KR101294896B1 - System for window tinting - Google Patents

Abstract

The window tinting system detects a glare incident to the front at a predetermined threshold angle by a glass assembly filled with a discolored layer having a changed color density by a power supply, a power supply unit for supplying power to the discolored layer, and a predetermined threshold angle. The light sensor for generating a sensing signal, and when receiving the sensing signal from the light sensor, in response to the sensing signal to adjust the amount of power supply of the power supply, and transmits the adjusted power to the color change layer of the color fading layer And a control unit for changing the color density. Window tinting system can automatically block the light that is difficult to secure the driver's vision, and can solve the difficulty of securing the view by the light.

Description

System for window tinting

The present invention relates to a window tinting system, and more particularly, to a window tinting system capable of automatically adjusting the transmittance of a window.

Window tinting is to block the sunlight entering through the windows of a vehicle or building and to increase the insulation effect. In general, window tinting is processed by attaching a tinting film having a certain concentration to the window. In particular, the window tinting of the vehicle is widely used to block the sunlight to secure the driver's field of view, reduce the amount of ultraviolet rays introduced into the vehicle, and make the inside of the vehicle not easily visible from the outside.

Generally, window tinting is performed by attaching a certain concentration of tinting film to the left and right side glass and rear glass of the vehicle. The current car tinting law stipulates that visible light transmittance of windshields of passenger windshields and vans should be 70% or more and 40% of visible light transmission of both sides of driver's seats. Therefore, it is practically impossible to attach a tinting film to the front glass of the vehicle. The windshield of the currently produced vehicle is only about the UV shielding within the regulation of the vehicle tinting law.

Most of the cases where the driver has difficulty in visibility while driving, the direct sunlight or strong reflected light of the sun is reflected directly in the driver's eyes. When direct sunlight or strong reflected light from the sun shines directly into the driver's eyes, the driver may experience reduced vision and discomfort due to a light source that is much brighter than the luminance the eye is adapted to. Direct or reflected light from a light source that is much brighter than the luminance at which the driver's eyes are adapted is called glare.

Since the tinting film is not attached to the windshield of the vehicle, the driver's seat and the passenger seat of the vehicle are equipped with a sun shade to block the light entering through the windshield. In general, when the driver is exposed to light while driving, the driver directly lowers the sun shade to block the light and returns the sun shade to its original position when the light disappears. The driver's direct adjustment of the sunshade while driving is not only a detrimental factor for safe driving, but also the difficulty of securing the vision by the bright light remains because the bright light that is suddenly reflected on the driver's eyes still remains.

The technical problem to be solved by the present invention is to provide a window tinting system that can automatically block the light to secure the driver's field of view.

Window tinting system according to an embodiment of the present invention is a glass assembly filled with a discoloration layer that changes the color density by the power supply, a power supply for supplying power to the discoloration layer, incident to the front at a predetermined threshold angle or less A light sensor for detecting a glare and generating a sensing signal, and when receiving the sensing signal from the light sensor, adjusts a power supply of the power supply unit in response to the sensing signal and discolors the adjusted power. And a control unit for transferring the layer to change the color density of the color fading layer.

The light sensor may include a sensing unit for detecting the light, and a guard to block the light incident at an angle higher than the predetermined critical angle from being incident on the sensing unit.

The guard includes a first guard that covers the upper side of the sensing unit and the front end of the first guard to form a critical angle with the sensing unit, and the bright sensor adjusts the position of the end of the first guard to adjust the threshold angle. It may further include.

The guard may include a first guard covering the upper side of the sensing unit and including a convex surface of the front convex shape, and the bright sensor may further include a sensor driver moving the sensing unit in the front direction.

The controller may include a signal comparator configured to calculate a differential value by comparing the level of the sensing signal with a reference level corresponding to a minimum luminance, and adjust an amount of power supplied from the power supply to the color change layer in response to the differential value. It may include a current control unit.

The controller may further include a signal generator configured to generate a first control signal for driving the sensor driver.

The signal generator may generate a second control signal for changing a reference level of the signal comparator.

Window tinting system can automatically block the light that is difficult to secure the driver's vision, and can solve the difficulty of securing the view by the light.

