NL1010089C1 - Rearview mirror for road vehicle has automatic anti-dazzle mechanism uses Electro-chromic coating which reduces reflective capability when current is passed through it - Google Patents

Abstract

The mirror can be installed in place of a conventional mirror. It has sensors which detect the intensity of incoming light from ahead (A) and behind (B). The sensor outputs are fed to a microprocessor circuit (D). If a potential dazzle situation is detected, a variable current (E) is passed through the electrochromic coating on the mirror, darkening the reflection.

Description

Device for controlling the amount of light reflected from a surface, provided with a mounting frame, applicable, for example, as an anti-glare rear-view mirror which can be mounted on an existing mirror and which can be mounted on an existing mirror.

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The invention relates to a device for controlling the amount of light reflected by a surface, provided with a frame for mounting, consisting of a number of photosensitive elements, a housing, an element with variable and adjustable optical properties, and an electronic control unit for its control 10, whether or not with the possibility of manually setting one or more threshold values and / or optical parameters. Such a device can, for example, be used as an anti-glare rear view mirror, which can be mounted on an existing mirror.

Anti-glare car rear view mirrors and systems are known, in which the reflection level of the mirror (s) is automatically controlled as a function of the intensity of the light coming from behind and the amount of ambient light. In doing so, use is made of photosensitive elements which measure the relevant light intensities, and of electronic circuits, which convert signals from these photosensitive elements into electrical signals, and of "electrochromic" elements, the optical properties of which vary as a function of imposed electrical signals.

The technology and various applications have been described, among others, by Niall R. Lynam in "Electrochromic mirrors and windows". A few dozen patents describe anti-glare mirrors and systems (eg EP0769419, EP0729864, EP728618, EP0711683, EP0725305, EP0693397, EP0614784, EP0571098, EP0568210, EP0496155, EP0492591, EP0470866, EP047031465, EP047081465, EP0470865, EP0470865, EP047031465, EP047031465, EP0470365, EP0470365, EP0470365, EP0470365, EP0470365, EP0470365, EP0470365, EP0470865, EP0470365, 9417443, WO8503136), electronic circuits for controlling them (eg EP0280278, EP0490658, EP0405699, EP0426503, EP0677427, EP0705734, EP0638835, EP0285724, EP0286401, EP0253686, EP0151212, EP015948898, EP015204898 EP0552012 and EP0448260).

Automatic anti-glare car rear view mirrors are usually built in by the car manufacturer during the production of the vehicle. Also available on the market are accessory electrochromic mirrors that must be installed by the user in the vehicle 1010089 2 to replace all or a major part of the interior mirror, which is experienced as a relatively large and irreversible intervention.

The electrochromic elements used react slowly to changes in the electric control signal, while in certain cases, for example when dazzled by a vehicle following behind, a quick response is desired. The response time of previously developed systems, because the electrochromic elements are driven by a unipolar voltage source, is mainly determined by the, generally long, charge and discharge times of these elements.

Furthermore, in previously developed systems, the electronic control is not easy to adapt to multiple types of elements and to mirrors of different sizes.

Moreover, with these systems the user has no or very limited options to set reflection levels and threshold values of optical parameters according to his own preference.

The object of the invention is to obtain an automatic or non-automatic device for controlling the amount of light reflected from a surface, with a short reaction time, in which different types of elements with variable and controllable optical properties can be used, the reflection properties and levels can be set at will by the user and the set values are recorded and preserved, and which device can be mounted relatively easily on an already existing substrate.

According to the invention, this can be achieved by using a programmable microcomputer, providing user-operable switches or keys, and providing the device with a simple mounting mechanism.

The use of a microcomputer makes it possible during the manufacturing process to adapt the control as required to the type and model of the optical element to be used, by means of (re) programming. Furthermore, the time required to activate the element can be minimized by controlled dosing of the supplied electric charge. By switching the polarity of the control signal, the deactivation time can also be minimized by apparently supplying a negative, i.e. neutralizing, electric charge. The microcomputer calculates the required amount of charge on the basis of the physical data of the element and the desired optical target properties.

