TWI500020B - Structure for controlling discoloration for electrochromic lens and method therefore - Google Patents

Description

Electrochromic lens control color changing structure and method

The invention relates to an electrochromic lens controlling color changing structure and method, in particular to increasing the input current conduction area and increasing the color conversion rate of the electrochromic region of the electrochromic lens, and in its overall application. An innovative designer of electrochromic lenses that control the color-changing structure and method.

According to the rapid development of science and technology, various special materials have been developed. Among them, electrochromic components refer to the application of a voltage to exhibit a reversible color change property, and the original transparent colorless state is turned into a colored state after being energized. The structure is a multi-layer electrochemical device that applies a voltage to the element, and causes a change in color due to a reversible reaction of oxidation or reduction of the substance in the element. The electrochromic element can be used in daily life. Among them, if the outside sun is too strong or wants to make the interior secret, this technology can be applied to change the glass transmittance.

In the operation and use of the electrochromic element, the electropositive element is provided with a symmetrical positive and negative power source on opposite sides or four sides of the electrochromic element, so as to input the electrochromic element. When the power is forward, the transmittance of the electrochromic element is lowered, the light absorption is increased, and the color is deeper. When a reverse power source is input to the electrochromic element, the transmittance of the electrochromic element is improved and the light absorption is improved. The reduction, the lighter the color, the reverse or positive power supply to the electrochromic element is reversed, and the electrochromic element is subjected to oxidation or reduction reaction, thereby achieving the purpose of adjusting the electrochromic element to the desired transmittance. .

However, the above electrochromic elements can utilize input forward or reverse The change of the power source achieves the expected effect of adjusting the transmittance, but it is also found in the actual practical use of the electrochromic element that the electrochromic element is symmetrical according to its corresponding side or four sides. The positive power supply and the negative power supply make it suitable for the structure of a relatively special design, such as a lens, because it cannot be provided with a positive power supply and a negative power supply on the four sides thereof. The rate of discoloration of the color changing element occurs, so that there is still room for improvement in overall operation.

The reason is that the inventor has been rich in design and development and practical production experience of the relevant industry for many years, researching and improving the existing structure and lack, providing an electrochromic lens to control the color-changing structure and method, in order to achieve better practical value. By.

The main object of the present invention is to provide an electrochromic lens control color changing structure and method, which are mainly used for the positive power source and the negative power terminal respectively disposed on both sides and the upper end of the electrochromic lens. When the power source is simultaneously input to the power source, the input current conduction area can be increased, and the color conversion rate of the electrochromic region of the electrochromic lens is increased, and the utility model is further enhanced in practical use.

The main purpose and effect of the electrochromic lens of the present invention for controlling the color changing structure are achieved by the following specific technical means: the electrochromic lens is mainly provided, and the positive power source is respectively disposed on both sides and the upper end of the electrochromic lens. The terminal and the negative power terminal respectively connect the positive power source and the negative power source to the positive power terminal and the negative power terminal of the matching polarity of the two sides and the upper end of the electrochromic lens, and the positive power terminal and the negative power terminal are electrically connected The electrochromic region of the color changing lens is connected to conduct.

A preferred embodiment of the electrochromic lens of the present invention controls a color changing structure, wherein the positive power terminal is disposed on one side of the electrochromic lens and extends to the upper end of the electrochromic lens, and the negative power terminal is disposed on the electro The other side of the color-changing lens is also extended to the upper end of the electrochromic lens.

A preferred embodiment of the electrochromic lens control color changing structure of the present invention, wherein the positive power terminal and the negative power terminal are respectively disposed on both sides of the electrochromic lens, and then disposed on both sides of the upper end of the electrochromic lens and electrochromic Positive power terminals and negative power terminals with opposite polarities on both sides of the lens.

Another purpose and effect of the electrochromic lens of the present invention for controlling the color changing structure is achieved by the following specific technical means: the electrochromic lens is mainly provided, and the two sides of the electrochromic lens are respectively provided with positive The power terminal and the negative power terminal respectively connect the positive power source and the negative power source to the positive power terminal and the negative power terminal of the matching polarity of the two sides and the lower end of the electrochromic lens, and the positive power terminal and the negative power terminal are electrically connected The electrochromic zone of the chromophoric lens is connected to conduct.

A preferred embodiment of the electrochromic lens of the present invention controls a color changing structure, wherein the positive power terminal is disposed on one side of the electrochromic lens and extends to the lower end of the electrochromic lens, and the negative power terminal is set to be electrically The other side of the color-changing lens is also extended to the upper end of the electrochromic lens.

