KR200250349Y1 - Sunglass having function of light transmission control - Google Patents

Abstract

The present invention is to provide a sunglass that allows the wearer to arbitrarily adjust the light transmittance by using the physical properties of the liquid crystal (Liquid Crystal) that the light transmittance is changed by the twist angle is changed according to the applied voltage. Sunglasses with adjustable light transmittance of the present invention are adjacent to the upper polarizing plate, the upper polarizing plate, the upper substrate coated with the upper transparent electrode, the upper substrate disposed at predetermined intervals, and the lower substrate coated with the lower transparent electrode, the lower substrate adjacent to the lower substrate. An optical unit including a lower polarizing plate having a polarization direction perpendicular to the upper polarizing plate, and a liquid crystal filled between the upper substrate and the lower substrate; A driving unit generating a driving voltage whose polarity is reversed with time, and applying the same between the upper transparent electrode and the lower transparent electrode; A voltage adjusting unit including a switching mode power supply and supplying an adjusting voltage having a predetermined size to the driving unit to adjust the driving voltage; A control unit which receives a light transmittance adjustment signal from the outside and provides a switching signal for controlling the magnitude of an output voltage of the voltage adjuster according to the light transmittance adjustment signal to the voltage adjuster; And a battery, the voltage adjusting unit and a power supply unit supplying power to the controller.

Description

Sunglasses with adjustable light transmittance {SUNGLASS HAVING FUNCTION OF LIGHT TRANSMISSION CONTROL}

The present invention relates to a sunglass with adjustable light transmittance, and more particularly, to allow the wearer to arbitrarily adjust the light transmittance by using the physical property of the liquid crystal, in which the light transmittance is changed by the twist angle depending on the applied voltage. It is to provide sunglasses.

Liquid crystal is a material having both liquidity and solid crystallinity, and has a characteristic that the molecular arrangement of the liquid crystal is changed along the direction of the electric field when a voltage is applied. Such liquid crystals are widely used in display devices such as liquid crystal displays (LCDs). A liquid crystal widely used in a general display device is a liquid crystal of twisted nematic (TN) mode. The liquid crystal display includes two polarizing plates having polarization directions perpendicular to each other, disposed between the polarizing plates, and two transparent substrates coated with a transparent electrode made of indium tin oxide (ITO) or the like, and a liquid crystal injected between the transparent substrates. . Here, when no voltage is applied between the two transparent electrodes, the polarized light incident through one polarizer passes through the liquid crystal, and the polarization direction thereof is switched by 90 degrees to exit through the other polarizer. It will transmit most of the light. In addition, when a voltage is applied between the transparent electrodes, the molecular arrangement of the liquid crystal changes according to the magnitude of the applied voltage, and thus the polarization direction of the light passing through the liquid crystal is different from the above case. Part of the light that can pass through is limited, resulting in a low light transmittance.

Sunglass is a device for protecting eyes by limiting excessive light incidence. Various kinds of sunglass have been developed and widely used, and applied in various forms such as industrial goggles, leisure goggles, motorcycle helmets, etc. It is becoming. The term 'sunglass' in the following is to collectively refer to the above mechanisms for protecting the eyes by limiting the excessive amount of light.

The prior art sunglass is generally coated on the front or a part of a thin film having a limited light transmittance on a lens made of a material such as glass, it is impossible to arbitrarily control the light transmittance, and when driving through the tunnel or outdoors and indoors If you go back, you have to take off your sunglasses and wear them again. In order to alleviate this inconvenience, a lens that chemically implements a function of automatically changing the color according to the amount of light is used, but there is a problem that it is impossible when the user needs to arbitrarily adjust the transmittance as needed. There is a limit in that it takes several seconds to adjust the transmittance according to the amount of light, and thus, many applications including industrial applications are restricted.

The present invention is to solve the above problems, as described above to allow the wearer to arbitrarily adjust the light transmittance by using the physical properties of the liquid crystal (Liquid Crystal) that changes the light transmittance by changing the twist angle according to the applied voltage To provide sunglasses.

Figure 1 shows one preferred embodiment of the sunglass capable of adjusting the light transmittance of the present invention.

2 shows an example of the configuration of the optical portion.

3 shows an example of a driving voltage and a change in transmittance according to the driving voltage.

4 shows an example of the circuit configuration of the voltage adjusting section.

5 shows modifications of various circuit configurations of the driving section in FIGS. 5A, 5B and 5C, respectively.

<Explanation of symbols for the main parts of the drawings>

10: optical unit 20: driving unit

30: voltage adjusting unit 40: control unit

50: power supply 60: switch

In order to achieve the above object, the sunglass which can adjust the light transmittance according to one feature of the present invention, the upper polarizing plate, the upper substrate adjacent to the upper polarizing plate and coated with the transparent electrode, arranged at a predetermined distance from the upper substrate An optical unit including a lower substrate coated with a lower transparent electrode, a lower polarizer adjacent to the lower substrate and having a polarization direction perpendicular to the upper polarizer, and a liquid crystal filled between the upper and lower substrates; A driving unit generating a driving voltage whose polarity is reversed with time, and applying the same between the upper transparent electrode and the lower transparent electrode; A voltage adjusting unit including a switching mode power supply and supplying an adjusting voltage having a predetermined magnitude to the driving unit to adjust the driving voltage; A control unit which receives an optical transmittance adjustment signal from the outside and provides a switching signal to the voltage adjuster for controlling the magnitude of an output voltage of the voltage adjuster according to the optical transmittance adjustment signal; And a battery, the voltage adjusting unit and a power supply unit supplying power to the control unit.

