CN102879919A - Sun glasses - Google Patents

Abstract

The invention discloses a pair of sunglasses, which are applied in the technical field of glasses. A light intensity detector is used to detect changes in the intensity of external light, and then a microprocessor calculates the result of detecting changes in the intensity of external light by the light intensity detector. The ratio of the time when the left liquid crystal lens and the right liquid crystal lens are turned on for passing light to the time when they are turned off for not passing light is the duty cycle. At the same time, a corresponding voltage is provided or no voltage is provided to the left liquid crystal lens and the right liquid crystal. The lens controls the left and right liquid crystal lenses to be turned on or off at the same time. When the calculated duty ratio increases, the light transmittance of the left and right liquid crystal lenses is high, and the light transmittance of the sunglasses is high. On the contrary, it is low, so that the light transmittance of the sunglasses will change with the change of the external light intensity, and the light transmittance of the sunglasses will be adaptively adjusted according to the change of the external light intensity, so as to meet the needs of the human eye for different external light. Sensory requirements.

Description

Sunglasses

technical field

The invention relates to the technical field of glasses, in particular to a pair of sunglasses.

Background technique

Sunglasses, also known as sunshade glasses, people usually rely on adjusting the pupil size to adjust the luminous flux in the sun. When the external light intensity exceeds the adjustment ability of the human eye, it will cause damage to the human eye, so in outdoor activities, especially in summer People generally use sunglasses to block the sun to reduce the fatigue caused by eye adjustment or the damage caused by strong light stimulation.

The sunshade function of sunglasses is all reflected on the lens, but the light transmittance of the lens of the existing sun glasses is fixed, resulting in the light transmittance of the existing sun glasses is fixed, that is, the light transmittance will not change with the outside world. The light intensity changes, and it is impossible to adjust the light transmittance adaptively according to the change of the external light intensity, and it cannot meet the sensory requirements of the human eye for different external light.

Contents of the invention

The technical problem to be solved by the present invention is to provide a kind of sunglasses.

The object of the present invention is to provide a kind of sunglasses, comprising: a light intensity detector, a microprocessor, a voltage provider, a left liquid crystal lens, a right liquid crystal lens, and a spectacle frame;

The light intensity detector is arranged on the spectacle frame and is used to detect changes in the intensity of external light;

The microprocessor is arranged on the spectacle frame and is connected with the light intensity detector and the voltage provider, and is used to calculate the change of the external light intensity according to the detection result of the light intensity detector. Obtain the duty ratio that makes described left liquid crystal mirror, described right liquid crystal mirror switch, calculate and make described left liquid crystal mirror, described right liquid crystal mirror open for the time that transmits light and close for the time that does not pass through. The ratio of the time of passing light;

The voltage provider is arranged on the spectacle frame and is connected with the microprocessor, the left liquid crystal lens, and the right liquid crystal lens, and is used for the calculation according to the microprocessor. The duty cycle, while providing a voltage of a corresponding magnitude or at the same time no voltage is provided to the left liquid crystal lens and the right liquid crystal lens to control the left liquid crystal lens and the right liquid crystal lens to be turned on or off at the same time;

The left liquid crystal lens is arranged on the spectacle frame;

The right liquid crystal lens is arranged on the spectacle frame.

The left liquid crystal lens includes:

Starting from the object side, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, and the second conductive layer of the left liquid crystal lens are arranged in sequence;

The right liquid crystal lens includes:

Starting from the object side, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, and the second conductive layer of the right liquid crystal lens are arranged in sequence.

The left liquid crystal lens includes:

Starting from the object side, the polarizing plate of the left liquid crystal lens, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, and the second conductive layer of the left liquid crystal lens are arranged in sequence;

The right liquid crystal lens includes:

Starting from the object side, the polarizing plate of the right liquid crystal lens, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, and the second conductive layer of the right liquid crystal lens are arranged in sequence;

The polarizing direction of the polarizing plate of the left liquid crystal lens is parallel to the polarizing direction of the polarizing plate of the right liquid crystal lens.