The preferred embodiment of the electrochromic lens control color changing structure of the present invention, wherein the positive power terminal and the negative power terminal are respectively disposed on both sides of the electrochromic lens, and then disposed on both sides of the lower end of the electrochromic lens and electrochromic Positive power terminals and negative power terminals with opposite polarities on both sides of the lens.

A preferred embodiment of the electrochromic lens of the present invention controls a color changing structure, wherein the electrochromic lens is recessed upwardly at a position intermediate the lower edge thereof to form a nose portion, and the positive power terminal and the negative power terminal are disposed on the electrochromic The lower ends of the lenses extend to the bridge of the nose.

The main purpose and effect of the electrochromic lens control color changing method of the present invention are achieved by the following specific technical means: the main purpose is to connect the positive electrode power source and the negative electrode power source respectively to the matching polarity of the two sides and the upper end of the electrochromic lens. The positive power supply terminal and the negative power supply terminal are used to input power to the positive power supply terminal and the negative power supply terminal of the positive polarity power supply and the negative power supply at the same time, and the positive power supply terminal and the negative power supply terminal of the two sides of the electrochromic lens are matched, so that the power supply can be increased. The current conduction area is input to increase the color conversion rate of the electrochromic region of the electrochromic lens.

(1)‧‧‧Electrochromic lenses

(11)‧‧‧ positive power terminals

(12)‧‧‧Negative power terminals

(13)‧‧‧Electrochromic zone

(14)‧‧‧Nose bridge

(2) ‧‧‧ positive power supply

(3)‧‧‧Negative power supply

First Figure: Schematic diagram of the structure of the present invention

Second Figure: Schematic diagram of the first embodiment of the present invention

Third figure: schematic diagram of the state of use of the present invention

Fourth figure: schematic diagram of the state of use of the first embodiment of the present invention

Figure 5 is a schematic view showing the state of use of the second embodiment of the present invention

Figure 6 is a schematic view showing the state of use of the third embodiment of the present invention

Figure 7 is a schematic view showing the state of use of the fourth embodiment of the present invention

Figure 8 is a schematic view showing the state of use of the fifth embodiment of the present invention

For a more complete and clear disclosure of the technical content, the purpose of the invention and the effects thereof achieved by the present invention, the following is a detailed description, and please refer to the drawings and drawings: First, please refer to BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the structure of a first embodiment of the present invention. The present invention is mainly provided with an electrochromic lens (1) on both sides of the electrochromic lens (1). And the upper end or the lower end are respectively provided with a positive power terminal (11) and a negative power terminal (12), and the positive power terminal (11) and the negative power terminal (12) are electrically connected with the electrochromic lens (1). The discoloration area (13) is connected to conduct.

In this way, the present invention is used in operation, please refer to the third diagram of the present invention, and the fourth diagram of the first embodiment of the present invention, as shown in the schematic diagram of the state of use, the positive power supply (2) And the negative power source (3) is respectively connected to the positive power terminal (11) and the negative power terminal (12) of the matching polarity of the two sides of the electrochromic lens (1) and the upper or lower end to utilize the positive power source (2) And the negative power source (3) simultaneously inputs power to the positive power supply terminal (11) and the negative power supply terminal (12) of the opposite sides of the electrochromic lens (1) and the upper or lower end of the phase, in the electrochromic When the lens (1) is input to the forward power source, the The electrochromic region (13) of the electrochromic lens (1) will reduce the transmittance, increase the absorbance, and the darker the color, and when the reverse power source is input to the electrochromic lens (1), the electricity The electrochromic region (13) of the photochromic lens (1) will increase the transmittance, reduce the light absorption, and the lighter the color, so as to input the forward or reverse power to the electrochromic lens (1) by repeating the electricity. The photochromic lens (1) is subjected to an oxidation or reduction reaction to adjust the electrochromic lens (1) to a desired transmittance, and at the same time, since the present invention is connected to the positive and negative power sources (2), (3), respectively The positive and negative power terminals (11) and (12) of the electrochromic lens (1) on both sides and the upper or lower end of the matching polarity enable the input current conduction area to increase the color of the electrochromic region (13) The conversion rate is increased.

The positive power supply terminal (11) and the negative power supply terminal (12) respectively disposed on the two sides and the upper or lower end of the electrochromic lens (1) can be used to set the positive power terminal (11) to electrochromic. One side of the lens (1) extends to the upper or lower end of the electrochromic lens (1), and the negative power terminal (12) is disposed on the other side of the electrochromic lens (1), and is also electrically The upper end or the lower end of the color changing lens (1) is extended; or, please refer to the fifth embodiment of the second embodiment of the present invention, and the sixth embodiment is shown in the state of use of the third embodiment of the present invention. The power terminal (11) and the negative power terminal (12) are respectively disposed on both sides of the electrochromic lens (1), and are disposed on both sides of the upper end or the lower end of the electrochromic lens (1) and the electrochromic lens (1). The positive power terminal (11) and the negative power terminal (12) with opposite sides of the opposite phase.