Preferably, the optical unit of the sunglass that can adjust the light transmittance of the present invention, a color filter for passing a light of a predetermined color; Sunscreens; And a lens.

Preferably, the drive unit of the sunglass which can adjust the light transmittance according to the present invention, the oscillation circuit outputting the drive voltage of the square wave having the adjustment voltage as an input, the voltage level close to the adjustment voltage and a predetermined frequency predetermined It includes.

Preferably, the voltage adjusting unit of the sun glasses that can adjust the light transmittance of the present invention, the inductor connected to the power supply; A three-terminal switching element having a current input terminal connected to the inductor, and a control terminal connected to the control unit and turned on and off according to a switching signal input to the control terminal; And a diode having a current input terminal connected to a common terminal of the inductor and the switching element, and a current output terminal connected to the driving unit.

Preferably, the control unit of the sun glasses capable of adjusting the light transmittance of the present invention, the input means for generating a light transmittance adjustment signal by the adjustment from the outside; And a microprocessor unit configured to generate the switching signal according to the light transmittance adjustment signal.

Preferably, the light transmittance adjustable sunglass of the present invention further comprises a switch for shutting off the power supply of the battery, wherein the control unit, the signal for automatically switching off the power after a predetermined time to the switch Supply.

Hereinafter, with reference to the drawings will be described a preferred embodiment according to the present invention in detail.

Figure 1 shows one preferred embodiment of the sunglass that can adjust the light transmittance of the present invention.

The sunglass of the embodiment includes the optical unit 10, the driving unit 20, the voltage adjusting unit 30, the control unit 40 and the power supply unit 50. Here, the optical portion 10 is a portion for receiving incident light and transmitting a portion thereof, and an example of a detailed configuration thereof is shown in FIG. As shown in FIG. 2, the optical unit 10 is adjacent to the upper polarizing plate 14-1 and the upper polarizing plate 14-1 through which polarized light in a predetermined direction passes and coated with the upper transparent electrode 16-1. The substrate is disposed at a predetermined distance from the upper substrate 15-1 and the upper substrate 15-1, and is adjacent to the lower substrate 15-2 and the lower substrate 15-2 coated with the lower transparent electrode 16-2. And a lower polarizing plate 14-2 having a polarization direction perpendicular to the upper polarizing plate 14-1, and a liquid crystal 17 filled between the upper substrate 15-1 and the lower substrate 15-2. . The liquid crystal has a torsion angle depending on the voltage applied between the upper transparent electrode 16-1 and the lower transparent electrode 16-2, and the voltage applied between the two electrodes according to the optical anisotropy of the liquid crystal described above. By this, it is possible to control the intensity of light passing through the upper polarizing plate 14-1 and the lower polarizing plate 14-2. In addition, in some cases, the optical unit 10 may correct the color filter 12 for passing light of a predetermined color, the UV blocking film 13 for limiting the transmission of ultraviolet rays, and visual acuity as shown in FIG. 2. Or may further include a lens 11 for preventing breakage or security.

The driving unit 20 is a portion for applying a driving voltage between the upper transparent electrode 14-1 and the lower transparent electrode 14-2 constituting the above optical unit. An example of the driving voltage is shown in FIG. . As shown in the lowermost graph of FIG. 3, the light transmittance varies according to the magnitude of the driving voltage. When the driving voltage is changed between the threshold voltage Vth and the saturation voltage Vs, the light transmittance is inversely proportional to the magnitude of the driving voltage. Will have 3 illustrates two cases in which the magnitude of the driving voltage is V1 and V2. The waveform may have the form of a square wave as shown in FIG. 3, where one period of the driving voltage is represented by T _osc , which is an inverse of the driving frequency f _osc .

The driving unit 20 may be configured in various ways, and FIG. 5 shows examples of various driving units 20. 5A illustrates an example in which the driver 20 is implemented as an oscillation circuit using two bipolar transistors Q1 and Q2. In this case, a square wave whose magnitude varies according to the magnitude of the adjustment voltage can be obtained as the driving voltage, and the driving frequency is obtained as f _osc = 1 / (0.7 (R ₂ C ₁ + R ₃ C ₂ )). In addition, FIG. 5B illustrates an example in which the driving unit 20 is implemented using a general ring oscillator. Here the driving frequency is approximated by f _osc = 0.45 / (R _T C _T ). 5C illustrates an example in which the driver 20 is implemented as an oscillation circuit using an OP amplifier. In this case, the driving frequency is expressed as f _osc = 1 / (2πR ₁ C ₁ ). Many other modifications may be made, but it is obvious to those skilled in the art that the circuit modifications thereof do not mean to depart from the technical spirit of the present invention.