The left liquid crystal lens includes:

Starting from the object side, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, the second conductive layer of the left liquid crystal lens, and the polarizing plate of the left liquid crystal lens are arranged in sequence;

The right liquid crystal lens includes:

Starting from the object side, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, the second conductive layer of the right liquid crystal lens, and the polarizing plate of the right liquid crystal lens are arranged in sequence;

The polarizing direction of the polarizing plate of the left liquid crystal lens is parallel to the polarizing direction of the polarizing plate of the right liquid crystal lens.

The left liquid crystal lens includes:

Starting from the object side, the first polarizing plate of the left liquid crystal lens, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, the second conductive layer of the left liquid crystal lens, and the second polarizing plate of the left liquid crystal lens are arranged in sequence;

The right liquid crystal lens includes:

Starting from the object side, the first polarizing plate of the right liquid crystal lens, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, the second conductive layer of the right liquid crystal lens, and the second polarizing plate of the right liquid crystal lens are arranged in sequence;

The polarity direction of the first polarizer of the left liquid crystal lens is parallel to the polarity direction of the first polarizer of the right liquid crystal lens;

The polarity direction of the second polarizer of the left liquid crystal lens is parallel to the polarity direction of the second polarizer of the right liquid crystal lens.

The first conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The first conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The liquid crystal layer of the left liquid crystal lens includes: a twisted nematic TN type liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a twisted nematic TN type liquid crystal layer; or

The liquid crystal layer of the left liquid crystal lens includes: a super twisted nematic STN type liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a super twisted nematic STN type liquid crystal layer.

The sun glasses of the present invention use a light intensity detector to detect the change of the external light intensity, and then the microprocessor detects the detection result of the change of the external light intensity according to the light intensity detector, and calculates the ratio of the left liquid crystal lens and the right liquid crystal lens to switch. Duty ratio, that is, calculate the ratio of the time when the left liquid crystal lens and the right liquid crystal lens are turned on for passing light to the time when they are turned off for not passing light, and then the voltage provider calculates the Duty cycle, provide the corresponding voltage or no voltage to the left liquid crystal lens and right liquid crystal lens at the same time, control the left liquid crystal lens and the right liquid crystal lens to open or close at the same time, when the calculated duty cycle increases, The light transmittance of the left liquid crystal lens and the right liquid crystal lens is high, and the light transmittance of the sunglasses is high, and vice versa, so that the light transmittance of the sun glasses will change with the change of the external light intensity, and the sun glasses will Adaptively adjust the light transmittance according to the change of the external light intensity to meet the sensory requirements of the human eye for different external light.

Description of drawings

Fig. 1 is the schematic diagram of the embodiment of sunglasses of the present invention;

Fig. 2 is a schematic diagram of the overall structure of the sunglasses of the present invention.

Detailed ways

The invention provides a kind of sun glasses, which are applied in the technical field of glasses. The sun glasses of the invention use a light intensity detector to detect the change of the external light intensity, and then the microprocessor detects the detection result of the change of the external light intensity according to the light intensity detector, and calculates Obtain the duty cycle that makes the left liquid crystal lens and the right liquid crystal lens switch, that is, calculate the time that the left liquid crystal lens and the right liquid crystal lens are turned on for passing light and closed for not passing light. The ratio of time, and then the voltage provider provides a corresponding voltage or no voltage to the left liquid crystal lens and the right liquid crystal lens at the same time according to the calculated duty cycle, and controls the left liquid crystal lens and the right liquid crystal lens to be turned on or off at the same time , when the calculated duty ratio increases, the light transmittance of the left liquid crystal lens and the right liquid crystal lens is high, the light transmittance of the sunglasses is high, and vice versa, so that the light transmittance of the sun glasses will be lower. With the change of the external light intensity, the realization of sunglasses will adaptively adjust the light transmittance according to the change of the external light intensity, so as to meet the sensory requirements of the human eye for different external light.

The invention provides a kind of sun glasses.

