CN107996444B - Lens device capable of reflecting light after power failure and using method of lens device on artificial intelligent dog collar - Google Patents

Abstract

The utility model provides a lens device of back reflection of light of outage, includes four-pin full-color LED, transparent conducting film, transparent top layer, transparent emollient, the two triangular pyramids of half empty reflection magnetism, transparent pillar, transparent pearl separate, flat electro-magnet. The transparent lubricant is used for filling the upper layer of the reflecting material after power failure and is used for assisting the turning of the semi-hollow reflecting magnetic double triangular pyramid. The semi-hollow reflective magnetic double triangular pyramid consists of a solid triangular pyramid and a hollow triangular pyramid, wherein a magnetic sheet is clamped between the solid triangular pyramid and the hollow triangular pyramid; the solid triangular pyramid is heavier than the hollow triangular pyramid; the magnetic sheet S pole is a mirror surface and is connected with the hollow triangular pyramid; the N pole of the magnetic sheet is a matte surface and is connected with the solid triangular pyramid; when the semi-hollow reflective magnetic double triangular pyramid is normally placed in the transparent lubricant, the heavy side is below and the mirror surface of the S pole of the magnetic sheet is upward due to the action of gravity, so that the magnetic sheet has a light reflecting function; when the semi-hollow reflective magnetic double triangular pyramid is placed on the magnet, and the surface of the magnet close to the magnet is the N pole, the matte surface of the N pole of the magnetic sheet faces upwards, and the semi-hollow reflective magnetic double triangular pyramid does not have a light reflecting function.

Description

Lens device capable of reflecting light after power failure and using method of lens device on artificial intelligent dog collar

Technical Field

The invention relates to the technical field of lens devices, artificial intelligence, pet machines and blind person machines, in particular to a lens device capable of reflecting light after power failure and a using method of the lens device on an artificial intelligence dog collar.

Background

The Chinese patent 'an artificial intelligence cloud computing dog collar and a using method' provides a method for restraining a dog without a rope, so that the dog can only be provided with no traction rope in a public place, and when attacking a human, the human sends a password, and the dog only becomes to sit down.

However, if the dog collar is powered off in the artificial intelligence cloud computing, the indicating lamp does not indicate, people can hardly know whether the dog collar can restrain the dog, so that safety is evaluated, and fear is eliminated.

Therefore, there is a need for a material that will indicate when the artificial intelligence cloud computing dog collar is powered down.

Artificial intelligence technology based on deep learning is rapidly developed in the last year, and particularly, face recognition basically blooms all the time, and the face recognition rapidly falls on the ground in various fields such as finance, the internet, public safety, traffic and the like, so that the development is rapid.

However, applications of artificial intelligence are not powered off, and therefore, a material is needed to indicate when the artificial intelligence device is not powered.

Disclosure of Invention

The embodiment of the invention provides a lens device capable of reflecting light after power failure, and aims to solve the problem that an artificial intelligence cloud computing can give an indication when a dog collar is powered off.

One of the purposes of the invention is to enable the artificial intelligence cloud computing to give an indication when the collar of the dog is powered off.

It is another object of the present invention to enable an artificial intelligence device to indicate when it is not powered.

The invention achieves the above object through the following technical scheme.

The utility model provides a lens device of back reflection of light of outage, includes four full-color LED of foot, transparent conducting film, transparent top layer, transparent emollient, half empty reflection magnetic hexahedron, transparent pillar, transparent pearl separate and flat electro-magnet.

The four-pin full-color LED is used for emitting different lights.

The transparent conductive film is used for supplying power to the four-pin full-color LED.

The transparent surface layer is used for protecting the lens device which reflects light after power failure.

The transparent lubricant is used for filling the upper layer of the reflecting material after power failure and is used for assisting the turning of the semi-hollow reflecting magnetic hexahedron.

The semi-hollow reflective magnetic hexahedron consists of a solid triangular pyramid, a hollow triangular pyramid and a magnetic sheet sandwiched between the solid triangular pyramid and the hollow triangular pyramid; the solid triangular pyramid is heavier than the hollow triangular pyramid; the magnetic sheet S pole is a mirror surface and is connected with the hollow triangular pyramid; the N pole of the magnetic sheet is a matte surface and is connected with the solid triangular pyramid; when the semi-hollow reflective magnetic hexahedron is normally placed in the transparent lubricant, the heavy side is below and the mirror surface of the S pole of the magnetic sheet is upward due to the action of gravity, so that the semi-hollow reflective magnetic hexahedron has a light reflecting function; when the semi-hollow reflective magnetic hexahedron is placed on the magnet, and the side close to the magnet is the N pole, the hollow triangular pyramid is arranged below due to the magnetic force, the matte surface of the N pole of the magnetic sheet faces upwards, and the semi-hollow reflective magnetic hexahedron does not have the light reflecting function.