4 shows an example of the voltage adjusting unit 30. The voltage adjusting unit 30 receives a switching signal from the control unit 40 above, and is a part for changing the voltage supplied from the power supply unit 50 to supply the driving unit 20, and switching mode power supply as shown in FIG. 4. Mode Power Supply (SMPS). Various modifications such as a general boost circuit, a buck circuit, and a sepic circuit are possible, and the operation of each specific circuit of the example of FIG. 4 is already well known, and thus description thereof will be omitted. By employing the switching mode power supply as described above it is possible to maximize the battery life by minimizing the power consumption of the battery.

In addition, the control unit 40 may include an input unit for generating a light transmittance adjustment signal by adjustment from the outside, and a microprocessor unit for generating a switching signal according to the light transmittance adjustment signal and transmitting it to the driving unit 20. . Here, the input means may be implemented as an external input means such as a variable resistor or a button adjustable by the wearer, and may be modified in combination with another device such as an external portable terminal to receive its output. In addition, the control unit 40 may include a timer circuit to generate a signal for automatically shutting off the battery after a predetermined time elapses, in which case the power supply unit 50 and the voltage adjusting unit 30 above. In addition, a switch 60 as shown in FIG. 1 is additionally required, and may be configured to operate by receiving a power cutoff signal from the controller.

Sunglasses capable of adjusting the light transmittance according to the present invention can be modified and applied in various forms within the scope of the technical idea of the present invention and are not limited to the above preferred embodiment. In addition, whether the sunglass with adjustable light transmittance of the present invention is constructed integrally or separated from each other in several parts is not an important factor in determining whether it is outside the scope of the technical idea of the present invention. This is obvious and will be seen as a mere variation of the present invention.

In addition, the embodiments and drawings are merely for the purpose of describing the contents of the subject matter in detail, not intended to limit the scope of the technical idea of the subject matter, the present subject matter described above is common knowledge in the technical field to which the present invention belongs. It is not limited to the embodiments and the accompanying drawings, so that various substitutions, modifications, and changes within the scope without departing from the spirit of the present invention for those having, of course, not only the claims below but also the claims And should be judged to include equality.

According to the sunglass that can adjust the light transmittance according to the present invention, unlike the prior art, the wearer can provide a sunglass or goggles having a function to arbitrarily adjust the light transmittance, and can be used in various fields such as driving, leisure and industrial Application is possible.

The light transmittance adjustable sunglass of the present invention can implement a low-power portable sunglass system by adopting a switching mode power supply, and can be configured to have the use of glasses and sunglass by integrating with an ultraviolet blocking film and a lens. A wide range of applications is possible.

Claims (6)

Sunglasses to protect the eyes by limiting the incidence of excessive light, An upper polarizing plate, an upper substrate adjacent to the upper polarizing plate and coated with an upper transparent electrode, a lower substrate disposed at a predetermined distance from the upper substrate, and coated with a lower transparent electrode, and a polarization perpendicular to the upper polarizing plate and adjacent to the lower polarizing plate An optical unit including a lower polarizing plate having a direction, and a liquid crystal filled between the upper substrate and the lower substrate; A driving unit generating a driving voltage whose polarity is reversed with time, and applying the same between the upper transparent electrode and the lower transparent electrode; A voltage adjusting unit including a switching mode power supply and supplying an adjusting voltage having a predetermined magnitude to the driving unit to adjust the driving voltage; A control unit which receives an optical transmittance adjustment signal from the outside and provides a switching signal to the voltage adjuster for controlling the magnitude of an output voltage of the voltage adjuster according to the optical transmittance adjustment signal; And Sunglasses including a battery, the light transmittance is adjustable including a voltage adjusting unit and a power supply for supplying power to the control unit. The method of claim 1, The optical unit A color filter passing light of a predetermined color; Sunscreens; Sunglasses with adjustable light transmittance further comprising a lens. The method of claim 1, The driving unit And an oscillation circuit having the adjustment voltage as an input, the oscillating circuit outputting a driving voltage of a square wave having a voltage level close to the adjustment voltage and a predetermined frequency. The method of claim 1, The voltage adjusting unit An inductor connected to the power supply unit; A three-terminal switching element having a current input terminal connected to the inductor, and a control terminal connected to the control unit and turned on and off according to a switching signal input to the control terminal; And And a current input terminal connected to a common terminal of the inductor and the switching device, and a current output terminal connected to the driving unit. The method of claim 1, The control unit Input means for generating a light transmittance adjustment signal by adjustment from the outside; And a microprocessor unit configured to generate the switching signal according to the light transmittance adjustment signal. The method of claim 1, The light transmittance adjustable sunglasses Further comprising a switch for shutting off the power supply of the battery, The control unit Sunglasses capable of adjusting the light transmittance for supplying a signal for automatically shutting off the power after a predetermined time to the switch.