photovoltaic conversion chip links to each other, one end with inductance L1 links to each other and the electric capacity C1 of other end ground connection, one end with electric capacity C1 links to each other and the interface J1 of other end ground connection, one end with the MPPT pin of photovoltaic conversion chip links to each other and the other end with resistance R1 that the VIN pin of photovoltaic conversion chip links to each other, and one end with the MPPT pin of photovoltaic conversion chip links to each other and the resistance R2 of other end ground connection, wherein, interface J1 is used for connecting the photovoltaic acquisition unit.

Further, the wake-UP circuit includes a battery B1 having one end connected to the BUCK _ UP pin of the photovoltaic conversion chip and the other end connected to the MINOP pin of the photovoltaic conversion chip, and a resistor R3 having one end connected to the MINOP pin of the photovoltaic conversion chip and the other end grounded, where the PGOOD pin and the DIS _ SW pin of the photovoltaic conversion chip are used to connect the controller.

Further, the bridge circuit comprises a resistor R4 with one end connected with the REF pin of the photovoltaic conversion chip and the other end connected with the SETSD pin of the photovoltaic conversion chip, a resistor R5 with one end connected with the REF pin of the photovoltaic conversion chip and the other end connected with the SETPG pin of the photovoltaic conversion chip, a resistor R6 with one end connected with the REF pin of the photovoltaic conversion chip and the other end connected with the TERM pin of the photovoltaic conversion chip, a resistor R7 with one end connected with the SETSD pin of the photovoltaic conversion chip and the other end grounded, a resistor R8 with one end connected with the SETPG pin of the photovoltaic conversion chip and the other end grounded, and a resistor R9 with one end connected with the TERM pin of the photovoltaic conversion chip and the other end grounded.

Further, the photovoltaic collection unit is a miniature photovoltaic panel.

Further, the rechargeable energy storage unit is a rechargeable button-type lithium battery.

Furthermore, the mirror frame body, the mirror beam wiring groove, the mirror nose bridge cavity and the mirror leg cavity are all made of titanium materials.

Compared with the prior art, the utility model has the following beneficial effects:

(1) the utility model fully utilizes the relatively large space of the bridge cavity of the nose and the leg cavities of the glasses to place the electronic components therein, fully utilizes the long and narrow space of the bridge wiring groove of the cross mirror of the glasses to realize the connection of the electronic components, the photovoltaic acquisition unit converts solar energy into electric energy, the photovoltaic conversion module boosts and amplifies the weak electric energy under the action of the controller, and then outputs a power supply to charge the rechargeable energy storage unit, thereby ensured intelligent device's power consumption demand, can not use up and can't normally work because of battery power, compensatied the limited duration that leads to of electric power storage capacity of battery and shorter and can't support the not enough of sufficient operating duration.

(2) The utility model adopts the photovoltaic conversion chip with the model number of ADP5090 and the matched acquisition circuit, the wake-up circuit and the bridge circuit which are connected with the photovoltaic conversion chip, realizes the high-efficiency acquisition and processing of energy, and the acquisition circuit, the wake-up circuit and the bridge circuit are simple in design so as to save space as much as possible.

(3) The photovoltaic acquisition unit is a miniature photovoltaic panel, and can be embedded on the bridge cavity of the nose of the mirror without blocking sight while increasing the photovoltaic acquisition area as much as possible.

(4) The rechargeable energy storage unit is a rechargeable button type lithium battery which not only has high energy storage density, but also is convenient to mount in the cavity of the glasses leg due to small volume.

(5) The spectacle frame body, the mirror crossbeam wiring groove, the mirror nose bridge cavity and the mirror leg cavity are all made of titanium materials, the titanium materials are light materials, and the weight of the spectacles can be reduced to the maximum extent on the basis of mounting of all electronic components.

Drawings

FIG. 1 is a schematic diagram of the system of the present invention.

Fig. 2 is a schematic diagram of the control principle of the present invention.

Fig. 3 is a schematic diagram of the acquisition circuit of the present invention.

Fig. 4 is a schematic diagram of a wake-up circuit of the present invention.