In addition, referring to the seventh embodiment of the present invention, the electrochromic lens (1) of the present invention can be recessed upwardly at the middle position of the lower edge thereof to form a bridge portion (14). Please refer to the eighth embodiment of the present invention as shown in the fifth embodiment of the present invention. The positive power terminal (11) and the negative power terminal (12) can be disposed on both sides of the electrochromic lens (1). The lower end extends to the bridge of the nose (14) and can be applied to a variety of sports glasses, sunglasses, goggles, and snow mirrors.

By the above, the composition and use of the structure of the present invention are described It can be seen that, in comparison with the prior art, the present invention mainly utilizes a positive power supply terminal and a negative power supply terminal respectively disposed on both sides and upper or lower ends of the electrochromic lens, so that the positive power source and the negative power source are simultaneously When the input power source is input, the input current conduction area can be increased, the color conversion rate of the electrochromic region of the electrochromic lens is increased, and the utility model is further enhanced in practical use.

However, the above-described embodiments or drawings are not intended to limit the structure or the use of the present invention, and any suitable variations or modifications of the invention will be apparent to those skilled in the art.

In summary, the embodiments of the present invention can achieve the expected use efficiency, and the specific structure disclosed therein has not been seen in similar products, nor has it been disclosed before the application, and has completely complied with the provisions of the Patent Law. And the request, the application for the invention of a patent in accordance with the law, please forgive the review, and grant the patent, it is really sensible.

(1)‧‧‧Electrochromic lenses

(11)‧‧‧ positive power terminals

(12)‧‧‧Negative power terminals

(13)‧‧‧Electrochromic zone

(2) ‧‧‧ positive power supply

(3)‧‧‧Negative power supply

Claims (8)

An electrochromic lens control color changing structure is mainly provided with an electrochromic lens, and a positive power terminal and a negative power terminal are respectively disposed on two sides and an upper end of the electrochromic lens, and the positive power source and the negative power source are respectively connected to The positive power supply terminal and the negative power supply terminal of the electrochromic lens have matching polarity on both sides and the upper end, and the positive power supply terminal and the negative power supply terminal are connected to the electrochromic region of the electrochromic lens. The electrochromic lens control color changing structure according to claim 1, wherein the positive power terminal is disposed on one side of the electrochromic lens, and extends to the upper end of the electrochromic lens, and the negative power terminal is disposed at The other side of the electrochromic lens is also extended to the upper end of the electrochromic lens. The electrochromic lens control color changing structure according to claim 1, wherein the positive power terminal and the negative power terminal are respectively disposed on two sides of the electrochromic lens, and then the two sides of the upper end of the electrochromic lens are electrically connected. A positive power terminal and a negative power terminal of different polarity on both sides of the photochromic lens. An electrochromic lens controls a color changing structure, which is mainly provided with an electrochromic lens, and a positive power terminal and a negative power terminal are respectively disposed at two sides and a lower end of the electrochromic lens, and the positive power source and the negative power source are respectively connected to The positive power supply terminal and the negative power supply terminal of the opposite sides of the electrochromic lens are matched with the polarity, and the positive power supply terminal and the negative power supply terminal are connected to the electrochromic region of the electrochromic lens. The electrochromic lens control color changing structure according to claim 4, wherein the positive power terminal is disposed on one side of the electrochromic lens, and extends to the lower end of the electrochromic lens, and the negative power terminal is disposed at The other side of the electrochromic lens is also extended to the lower end of the electrochromic lens. The electrochromic lens controls the color change knot as described in claim 4 The positive power terminal and the negative power terminal are respectively disposed on two sides of the electrochromic lens, and the positive power terminal and the negative power source having different polarities from the two sides of the electrochromic lens are disposed on both sides of the lower end of the electrochromic lens. Terminal. The electrochromic lens control color changing structure according to claim 4, 5 or 6, wherein the electrochromic lens is recessed upwardly at a position intermediate the lower edge thereof to form a nose portion, the positive power terminal and the negative power terminal. The lower ends of the electrochromic lenses are arranged to extend to the bridge of the nose. An electrochromic lens control color changing method, which mainly connects a positive power source and a negative power source to a positive power terminal and a negative power terminal of a matching polarity of the two sides and the upper end of the electrochromic lens, so as to utilize a positive power source and a negative power source. At the same time, the positive power supply terminal and the negative power supply terminal of the opposite sides of the electrochromic lens are input with a power source, so that the input current conduction area can be increased, and the color conversion rate of the electrochromic region of the electrochromic lens is increased. .