1 is a block diagram schematically illustrating a window tinting system according to an embodiment of the present invention.
2 is a front view showing the front of the light sensor according to an embodiment of the present invention.
3 is a cross-sectional view showing the configuration of a light sensor according to an embodiment of the present invention.
4 is a cross-sectional view showing the configuration of a light sensor according to another embodiment of the present invention.
5 is a block diagram illustrating a control unit according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In addition, in the various embodiments, components having the same configuration are represented by the same reference symbols in the first embodiment. In the other embodiments, only components different from those in the first embodiment will be described .

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a block diagram schematically illustrating a window tinting system according to an embodiment of the present invention.

Referring to FIG. 1, the window tinting system includes a glass assembly 10, a power supply unit 20, a controller 30, and a light sensor 40.

The glass assembly 10 has a structure in which the discoloration layer 12 whose color density is changed by the power supply is filled between the transparent glass panels 11. The color change layer 12 may be composed of a liquid electrochromic material. Electrochromic materials include well known inorganic electrochromic materials such as WO ₃ , NiO x Hy, Nb ₂ O ₅ , V ₂ O ₅ , TiO ₂ , MoO ₃ and organic electrochromic materials such as polyaniline. The inorganic / organic electrochromic material may be dissolved in an organic solvent to prepare a liquid electrochromic material.

The discoloration layer 12 may be filled over a portion of the glass aggregate 10. Although the discoloration layer 12 is shown to be filled for a part of the area of the glass assembly 10, the discoloration layer 12 may be configured to fill the entire area of the glass assembly 10. For example, the glass aggregate 10 filled with the discoloration layer 12 for the entire area may be used as the side glass of the vehicle, and the glass aggregate 10 filled with the discoloration layer 12 for the partial area may be used for the vehicle. Can be used as the windshield of the. That is, the discoloration layer 12 is filled in the upper portion of the windshield of the vehicle, the color density of the upper portion of the windshield is changed by the power supply to weaken or block the light that obstructs the driver's view, and the driver discolors the discoloration layer. A bright field of view can be secured through the lower portion of the windshield (12) not filled. On the other hand, the glass assembly 10 may be made of a separate glass plate that can be attached to the interior of the vehicle, such as the sun shade of the vehicle.

The power supply 20 enters between the glass panels 11 of the glass assembly 10 and applies power to the electrode rods 21 directly contacting the color change layer 12. In order to prevent the outflow of the electrochromic material through the electrode rod 21 entering between the glass panels 11, it is preferable that the glass aggregate 10 is properly sealed. As the power supply unit 20 applies power to the electrode 21, power may flow to the color change layer 12 through the electrode 21.

When power is not applied to the electrode rod 21 from the power supply 20, the glass assembly 10 may maintain a transparent state. When a predetermined power is applied from the power supply unit 20 to the electrode rod 21, a color change having a predetermined concentration occurs in the color fading layer 12 in proportion to the power supply amount (for example, the current amount). The color density of the color change layer 12 becomes darker, so that the power supply amount is large.

The controller 30 adjusts the amount of power supplied from the power supply unit 20 to the color change layer 12 in response to the sensing signal received from the light sensor 40, and transmits the adjusted power to the color change layer 12. The color density of the color change layer 12 can be changed. The controller 30 may adjust the light measurement range of the light sensor 40 by adjusting the critical angle of the light sensor 40.

The bright sensor 40 generates a sensing signal by detecting a glare incident to the front at a predetermined threshold angle or less. The bright light refers to the light directly incident on the driver's eyes as the direct light or reflected light of the light source much brighter than the luminance of the driver's eyes. The bright light sensor 40 may detect light having a brightness level higher than a predetermined reference level, and generate a high level sensing signal as the light intensity increases.

The bright light sensor 40 may be configured to adjust a critical angle capable of detecting bright light. For example, the angle of incidence of light incident directly to the driver's eye through the windshield or side glass of the vehicle depends on the driver's sitting height or driving position. That is, the critical angle of the bright sensor 40 may be adjusted to correspond to the incident angle of light directly incident to the driver's eye through the windshield or side glass of the vehicle. Accordingly, the window tinting system detects the light at the time when the light is incident on the driver's eyes and applies the power to the color change layer 12 to weaken or block the light.