Fig. 5 is a schematic diagram of a bridge circuit of the present invention.

In the drawings, the names of the parts corresponding to the reference numerals are as follows:

the glasses frame comprises a glass frame body 1, a 2-glass beam wiring groove, a 3-glass nose bridge cavity, a 4-photovoltaic acquisition unit, a 5-glass leg cavity, a 6-photovoltaic conversion module, a 7-controller, an 8-rechargeable energy storage unit, a 9-intelligent device, a 601-photovoltaic conversion chip, a 602-acquisition circuit, a 603-wake-up circuit and a 604-bridge circuit.

Detailed Description

The present invention is further illustrated by the following figures and examples, which include, but are not limited to, the following examples.

Examples

As shown in fig. 1 to 5, the utility model includes a frame body 1, a bridge wiring slot 2, a bridge cavity 3, a photovoltaic collection unit 4, a leg cavity 5, a photovoltaic conversion module 6, a controller 7, a rechargeable energy storage unit 8, and an intelligent device 9, in this embodiment, the frame body 1 includes basic structures of a frame, a lens, a bridge, and legs of glasses, the photovoltaic is solar energy, the photovoltaic collection unit 4 is embedded in the bridge cavity 3 right in front of the glasses, so as to facilitate the efficient collection of solar energy, the photovoltaic conversion module 6, the controller 7, the rechargeable energy storage unit 8, and the intelligent device 9 are disposed in the leg cavities 5 at two sides, which are relatively large in space and relatively hidden, and further process the collected energy and charge the rechargeable energy storage unit 8 to meet the electricity demand of the intelligent device 9, by disposing the bridge wiring slot 2, realized photovoltaic collection unit 4, photovoltaic conversion module 6, controller 7, chargeable energy storage unit 8, intelligent device 9's interconnect, in this embodiment, the cavity in bridge of the nose chamber 3 and mirror leg chamber 5 is all suitably done greatly, nevertheless receive the glasses structure and wear the restriction, the space is still comparatively limited, so photovoltaic collection unit 4, photovoltaic conversion module 6, controller 7, chargeable energy storage unit 8, intelligent device 9 all adopts miniaturized preparation, the characteristics of glasses personal wearing have been fully utilized to this embodiment, automatic solar energy collection in open air activity through glasses person of wearing, charge chargeable energy storage unit 8 in order to guarantee that intelligent device 9 can not use up because of chargeable energy storage unit 8 electric quantity and can't normally work.

In this embodiment, the photovoltaic conversion module 6 includes a photovoltaic conversion chip 601 with a model of ADP5090, and an acquisition circuit 602, a wake-up circuit 603, and a bridge circuit 604 all connected to the photovoltaic conversion chip 601, wherein the photovoltaic conversion chip 601 is connected to the rechargeable energy storage unit 8, the acquisition circuit 602 is connected to the photovoltaic acquisition unit 4, and the wake-up circuit 603 is connected to the controller 7, so as to implement efficient acquisition and processing of energy, and the acquisition circuit 602, the wake-up circuit 603, and the bridge circuit 604 are simple in design to save space as much as possible.

In this embodiment, the acquisition circuit 602 includes an inductor L1 having one end connected to the SW pin of the photovoltaic conversion chip 601 and the other end connected to the VIN pin of the photovoltaic conversion chip 601, a capacitor C1 having one end connected to the inductor L1 and the other end grounded, an interface J1 having one end connected to the capacitor C1 and the other end grounded, a resistor R1 having one end connected to the MPPT pin of the photovoltaic conversion chip 601 and the other end connected to the VIN pin of the photovoltaic conversion chip 601, and a resistor R2 having one end connected to the MPPT pin of the photovoltaic conversion chip 601 and the other end grounded, where the interface J1 is used to connect the photovoltaic acquisition unit 4.

In the present embodiment, the wake-UP circuit 603 includes a battery B1 having one end connected to the BUCK _ UP pin of the photovoltaic conversion chip 601 and the other end connected to the MINOP pin of the photovoltaic conversion chip 601, and a resistor R3 having one end connected to the MINOP pin of the photovoltaic conversion chip 601 and the other end grounded, wherein the PGOOD pin and the DIS _ SW pin of the photovoltaic conversion chip 601 are used for connecting the controller 7.