The user can influence the optical behavior of the system by giving certain instructions I to the microcomputer by means of a number of switches and / or keys.

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The fixing mechanism makes it possible to mount the device on a surface without auxiliary tools.

The user can influence the optical behavior of the system by giving certain instructions to the microcomputer by means of a number of switches and / or keys.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the figures.

Fig. 1 shows a front view of a rear-view mirror with a mirror surface 1, a housing 2, a push button 3 for switching on and off and two push buttons 4.5 for setting the desired reflection level, and electrical conductors 6 for the power supply. 10 close to the vehicle's electrical system.

Fig. 2 shows a rear view of a possible fixing device, in this case two fixed clamps 1,2 and two clamps 3,4 movable relative to the housing, with which the whole is fixed on an existing mirror.

Fig. 3 shows an openwork mirror with a spring 6 for tightening the springs shown in Figs. 2 movable clamps shown, "electrochromic" glass 4, and a printed circuit board with microcomputer 5 for controlling and controlling the "electrochromic glass.

Fig. 4 schematically shows the control system. The light detectors Α, Β give microcomputer D information about the intensity of the light at the front of the vehicle and coming from behind. The microcomputer D processes this information and controls the reflectivity of the "EC element" G via the variable power source E and the "EC (electrochromic) element driver" F. Switches C allows the user to influence the behavior of the microcomputer. The desired reflectivity of 'EC element' G can be set manually and the sensitivity of the detectors Α, Β can be adjusted indirectly.

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Claims (13)

1. The invention relates to a device for controlling the amount of light reflected by a surface, consisting of a number of photosensitive elements, a housing, an element with variable and controllable optical properties, and a control unit for controlling it, with characterized in that this device is provided with a frame for mounting on a surface, such as, for example, in the case of a rear-view mirror, a number of resilient clamps with which the housing can be mounted relatively easily without auxiliary tools on an existing mirror. Device according to claim 1, characterized in that the housing can be mounted on several types of surfaces, such as several types of existing mirrors in the case of a rear-view mirror. 3. Device as claimed in claim 1, characterized in that the required power supply is obtained by connection to an already existing energy source, such as the electrical network of a vehicle in the case of a rear-view mirror. Device according to claim 1, characterized in that it is provided with one or more switches or buttons, with which threshold values and control parameters, such as reflection levels and light sensitivities, can be set manually or, for example, the device can be switched on and off. Device according to claim 4, characterized in that said set values and parameters are recorded and stored. Device according to claim 5, characterized in that the set and recorded values and parameters are also retained after the system has been switched off, such as when the electrical supply is switched off in the case of an electronic control. Device according to claim 1, characterized in that it is provided with one or more signal features which indicate whether the device, or the elements or the control unit, is active, such as, for example, by lighting up a light-emitting diode when said element with variable and adjustable optical properties. 8. Device as claimed in claim 1, characterized in that said control unit for control comprises a circuit of electronic components and a microcomputer. 9. Device according to claim 8, characterized in that said element with variable and controllable optical properties is an electrochromic element. 1010089 Device according to claim 8 or 9, characterized in that said microcomputer can be programmed 'in circuit' to make said control unit suitable for controlling several types of elements with variable and controllable optical properties, such as' solid phase and "liquid-phase" electrochromic 5 elements. Device according to claim 8 or 9, characterized in that said microcomputer can be programmed "in circuit" to make said control unit suitable for systems with a reflective surface of different shape or size, such as mirrors of different sizes. Device according to claim 8 or 9, characterized in that said control unit for the control protects said element with variable and controllable optical properties by limiting the maximum amount of energy supplied thereto, such as by current limiting in the case of an electrochromic element . Device according to claim 8 or 9, characterized in that both positive and negative electrical voltages can be applied to said electrochromic element, said microcomputer calculating the optimal values and durations, whereby relatively rapid changes, in less than 2 seconds, in the reflection level of the device are possible. 20 1010089