Now, the light sensor 40 for detecting the light incident upon the predetermined threshold angle will be described in more detail.

2 is a front view showing the front of the light sensor according to an embodiment of the present invention. 3 is a cross-sectional view showing the configuration of a light sensor according to an embodiment of the present invention. 3 is a cross-sectional view taken along line AA ′ of FIG. 2 to explain the configuration and operation of the light sensor.

2 and 3, the light sensor 40 includes a sensing unit 41 for detecting the light and a guard for blocking the light incident at an angle higher than the predetermined critical angle θ from being incident on the sensing unit 41. (43).

The sensing unit 41 generates an electrical signal or an optical signal in response to the intensity of the incident light, and transmits the electrical signal or the optical signal to the controller 30. The sensing unit 41 may generate an electrical signal having a high voltage or a large amount of current as the intensity of incident light increases. Alternatively, the sensing unit 41 may change and output the intensity, frequency, etc. of the optical signal as the intensity of incident light increases. For example, a photo diode, which is a device that generates current or electromotive voltage according to the intensity of incident light, may be used as the sensing unit 41.

The guard 43 includes a first guard 43a covering the upper side of the sensing unit 41, and a second guard 43b covering the left and right sides and the lower side of the sensing unit 41. That is, the guard 43 may be configured to surround the sensing unit 41 so as to detect the light incident on the front of the light sensor 40 at a predetermined threshold angle θ or less.

The first guard 43a may be configured such that the end n forms a critical angle θ with the sensing unit 41 at the front of the incident light. As the end n of the first guard 43a forms a critical angle θ with the sensing unit 41, the light beam L1 incident at an incident angle greater than the critical angle θ is blocked and an incident angle smaller than the critical angle θ Light rays L2 incident to each other may reach the sensing unit 41.

The bright light sensor 40 may further include a sensor driver 44 that adjusts the position of the end n of the first guard 43a. The sensor driver 44 may move the first guard 43a up and down according to the first control signal of the controller 30, and thus the position of the end n of the first guard 43a may be adjusted. have. As the position of the end n of the first guard 43a is adjusted, the critical angle θ formed between the sensing unit 41 and the end n of the first guard 43a may be adjusted.

The driver adjusts the position of the end n of the first guard 43a of the light sensor 40 according to his / her sitting height or driving posture, whereby the color density of the color change layer 12 of the glass assembly 10 is changed. You can adjust the viewpoint. For example, a driver driving in a position close to a steering wheel with a small sitting height may adjust the critical angle θ of the light sensor 40 to be large so as to correspond to the light having a relatively large incident angle. 12) can be made darker. In addition, the driver driving in a posture with a large sitting height or a distance away from the steering wheel adjusts the critical angle θ of the light sensor 40 to be small so as to correspond to the light having a relatively small incident angle. The color density can be made darker.

On the other hand, the angle formed by the second guard 43b with the sensing unit 41 may be determined in consideration of the angle of the light beam that can be incident to the driver's eyes from the left and right sides through the glass assembly 10. For example, in the vehicle in which the glass assembly 10 is used as the windshield of the vehicle and the driver's seat is provided on the left side, the left side of the second guard 43b is formed at a relatively small angle with the sensing unit 41 and the second guard ( The right side of 43b may be configured at a relatively large angle with the sensing unit 41. Herein, the configuration in which the critical angle θ of the first guard 43a is adjusted is described, but the left and right sides of the second guard 43b are sensed in the same manner as the configuration in which the critical angle θ of the first guard 43a is adjusted. Angle formed with the portion 41 can be adjusted.

4 is a cross-sectional view showing the configuration of a light sensor according to another embodiment of the present invention.

Referring to FIG. 4, the light sensor 140 may include a sensing unit 141 that detects light, a guard 143 that blocks light incident at an angle higher than a predetermined critical angle from entering the sensing unit 141, and The sensor driver 144 moves the sensing unit 141 in the front direction.