In the present embodiment, the bridge circuit 604 includes a resistor R4 having one end connected to the REF pin of the photovoltaic conversion chip 601 and the other end connected to the SETSD pin of the photovoltaic conversion chip 601, a resistor R5 having one end connected to the REF pin of the photovoltaic conversion chip 601 and the other end connected to the setsg pin of the photovoltaic conversion chip 601, a resistor R6 having one end connected to the REF pin of the photovoltaic conversion chip 601 and the other end connected to the TERM pin of the photovoltaic conversion chip 601, a resistor R7 having one end connected to the SETSD pin of the photovoltaic conversion chip 601 and the other end grounded, a resistor R8 having one end connected to the setsg pin of the photovoltaic conversion chip 601 and the other end grounded, and a resistor R9 having one end connected to the TERM pin of the photovoltaic conversion chip 601 and the other end grounded.

In this embodiment, the photovoltaic collection unit 4 is a micro photovoltaic panel, and when the photovoltaic collection area is increased as much as possible, the photovoltaic collection unit can be embedded in the bridge cavity 3 without shielding the sight.

In this embodiment, the rechargeable energy storage unit 8 is a rechargeable button-type lithium battery, which not only has high energy storage density, but also is convenient to install in the temple cavity 5 due to small size.

In this embodiment, the spectacle frame body 1, the spectacle beam wiring groove 2, the spectacle nose bridge cavity 3 and the spectacle leg cavity 5 are all made of titanium materials, and the titanium materials are light materials, so that the weight of the spectacles can be reduced to the maximum extent on the basis of mounting of each electronic component.

When the utility model is used, the bridge cavity 3 of the glasses nose is used for placing the photovoltaic acquisition unit 4, the leg cavity 5 of the glasses is used for placing the photovoltaic conversion module 6, the controller 7, the rechargeable energy storage unit 8 and the intelligent device 9, the bridge cavity 2 of the glasses nose and the leg cavity 5 of the glasses are skillfully arranged, and the cavity space of the bridge cavity 3 of the glasses nose and the leg cavity 5 is used for connecting and routing the photovoltaic acquisition unit 4, the photovoltaic conversion module 6, the controller 7, the rechargeable energy storage unit 8 and the intelligent device 9, the utility model fully utilizes the relatively large space of the bridge cavity 3 of the glasses nose and the leg cavity 5 of the glasses, places each electronic component therein, fully utilizes the long and narrow space of the bridge routing groove 2 of the glasses to realize the connection of each electronic component, the photovoltaic acquisition unit 4 converts solar energy into electric energy, and the photovoltaic conversion module 6 boosts and amplifies weak electric energy under the action of the controller 7, then the output power supply charges the chargeable energy storage unit 8, so that the electricity utilization requirement of the intelligent device 9 is guaranteed, the intelligent device cannot work normally due to the fact that the electric quantity of the battery is used up, and the defect that the endurance time is short due to the fact that the storage capacity of the battery is limited is overcome. In this embodiment, the connection between the photovoltaic collection unit 4, the photovoltaic conversion module 6, the controller 7, the rechargeable energy storage unit 8, and the intelligent device 9 belongs to the prior art, and can be realized through conventional design, and the specific circuit configuration thereof is not repeated in this embodiment.

The above embodiments are only preferred embodiments of the present invention, and are not intended to limit the scope of the present invention, but all changes that can be made by applying the principles of the present invention and performing non-inventive work on the basis of the principles shall fall within the scope of the present invention.