Please refer to Fig. 1, which is a schematic diagram of an embodiment of the sunglasses of the present invention, and in conjunction with Fig. 2, Fig. 2 is a schematic diagram of the overall structure of the sunglasses of the present invention, the sunglasses 100 include: a light intensity detector 101, a microprocessor 102, a voltage Provider 103, left liquid crystal lens 104, right liquid crystal lens 105, spectacle frame 106;

The light intensity detector 101 is arranged on the spectacle frame 106 and is used to detect changes in the intensity of external light;

The microprocessor 102 is arranged on the spectacle frame 106, and is connected with the light intensity detector 101 and the voltage provider 103, and is used to calculate the left liquid crystal according to the detection result of the light intensity detector 101 detecting the change of the external light intensity. The duty cycle of the switching of the lens 104 and the right liquid crystal lens 105 is to calculate the ratio between the time when the left liquid crystal lens 104 and the right liquid crystal lens 105 are turned on for passing light and the time when they are turned off for not passing light;

The voltage provider 103 is arranged on the spectacle frame 106 and is connected with the microprocessor 102, the left liquid crystal lens 104 and the right liquid crystal lens 105, and is used to make the left liquid crystal lens 104 and the right liquid crystal lens 104 calculated according to the microprocessor 102. Mirror 105 carries out the duty ratio of switch, provides the voltage of corresponding magnitude simultaneously to left liquid crystal mirror 104, right liquid crystal mirror 105, or does not provide voltage simultaneously to left liquid crystal mirror 104, right liquid crystal mirror 105, controls left liquid crystal mirror 104, right liquid crystal mirror The mirrors 105 are opened or closed simultaneously;

The left liquid crystal lens 104 is arranged on the spectacle frame 106;

The right liquid crystal lens 105 is arranged on the spectacle frame 106 .

Wherein, the structures of the left liquid crystal lens 104 and the right liquid crystal lens 105 include:

1. The left liquid crystal lens 104, including:

Starting from the object side, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, and the second conductive layer of the left liquid crystal lens are arranged in sequence;

Right liquid crystal lens 105, comprises:

Starting from the object side, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, and the second conductive layer of the right liquid crystal lens are arranged in sequence;

The liquid crystal layer of the left liquid crystal lens includes: a twisted nematic (TN) liquid crystal layer, a super twisted nematic (STN) liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a twisted nematic TN type liquid crystal layer, a super twisted nematic STN type liquid crystal layer;

The first conductive layer of the left liquid crystal lens includes: indium tin oxide (ITO) conductive glass;

The second conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The first conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

Two, the left liquid crystal lens 104, including:

Starting from the object side, the polarizing plate of the left liquid crystal lens, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, and the second conductive layer of the left liquid crystal lens are arranged in sequence;

Right liquid crystal lens 105, comprises:

Starting from the object side, the polarizing plate of the right liquid crystal lens, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, and the second conductive layer of the right liquid crystal lens are arranged in sequence;

The polarity direction of the polarizing plate of the left liquid crystal lens is parallel to the polarizing direction of the polarizing plate of the right liquid crystal lens;

The liquid crystal layer of the left liquid crystal lens includes: twisted nematic TN type liquid crystal layer, super twisted nematic STN type liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a twisted nematic TN type liquid crystal layer, a super twisted nematic STN type liquid crystal layer;

The first conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The first conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

Three, the left liquid crystal lens 104, including:

Starting from the object side, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, the second conductive layer of the left liquid crystal lens, and the polarizing plate of the left liquid crystal lens are arranged in sequence;

Right liquid crystal lens 105, comprises:

Starting from the object side, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, the second conductive layer of the right liquid crystal lens, and the polarizing plate of the right liquid crystal lens are arranged in sequence;

The polarity direction of the polarizing plate of the left liquid crystal lens is parallel to the polarizing direction of the polarizing plate of the right liquid crystal lens;

The liquid crystal layer of the left liquid crystal lens includes: twisted nematic TN type liquid crystal layer, super twisted nematic STN type liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a twisted nematic TN type liquid crystal layer, a super twisted nematic STN type liquid crystal layer;