The transparent pillar is arranged between the transparent supporting surface layer and the flat electromagnet and used for supporting a space for placing a transparent lubricant, a semi-hollow reflective magnetic hexahedron and a transparent bead partition.

The transparent bead is used for fixing the position of the semi-hollow reflective magnetic hexahedron at intervals, so that the semi-hollow reflective magnetic hexahedron is turned over only at the original position.

The flat electromagnet is positioned on the electromagnetic layer and comprises an outer film and an electromagnet, two ends of the flat electromagnet are slightly longer than the transparent surface layer below the semi-hollow reflective magnetic hexahedron and are used for controlling the semi-hollow reflective magnetic hexahedron to turn over; when the hollow triangular pyramid is powered on, the N pole is arranged on the surface, close to the semi-hollow reflective magnetic hexahedron, of the flat electromagnet, due to the magnetic force action, the S pole of the magnetic sheet faces downwards, the hollow triangular pyramid is turned downwards, the matte surface of the N pole of the magnetic sheet faces upwards, and the reflective function is not achieved.

The magnetic sheet of the semi-hollow reflective magnetic hexahedron can also be connected with the hollow triangular pyramid by the N pole, and connected with the solid triangular pyramid by the S pole, and at the moment, the S pole is arranged on one side of the semi-hollow reflective magnetic hexahedron when the power is on.

The lens assembly, which reflects light after power failure, includes a power cord for powering the flat electromagnet.

The lens device capable of reflecting light after power failure can be added with back glue and back paper and used for adhering the light-reflecting material to a used object after power failure.

A method for using a lens device which reflects light after power failure in a dog collar comprises the following steps.

A. When a dog owner places a dog in a public place, the lens device which reflects light after power failure is pasted on the dog collar.

B. The transparent conductive film and the power supply line are connected to a dog collar power supply device.

C. The power line is electrified, and the lens device which reflects light after power failure does not reflect light. When the power supply is sufficient, the dog collar control device controls the four-pin full-color LED to emit green light through the transparent conductive film; when the power supply is only 30%, the dog collar control device controls the four-foot full-color LED to emit yellow light through the transparent conductive film; when the power supply is only 10%, the dog collar control device controls the four-foot full-color LED to emit red light through the transparent conductive film.

D. When the power supply is completely powered off, the four-pin full-color LED cannot emit light; when the power line is not electrified, the mirror surface of the S pole of the magnetic sheet of the semi-hollow reflective magnetic hexahedron faces upwards, and the lens device which reflects light after power failure reflects light because the surrounding dim light illuminates the mirror surface of the semi-hollow reflective magnetic hexahedron from all directions.

E. The dog owner finds that the neck ring of the dog is free of electricity, and immediately restrains the dog by adopting the traction rope.

F. Others see the light reflected from the collar of the dog, know that the dog is not restrained, keep away from the dog, take away the child to ensure safety, and find that the dog owner restrains the dog.

The method has the beneficial effects that: the artificial intelligence cloud computing can give an indication when the dog collar is powered off.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, 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 exercise.

FIG. 1: a lens device reflecting light after power failure.

FIG. 2: a method for using a lens device capable of reflecting light after power failure in an artificial intelligence cloud computing dog collar.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1 a lens device that reflects light after power is turned off.

As shown in fig. 1, a lens device reflecting light after power failure according to an embodiment of the present invention includes a four-pin full-color LED, a transparent conductive film, a transparent surface layer, a transparent lubricant, a semi-hollow reflective magnetic hexahedron, a transparent pillar, a transparent bead spacer, and a flat electromagnet.

The four-pin full-color LED is used for emitting different lights.

The transparent conductive film is used for supplying power to the four-pin full-color LED.

The transparent surface layer is used for protecting the reflecting material after power failure.

The transparent lubricant is used for filling the upper layer of the reflecting material after power failure and is used for assisting the turning of the semi-hollow reflecting magnetic hexahedron.