The sensing unit 141 generates an electrical signal or an optical signal in response to the intensity of the incident light, and transmits the electrical signal or the optical signal to the controller 30. The sensing unit 141 may generate an electrical signal having a high voltage or a large amount of current as the intensity of incident light increases. Alternatively, the sensing unit 141 may change and output the intensity, frequency, etc. of the optical signal as the intensity of incident light increases. For example, a photodiode, which is a device that generates current or electromotive voltage according to the intensity of incident light, may be used as the sensing unit 141.

The guard 143 includes a first guard 143a covering the upper side of the sensing unit 141, and a second guard 143b covering the left and right sides and the lower side of the sensing unit 141. That is, the guard 143 may be configured to surround the sensing unit 141 to detect the light incident to the front of the light sensor 140 at a predetermined threshold angle or less.

The first guard 143a includes a convex surface c of the front convex shape in which the bright light is incident.

The sensor driver 144 may linearly move the sensing unit 141 in the front direction in which the bright light is incident according to the first control signal of the controller 30. To this end, a driving pin 142 facing the front direction may be attached to one side of the sensing unit 141, and the sensor driving unit 144 moves the sensing unit 141 in the front direction by linearly moving the driving pin 142. Can be moved linearly. The linear movement of the sensing unit 141 may be employed in various configurations, and the proposed invention is not limited thereto.

The convex surface c is formed on the first guard 143a, and the sensor driver 144 linearly moves the sensing unit 141 in the front direction so that the critical angle at which the sensing unit 141 can detect the bright light is increased. Can be adjusted. For example, when the sensing unit 141 is located at the first point a, the sensing unit 141 is incident by a convex surface c of the first guard 143a at an angle lower than θ1. L3) can be detected. That is, when the sensing unit 141 is located at the first point a, the critical angle of the light sensor 140 is θ1. When the sensing unit 141 is located at the second point b, the sensing unit 141 receives the light beam L4 incident at an angle lower than θ2 by the convex surface c of the first guard 143a. Can be detected. That is, when the sensing unit 141 is located at the second point b, the critical angle of the light sensor 140 is θ2.

The driver may adjust the timing at which the color density of the color change layer 12 of the glass assembly 10 is changed by adjusting the position of the sensing unit 141 of the light sensor 140 according to his / her sitting height or driving posture. For example, a driver driving in a position close to a steering wheel having a small sitting height may move the sensing unit 141 in the front direction to greatly adjust the critical angle of the light sensor 140 and correspond to the light of a relatively large incident angle. The color density of the discoloration layer 12 of the glass aggregate 10 can be increased. In addition, a driver who sits tall or sits away from the steering wheel may adjust the critical angle of the light sensor 140 by reversing the sensing unit 141 in the front direction, and respond to the light of a relatively small incident angle. The color density of the discoloration layer 12 of (10) can be made thick.

Now, the controller 30 that adjusts the amount of power supplied from the power supply 20 to the color change layer 12 and adjusts the critical angles of the light sensors 40 and 140 will be described in more detail.

5 is a block diagram illustrating a control unit according to an embodiment of the present invention.

Referring to FIG. 5, the controller 30 includes a user interface 31, a signal generator 32, a signal processor 33, a signal comparator 34, and a current controller 35.

The user interface unit 31 includes display means for displaying the transmittance or concentration level of the glass aggregate 10 to the user, and / or input means for the user to input a command. The user may check the transmittance or concentration level of the glass assembly 10 through the user interface 31. The user may control the driving of the sensor drivers 44 and 144 and the change in concentration of the color change layer 12 through the user interface 31.

The signal generator 32 generates a first control signal for driving the sensor drivers 44 and 144 and a second control signal for controlling a change in concentration of the color change layer 12. That is, the signal generator 32 may generate a first control signal or a second control signal according to a user command input through the user interface unit 31.

The signal processor 33 is connected to the sensor drivers 44 and 144, and converts the first control signal into an analog signal and transmits the first control signal to the sensor drivers 44 and 144. The sensor driver 44 of FIG. 3 may adjust the position of the end of the first guard 43a according to the first control signal. The sensor driver 144 of FIG. 4 may adjust the position of the sensing unit 141 according to the first control signal.