The first conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The first conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

Four, left liquid crystal eyeglass 104, comprise:

Starting from the object side, the first polarizing plate of the left liquid crystal lens, the first conductive layer of the left liquid crystal lens, the liquid crystal layer of the left liquid crystal lens, the second conductive layer of the left liquid crystal lens, and the second polarizing plate of the left liquid crystal lens are arranged in sequence;

Right liquid crystal lens 105, comprises:

Starting from the object side, the first polarizing plate of the right liquid crystal lens, the first conductive layer of the right liquid crystal lens, the liquid crystal layer of the right liquid crystal lens, the second conductive layer of the right liquid crystal lens, and the second polarizing plate of the right liquid crystal lens are arranged in sequence;

The polarity direction of the first polarizer of the left liquid crystal lens is parallel to the polarity direction of the first polarizer of the right liquid crystal lens;

The polarity direction of the second polarizer of the left liquid crystal lens is parallel to the polarity direction of the second polarizer of the right liquid crystal lens;

The liquid crystal layer of the left liquid crystal lens includes: twisted nematic TN type liquid crystal layer, super twisted nematic STN type liquid crystal layer;

The liquid crystal layer of the right liquid crystal lens includes: a twisted nematic TN type liquid crystal layer, a super twisted nematic STN type liquid crystal layer;

The first conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the left liquid crystal lens includes: indium tin oxide ITO conductive glass;

The first conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass;

The second conductive layer of the right liquid crystal lens includes: indium tin oxide ITO conductive glass.

The embodiment of the sun glasses of the present invention uses the light intensity detector 101 to detect changes in the intensity of external light, and then the microprocessor 102 calculates the left liquid crystal lens 104, the right The liquid crystal lens 105 carries out the switching duty cycle, then the voltage provider 103 according to the duty cycle of the left liquid crystal lens 104 and the right liquid crystal lens 105 calculated by the microprocessor 102, provides a voltage of corresponding magnitude to the left Liquid crystal lens 104, right liquid crystal lens 105, or do not provide voltage to left liquid crystal lens 104, right liquid crystal lens 105 at the same time, control left liquid crystal lens 104, right liquid crystal lens 105 to open or close at the same time, calculated by microprocessor 102 When the duty cycle of the switch of the left liquid crystal lens 104 and the right liquid crystal lens 105 is increased, the light transmittance of the left liquid crystal lens 104 and the right liquid crystal lens 105 is high, and the light transmittance of the sunglasses is high; 104. The light transmittance of the right liquid crystal lens 105 is low, and the light transmittance of the sunglasses is low, so as to realize that the light transmittance of the sunglasses will change with the change of the intensity of the external light, and realize that the transmittance of the sunglasses will change according to the intensity of the external light. The change adaptively adjusts the light transmittance to meet the sensory requirements of the human eye for different external light.

For the sunglasses of the present invention, the forms of realization are varied. Any modifications, equivalent replacements, improvements, etc. made within the spirit and principles of the present invention shall be included within the protection scope of the present invention.

Claims (6)

1. sunglasses is characterized in that, comprising: light intensity detector, microprocessor, voltage provide device, left liquid crystal lens, right liquid crystal lens, frame;

Described light intensity detector is arranged on the described frame, for detection of the variation of ambient light line strength;

Described microprocessor, be arranged on the described frame, provide device to be connected with described light intensity detector, described voltage, be used for detecting according to described light intensity detector the testing result of the variation of ambient light line strength, calculate the dutycycle that the described left liquid crystal lens of sening as an envoy to, described right liquid crystal lens carry out switch, calculate the described left liquid crystal lens of sening as an envoy to, described right liquid crystal lens and open the time that is used for transmitted light and close for the ratio of the time of transmitted light not;

Described voltage provides device, be arranged on the described frame, be connected with described microprocessor, described left liquid crystal lens, described right liquid crystal lens, for the described dutycycle that calculates according to described microprocessor, the voltage of corresponding size is provided simultaneously or does not simultaneously provide voltage to described left liquid crystal lens, described right liquid crystal lens, control described left liquid crystal lens, described right liquid crystal lens is opened simultaneously or closed;

Described left liquid crystal lens is arranged on the described frame;

Described right liquid crystal lens is arranged on the described frame.