Claims (8)

1. The utility model provides a photovoltaic automatic acquisition power supply intelligence glasses which characterized in that: comprises a mirror frame body (1), a mirror beam wiring groove (2) connected with the upper edge of the mirror frame body (1), a mirror nose bridge cavity (3) arranged in the middle of the mirror frame body (1) and communicated with the inside of the mirror beam wiring groove (2), and a photovoltaic acquisition unit (4) embedded on the mirror nose bridge cavity (3), a glasses leg cavity (5) which is connected with the glasses frame body (1) and is communicated with the inside of the glasses beam wiring groove (2), and a photovoltaic conversion module (6), a controller (7), a rechargeable energy storage unit (8) and an intelligent device (9) which are arranged in the glasses leg cavity (5), wherein the photovoltaic acquisition unit (4) is connected with the photovoltaic conversion module (6), the photovoltaic conversion module (6) is respectively connected with the controller (7) and the rechargeable energy storage unit (8), the intelligent device (9) is respectively connected with the rechargeable energy storage unit (8) and the controller (7).

2. The photovoltaic automatic acquisition power supply smart glasses according to claim 1, characterized in that: the photovoltaic conversion module (6) comprises a photovoltaic conversion chip (601) with the model number of ADP5090, and a collection circuit (602), a wake-up circuit (603) and a bridge circuit (604) which are connected with the photovoltaic conversion chip (601), wherein the photovoltaic conversion chip (601) is connected with the rechargeable energy storage unit (8), the collection circuit (602) is connected with the photovoltaic collection unit (4), and the wake-up circuit (603) is connected with the controller (7).

3. The photovoltaic automatic acquisition power supply smart glasses according to claim 2, characterized in that: the acquisition circuit (602) comprises an inductor L1 with one end connected with the SW pin of the photovoltaic conversion chip (601) and the other end connected with the VIN pin of the photovoltaic conversion chip (601), a capacitor C1 with one end connected with the inductor L1 and the other end grounded, an interface J1 with one end connected with the capacitor C1 and the other end grounded, a resistor R1 with one end connected with the MPPT pin of the photovoltaic conversion chip (601) and the other end connected with the VIN pin of the photovoltaic conversion chip (601), and a resistor R2 with one end connected with the MPPT pin of the photovoltaic conversion chip (601) and the other end grounded, wherein the interface J1 is used for connecting the photovoltaic acquisition unit (4).

4. The photovoltaic automatic acquisition power supply smart glasses according to claim 2, characterized in that: the wake-UP circuit (603) comprises a battery B1 with one end connected with a BUCK _ UP pin of the photovoltaic conversion chip (601) and the other end connected with a MINOP pin of the photovoltaic conversion chip (601), and a resistor R3 with one end connected with the MINOP pin of the photovoltaic conversion chip (601) and the other end grounded, wherein a PGOOD pin and a DIS _ SW pin of the photovoltaic conversion chip (601) are used for connecting the controller (7).

5. The photovoltaic automatic acquisition power supply smart glasses according to claim 2, characterized in that: the bridge circuit (604) comprises a resistor R4 with one end connected with the REF pin of the photovoltaic conversion chip (601) and the other end connected with the SETSD pin of the photovoltaic conversion chip (601), a resistor R5 with one end connected with the REF pin of the photovoltaic conversion chip (601) and the other end connected with the SETPG pin of the photovoltaic conversion chip (601), a resistor R6 with one end connected with the REF pin of the photovoltaic conversion chip (601) and the other end connected with the TERM pin of the photovoltaic conversion chip (601), a resistor R7 with one end connected with the SETSD pin of the photovoltaic conversion chip (601) and the other end grounded, a resistor R8 with one end connected with the SETPG pin of the photovoltaic conversion chip (601) and the other end grounded, and a resistor R9 with one end connected with the TERM pin of the photovoltaic conversion chip (601) and the other end grounded.

6. The photovoltaic automatic acquisition power supply smart glasses according to claim 1, characterized in that: the photovoltaic acquisition unit (4) is a miniature photovoltaic panel.

7. The photovoltaic automatic acquisition power supply smart glasses according to claim 1, characterized in that: the rechargeable energy storage unit (8) is a rechargeable button type lithium battery.

8. The photovoltaic automatic acquisition power supply intelligent glasses according to any one of claims 1-7, wherein: the glasses frame body (1), the glasses beam wiring groove (2), the glasses nose bridge cavity (3) and the glasses leg cavity (5) are all made of titanium materials.

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