The signal comparison unit 34 calculates a differential value by comparing the level of the sensing signal transmitted from the sensing units 41 and 141 with a reference level. The reference level corresponds to the level of the sensing signal transmitted from the sensing units 41 and 141 when the lowest luminance when the driver starts to feel the bright light is incident on the sensing units 41 and 141. That is, when the lowest luminance is incident on the sensing units 41 and 141, the level of the sensing signal transmitted from the sensing units 41 and 141 and the reference level are the same, and thus the differential value is calculated as zero. When light stronger than the lowest luminance is incident on the sensing units 41 and 141, the level of the sensing signal transmitted from the sensing units 41 and 141 may be higher than the reference level and the differential value may be calculated as a positive value. The signal comparator 34 transmits a difference value between the level of the sensing signal and the reference level to the current controller 35.

The current controller 35 adjusts the amount of power supplied from the power supply 20 to the color change layer 12 in response to the difference between the level of the sensing signal and the reference level. That is, the current controller 35 may increase the amount of power supplied to the discoloration layer 12 as the magnitude of the differential value transmitted from the signal comparator 34 increases.

The reference level of the signal comparator 34 may be changed by the second control signal. The signal generator 32 generates a second control signal for setting a reference level of the signal comparator 34 according to a user command input through the user interface 31, and transmits the second control signal to the signal comparator 34. The signal comparator 34 changes the reference level according to the second control signal. When the reference level is changed, the differential value calculated by the signal comparator 34 for the bright light of the same brightness is also changed, and the amount of power supply transmitted to the color change layer 12 by the current adjuster 35 is also changed. That is, by changing the reference level of the signal comparator 34 with the second control signal, it is possible to control the change in concentration of the color fading layer 12.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are illustrative and explanatory only and are intended to be illustrative of the invention and are not to be construed as limiting the scope of the invention as defined by the appended claims. It is not. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10 glass aggregate 33 signal processing unit
11: glass panel 34: signal comparison unit
12: discoloration layer 35: current control unit
20: power supply unit 40, 140: light sensor
21: electrode 41, 141: sensing unit
30: control unit 43, 143: guard
31: user interface 44, 144: sensor drive unit
32: signal generator

Claims (7)

A glass aggregate filled with a discoloration layer whose color density is changed by a power supply;
A power supply unit supplying power to the color change layer;
A sensing unit for detecting a glare incident to the front at a predetermined threshold angle or less to generate a sensing signal, a guard for blocking light incident at an angle higher than the predetermined critical angle from entering the sensing unit, and a guard A bright light sensor including a sensor driver to move and adjust the predetermined critical angle; And
A signal comparator configured to calculate a differential value by comparing the level of the sensing signal with a reference level corresponding to a minimum luminance, a current adjuster configured to adjust a power supply amount supplied from the power supply to the color fading layer in response to the differential value; And a control unit including a signal generation unit configured to generate a first control signal for driving the sensor driver and a second control signal for changing the reference level. delete The method according to claim 1,
The guard includes a first guard that covers the upper side of the sensing portion and the front end of the sensing portion forms a critical angle with the sensing unit,
And the sensor driver adjusts the position of the end of the first guard to adjust the threshold angle. A glass aggregate filled with a discoloration layer whose color density is changed by a power supply;
A power supply unit supplying power to the color change layer;
A light sensor which detects a glare incident to the front at a predetermined threshold angle or less and generates a sensing signal; And
And a controller configured to adjust the power supply of the power supply unit in response to the sensing signal and to change the color density of the color fading layer by transferring the adjusted power to the color changing layer when the sensing signal is received from the bright sensor. ,
The light sensor,
A sensing unit detecting the light;
A guard covering an upper side of the sensing unit and including a convex surface convex toward the front, and blocking a light incident at an angle higher than the predetermined critical angle from being incident on the sensing unit; And
And a sensor driver to move the sensing part to adjust the predetermined critical angle. 5. The method of claim 4,
The control unit,
A signal comparison unit configured to calculate a differential value by comparing the level of the sensing signal with a reference level corresponding to minimum luminance; And
And a current controller configured to adjust a power supply amount transferred from the power supply unit to the color change layer in response to the differential value. 6. The method of claim 5,
The control unit,
And a signal generator configured to generate a first control signal for driving the sensor driver. The method of claim 6,
And the signal generator generates a second control signal for changing a reference level of the signal comparator.

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