2. sunglasses as claimed in claim 1 is characterized in that, described left liquid crystal lens comprises:

Risen by the thing side, be arranged in order left liquid crystal lens first conductive layer of setting, left liquid crystal lens liquid crystal layer, left liquid crystal lens the second conductive layer;

Described right liquid crystal lens comprises:

Risen by the thing side, be arranged in order right liquid crystal lens first conductive layer of setting, right liquid crystal lens liquid crystal layer, right liquid crystal lens the second conductive layer.

3. sunglasses as claimed in claim 1 is characterized in that, described left liquid crystal lens comprises:

Risen by the thing side, be arranged in order the left liquid crystal lens Polarizer of setting, left liquid crystal lens the first conductive layer, left liquid crystal lens liquid crystal layer, left liquid crystal lens the second conductive layer;

Described right liquid crystal lens comprises:

Risen by the thing side, be arranged in order the right liquid crystal lens Polarizer of setting, right liquid crystal lens the first conductive layer, right liquid crystal lens liquid crystal layer, right liquid crystal lens the second conductive layer;

The polar orientation of described left liquid crystal lens Polarizer parallels with the polar orientation of described right liquid crystal lens Polarizer.

4. sunglasses as claimed in claim 1 is characterized in that, described left liquid crystal lens comprises:

Risen by the thing side, be arranged in order left liquid crystal lens first conductive layer of setting, left liquid crystal lens liquid crystal layer, left liquid crystal lens the second conductive layer, left liquid crystal lens Polarizer;

Described right liquid crystal lens comprises:

Risen by the thing side, be arranged in order right liquid crystal lens first conductive layer of setting, right liquid crystal lens liquid crystal layer, right liquid crystal lens the second conductive layer, right liquid crystal lens Polarizer;

The polar orientation of described left liquid crystal lens Polarizer parallels with the polar orientation of described right liquid crystal lens Polarizer.

5. sunglasses as claimed in claim 1 is characterized in that, described left liquid crystal lens comprises:

Risen by the thing side, be arranged in order left liquid crystal lens first Polarizer of setting, left liquid crystal lens the first conductive layer, left liquid crystal lens liquid crystal layer, left liquid crystal lens the second conductive layer, left liquid crystal lens the second Polarizer;

Described right liquid crystal lens comprises:

Risen by the thing side, be arranged in order right liquid crystal lens first Polarizer of setting, right liquid crystal lens the first conductive layer, right liquid crystal lens liquid crystal layer, right liquid crystal lens the second conductive layer, right liquid crystal lens the second Polarizer;

The polar orientation of described left liquid crystal lens the first Polarizer parallels with the polar orientation of described right liquid crystal lens the first Polarizer;

The polar orientation of described left liquid crystal lens the second Polarizer parallels with the polar orientation of described right liquid crystal lens the second Polarizer.

6. such as claim 2 or 3 or 4 or 5 described sunglasses, it is characterized in that, described left liquid crystal lens the first conductive layer comprises: tin indium oxide ITO electro-conductive glass;

Described left liquid crystal lens the second conductive layer comprises: tin indium oxide ITO electro-conductive glass;

Described right liquid crystal lens the first conductive layer comprises: tin indium oxide ITO electro-conductive glass;

Described right liquid crystal lens the second conductive layer comprises: tin indium oxide ITO electro-conductive glass;

Described left liquid crystal lens liquid crystal layer comprises: twisted-nematic TN type liquid crystal layer;

Described right liquid crystal lens liquid crystal layer comprises: twisted-nematic TN type liquid crystal layer; Or

Described left liquid crystal lens liquid crystal layer comprises: super twisted nematic STN type liquid crystal layer;

Described right liquid crystal lens liquid crystal layer comprises: super twisted nematic STN type liquid crystal layer.

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