Abstract: A method of making a curved electrochromic film includes: disposing a UV curable adhesive layer between a first electrochromic member and a second electrochromic member to form an electrochromic film semi-product in flat form; arching the electrochromic film semi-product between the first and second bending members of a forming apparatus and by moving the first and second bending members toward each other; and curing the UV curable adhesive layer using a UV light source while the electrochromic film semi-product is arched. Forming apparatuses for forming a flat electrochromic film semi-product into a curved electrochromic film are also disclosed.

Abstract: An electrochromic device includes a housing, an electrochromic structure, and a cover. The housing defines a receiving space therein and has an opening. The electrochromic structure is disposed in the receiving space, and has a central region and a peripheral region. The electrochromic structure includes an upper substrate, a lower substrate, an upper electrode, a lower electrode, and an electrochromic laminate sandwiched between the upper the lower electrodes. The cover includes a protecting plate covering the opening, and a shielding member disposed between the peripheral region of the electrochromic structure and the protecting plate and covering the peripheral region.

Abstract: An electrochromic device includes upper and lower substrate units, and an electrochromic laminate sandwiched between an upper electrode of the upper substrate unit and a lower electrode of the lower substrate unit. The electrochromic laminate includes en ion storage layer formed on the upper electrode, an active layer formed on the lower electrode, and a polymer electrolyte sandwiched between inner surfaces of the ion storage layer and the active layer. At least one of the inner surfaces has a roughened peripheral region such that an adhesion force generated between the roughened peripheral region and the polymer electrolyte is effective to minimize thermal shrinkage of the polymer electrolyte.

Abstract: A method for control of electrochromic devices is revealed. First a duty cycle of PWM is changed to a preset Q value according to a signal detected by a detector while the electrochromic device is switched to the colored state. The Q value represents electric charge that corresponds to colored-state transmittance. Then turn off the PWM. Thus the response time for coloration and the transmittance of the electrochromic device are maintained within a preset range, without being affected by ambient temperature, setting time and aging of the materials used. Thus the electrochromic device is more convenient to use and having more practical value.

Abstract: A control circuit and a method for maintaining light transmittance of an electrochromic device are revealed. An input power source is turned off once a current input into an electrochromic device is decreased to a preset value. Then a voltage between two electrodes of the electrochromic device is detected. When the voltage between two electrodes of the electrochromic device is dropped to a preset value, the input power source is restored. According to the above steps, the coloration of the electrochromic device is maintained within a preset range. Thus light transmittance of the electrochromic device is kept at a certain range.