The semi-hollow reflective magnetic hexahedron consists of a solid triangular pyramid, a hollow triangular pyramid and a magnetic sheet sandwiched between the solid triangular pyramid and the hollow triangular pyramid; the solid triangular pyramid is heavier than the hollow triangular pyramid; the magnetic sheet S pole is a mirror surface and is connected with the hollow triangular pyramid; the N pole of the magnetic sheet is a matte surface and is connected with the solid triangular pyramid; when the semi-hollow reflective magnetic hexahedron is normally placed in the transparent lubricant, the heavy side is below and the mirror surface of the S pole of the magnetic sheet is upward due to the action of gravity, so that the semi-hollow reflective magnetic hexahedron has a light reflecting function; when the semi-hollow reflective magnetic hexahedron is placed on the magnet, and the side close to the magnet is the N pole, the hollow triangular pyramid is arranged below due to the magnetic force, the matte surface of the N pole of the magnetic sheet faces upwards, and the semi-hollow reflective magnetic hexahedron does not have the light reflecting function.

The transparent pillar is arranged between the transparent supporting surface layer and the flat electromagnet and used for supporting a space for placing a transparent lubricant, a semi-hollow reflective magnetic hexahedron and a transparent bead partition.

The transparent bead is used for fixing the position of the semi-hollow reflective magnetic hexahedron at intervals, so that the semi-hollow reflective magnetic hexahedron is turned over only at the original position.

The flat electromagnet is positioned on the electromagnetic layer and comprises an outer film and an electromagnet, two ends of the flat electromagnet are slightly longer than the transparent surface layer below the semi-hollow reflective magnetic hexahedron and are used for controlling the semi-hollow reflective magnetic hexahedron to turn over; when the hollow triangular pyramid is powered on, the N pole is arranged on the surface, close to the semi-hollow reflective magnetic hexahedron, of the flat electromagnet, due to the magnetic force action, the S pole of the magnetic sheet faces downwards, the hollow triangular pyramid is turned downwards, the matte surface of the N pole of the magnetic sheet faces upwards, and the reflective function is not achieved.

The magnetic sheet of the semi-hollow reflective magnetic hexahedron can also be connected with the hollow triangular pyramid by the N pole, and connected with the solid triangular pyramid by the S pole, and at the moment, the S pole is arranged on one side of the semi-hollow reflective magnetic hexahedron when the power is on.

The lens assembly, which reflects light after power failure, includes a power cord for powering the flat electromagnet.

The lens device capable of reflecting light after power failure can be added with back glue and back paper and used for adhering the light-reflecting material to a used object after power failure.

Embodiment 2 a method for using a lens device that reflects light after power failure in an artificial intelligence cloud computing dog collar.

As shown in FIG. 2, a method for using a lens device that reflects light after power is turned off in a dog collar according to an embodiment of the present invention includes the following steps.

A. When a dog owner places a dog in a public place, the lens device which reflects light after power failure is pasted on the dog collar.

B. The transparent conductive film and the power supply line are connected to a dog collar power supply device.

C. The power line is electrified, and the lens device which reflects light after power failure does not reflect light. When the power supply is sufficient, the dog collar control device controls the four-pin full-color LED to emit green light through the transparent conductive film; when the power supply is only 30%, the dog collar control device controls the four-foot full-color LED to emit yellow light through the transparent conductive film; when the power supply is only 10%, the dog collar control device controls the four-pin full-color LED to emit red light through the transparent conductive film; the power line is electrified, and the lens device which reflects light after power failure does not reflect light.

D. When the power supply is completely powered off, the four-pin full-color LED cannot emit light; when the power line is not electrified, the mirror surface of the S pole of the magnetic sheet of the semi-hollow reflective magnetic hexahedron faces upwards, and the lens device which reflects light after power failure reflects light because the surrounding dim light illuminates the mirror surface of the semi-hollow reflective magnetic hexahedron from all directions.

E. The dog owner finds that the neck ring of the dog is free of electricity, and immediately restrains the dog by adopting the traction rope.

F. Others see the light reflected from the collar of the dog, know that the dog is not restrained, keep away from the dog, take away the child to ensure safety, and find that the dog owner restrains the dog.

The principle and the implementation mode of the invention are explained by applying specific embodiments in the invention, and the description of the embodiments is only used for helping to understand the method and the core idea of the invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (5)

1. The utility model provides a lens device of outage back reflection of light which characterized in that: the LED comprises a four-pin full-color LED, a transparent conductive film, a transparent surface layer, a transparent lubricant, a semi-hollow reflective magnetic hexahedron, a transparent pillar, a transparent bead spacer and a flat electromagnet;

the four-pin full-color LED is used for emitting different lights;

the transparent conductive film is used for supplying power to the four-pin full-color LED;

the transparent surface layer is used for protecting the reflecting material after power failure;

the transparent lubricant is used for filling the upper layer of the reflecting material after power failure and is used for assisting the turning of the semi-hollow reflecting magnetic hexahedron;

the semi-hollow reflective magnetic hexahedron consists of a solid triangular pyramid, a hollow triangular pyramid and a magnetic sheet sandwiched between the solid triangular pyramid and the hollow triangular pyramid; the solid triangular pyramid is heavier than the hollow triangular pyramid; the magnetic sheet S pole is a mirror surface and is connected with the hollow triangular pyramid; the N pole of the magnetic sheet is a matte surface and is connected with the solid triangular pyramid; when the semi-hollow reflective magnetic hexahedron is normally placed in the transparent lubricant, the heavy side is below and the mirror surface of the S pole of the magnetic sheet is upward due to the action of gravity, so that the semi-hollow reflective magnetic hexahedron has a light reflecting function; when the semi-hollow reflective magnetic hexahedron is placed on the magnet, and the surface of the magnet close to the magnet is an N pole, the hollow triangular pyramid is arranged below the magnet due to the action of magnetic force, the matte surface of the N pole of the magnetic sheet is upwards, and the magnetic sheet does not have a light reflecting function;

the transparent pillar is arranged between the supporting transparent surface layer and the flat electromagnet and used for supporting a space for placing a transparent lubricant, a semi-hollow reflective magnetic hexahedron and a transparent bead;

the transparent bead is used for fixing the position of the semi-hollow reflective magnetic hexahedron, so that the semi-hollow reflective magnetic hexahedron is turned over only in situ;

the flat electromagnet is positioned on the electromagnetic layer and comprises an outer film and an electromagnet, two ends of the flat electromagnet are slightly longer than the transparent surface layer below the semi-hollow reflective magnetic hexahedron and are used for controlling the semi-hollow reflective magnetic hexahedron to turn over; when the hollow triangular pyramid is powered on, the N pole is arranged on the surface, close to the semi-hollow reflective magnetic hexahedron, of the flat electromagnet, due to the magnetic force action, the S pole of the magnetic sheet faces downwards, the hollow triangular pyramid is turned downwards, the matte surface of the N pole of the magnetic sheet faces upwards, and the reflective function is not achieved.

2. The lens apparatus of claim 1, wherein the semi-hollow reflective magnetic hexahedron has an N-pole connected to the hollow triangular pyramid and an S-pole connected to the solid triangular pyramid, and when the lens apparatus is powered on, the S-pole is formed on one side of the semi-hollow reflective magnetic hexahedron.

3. The device of claim 1, wherein the device includes a power cord for powering the flat electromagnet.

4. The lens device reflecting light after power failure as claimed in claim 1, wherein the lens device reflecting light after power failure is added with a back adhesive and a backing paper for adhering the reflecting material after power failure to the object to be used.

5. A method for using a lens device capable of reflecting light after power failure in an artificial intelligent dog collar is characterized by comprising the following steps:

A. when a dog owner places a dog in a public place, the lens device which reflects light after power failure is pasted on a dog collar;

B. connecting the transparent conductive film and the power line to a dog collar power supply device;

C. when the power line is electrified, the lens device which reflects light after power failure does not reflect light; when the power supply is sufficient, the dog collar control device controls the four-pin full-color LED to emit green light through the transparent conductive film; when the power supply is only 30%, the dog collar control device controls the four-foot full-color LED to emit yellow light through the transparent conductive film; when the power supply is only 10%, the dog collar control device controls the four-pin full-color LED to emit red light through the transparent conductive film;

D. when the power supply is completely powered off, the four-pin full-color LED cannot emit light; when the power line is not electrified, the mirror surface of the S pole of the magnetic sheet of the semi-hollow reflective magnetic hexahedron faces upwards, and the mirror surface of the semi-hollow reflective magnetic hexahedron is illuminated by the surrounding dim light from all directions, and the light is reflected by the lens device after the power is off;

E. the dog owner finds that the neck ring of the dog is free of electricity, and immediately restricts the dog by adopting a traction rope;

F. others see the light reflected from the collar of the dog, know that the dog is not restrained, keep away from the dog, take away the child to ensure safety, and find that the dog owner restrains the dog.

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