RU2271027C2 - Universal switched mirror - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: universal mirror has mirror, case, holder and radiation receiver. Assembly has at least two mirrors and at least one polarization filter and device for mounting mirrors in series into working position. Polarization filter is fixed onto at least one mirror. Assembly is made for installation of mirror without filter into working position, or at least one mirror with at least one polarization filter. Mirror being at working position provides ability of reflecting of incident radiation to radiation receiver.

EFFECT: improved efficiency at natural light.

14 cl, 10 dwg

Description

The invention relates to devices for improving the safety of vehicles, as well as improving the comfort and convenience of using vehicle mirrors, and, in particular, relates to a method of combining mirrors with different functionalities in one housing.

Known devices for vehicles [1, 2], containing a rear view mirror, side mirrors with polarizing filters to suppress glare polarized radiation. A disadvantage of the known devices is the large losses in the filters, leading to a significant darkening of the mirrors when they are used in the daytime and twilight, when polarized radiation is not used [1, 2].

The closest in technical essence and selected as a prototype is "Polarizing anti-dazzle" [1], containing a rearview mirror and side mirrors with polarizing filters.

The disadvantages of the prototype:

1. Significant losses in the polarization filters of the mirrors of natural unpolarized radiation in the daytime and twilight, leading to significant darkening of the mirrors.

2. It is not possible to exclude filters if necessary.

The claimed technical solution in the application to mirrors for vehicles is aimed at creating devices that allow the efficient use of mirrors in both natural, unpolarized and polarized radiation.

1. This is achieved by the fact that, in contrast to the well-known "Polarization anti-dazzle" [1], which includes a mirror, a housing, a holder and a radiation receiver, the "Universal Switched Mirror" contains at least two mirrors, at least one polarizing filter and a device for sequentially installing mirrors in a working position, wherein the polarizing filter is mounted on at least one of the mirrors, while this device is designed to be installed in the working position of a mirror without a filter or at least one mirror feces with at least one polarizing filter, and a mirror in the working position provides the ability to reflect the radiation incident on it to the radiation receiver.

2. In addition, it contains at least one more polarizing filter, the plane of polarization of which is rotated relative to the installed one.

3. In addition, it contains a third mirror on which at least two sequentially installed polarizing filters are located, the polarization planes of which are mutually deployed.

4. In addition, at least one polarizing filter is made on the basis of separators of the orthogonal polarizing radiation components of the sawtooth profile, the surfaces of which are installed in such a way that the input beam of incident radiation and the output beam of radiation reflected from the surface of the mirror pass through them at an angle close to the angle full polarization, and at least on one side under the tops of the sawtooth profile contains light absorbers.

5. In addition, the input surface of the polarizing filter contains a rotator of the plane of polarization.

6. In addition, the surface of the mirror contains a rotator of the plane of polarization.

7. In addition, the input surface of the polarization filter contains a rotator of the plane of polarization, the input directors of which are oriented relative to the incident polarized radiation, and the output directors are oriented relative to the vertices of the separators of the orthogonal polarized components of the radiation of the sawtooth profile.

8. In addition, the output directors and the vertices of the separators of the orthogonal polarization components of the sawtooth profile radiation are oriented relative to the radiation receiver.

9. In addition, a controlled rotator of the plane of polarization is introduced between the polarization filters.

10. In addition, it contains polarization filters with a controlled degree of polarization.

11. In addition, the input surface of the polarizing filter is located at an angle to the mirror.

12. In addition, it contains a sensor for the degree of polarization of radiation.

13. In addition, contains at least one color correction filter.

14. In addition, the optical surfaces contain an antireflection coating.

The proposed technical solution is illustrated using figures 1 to 10.

On figa, b, c shows the mirrors, respectively, with manual, mechanical and electromechanical switching.

On figa, b shows options with two and three switchable mirrors (side view).

Figure 3 shows the operation of the filter using sawtooth profile dividers.

On figa shows a fragment of a mirror with a polarizing filter on the separators of the polarizing components of the radiation.

On fig.4b shows a fragment of the mirror figa in section along the plane of incidence of the beam (side view).

On figa, a fragment of a mirror with two separators is shown, the polarization planes of which are mutually deployed.

Fig. 5b shows a fragment of the mirror of Fig. 5a in a section along the plane of incidence of the beam (side view).

In Fig.6, Fig.7 shows fragments of mirrors with polarizing filters containing rotators of the plane of polarization.

On Fig shows a fragment of the mirror with two separators of polarization components, the input rotator of the plane of polarization and a quarter-wave rotator on the surface of the mirror.

Figure 9 shows a fragment of a mirror in which a polaroid is used as the second filter.

Figure 10a shows a mirror with a polarizing filter, in the polarizing filter of which the separators of the polarizing components are oriented relative to the radiation receiver.

Figure 10b shows the relative position in space of the mirror and the radiation receiver (top view).

Figure 1 - 10 and in the text the following notation:

1 - housing.

2 - holder.

3 - a mirror.

4 - mirror with one polarizing filter.

5 - mirror with two polarizing filters.

6 - the handle of switching mirrors.

7 - mechanical or electromechanical device for switching mirrors.

8 - separator of orthogonal polarization components.

9 - light absorbers.

10 - directions of orientation in the space of the polarization planes of the incident and reflected radiation corresponding to the angle of total polarization.

11 is the basis.

12 - rotator of the plane of polarization.

13 - polaroid.

14 - quarter-wave rotator.

15 - radiation receiver (driver).

Thus, the inventive device "Universal switchable mirror" (1, 2) contains a housing (1), a holder (2), a mirror (3), a radiation receiver (15), a mirror with at least one polarizing filter (4) and a mirror switching device and further comprises at least one more polarizing filter, the plane of polarization of which is rotated relative to the installed one, a third mirror on which at least two polarizing filters are located (5), a polarizing filter on orthogonal polarization separators of the radiation components of the sawtooth profile, the polarization plane rotator (12), the input directors of which are oriented relative to the polarized radiation incident on them, the input surface of the polarization filter is angled to the mirror, polarization filters with a controlled degree of polarization, contain at least one polarization degree sensor The color correction filter and optical surfaces contain an antireflection coating.

The device operates as follows.

A universal switchable mirror is mounted on a vehicle and can be used as a rear-view mirror (figa, b) and as side mirrors (fig.1c).

In daylight and dusk, the driver installs a mirror without a filter (3) using a mirror switching device (7), which contains a mirror switching handle (6) for manual switching, or mechanical or electromechanical devices that switch mirrors semi-automatically, for example, by pressing the corresponding button on vehicle control panel or automatically according to a given algorithm embedded in the control unit.

In the dark, in the presence of glare radiation from passing vehicles, a mirror with one polarizing filter is installed (4) (Fig. 2a, b), while in the case of polarized glare radiation, the filter does not pass most of this radiation, and for non-polarized radiation, at least halves its intensity.

A mirror with a polarizing filter may contain at least one more polarizing filter, the plane of polarization of which is rotated relative to the installed filter (4), and a “band-pass” filter is realized.

Figure 2b shows a variant of the device with three mirrors (5), in which the third mirror contains at least two polarizing filters, the polarization planes of which are mutually deployed. At the same time, in the daytime and at dusk time, a mirror (3) is used without a filter, and in the dark with a low traffic intensity, the driver can install a mirror with one polarizing filter (4), which protects against blinding, but modulation of the residual glare transmitted through a filter caused by vehicle rolls while they are moving, which can help the driver to notice the vehicle approaching from behind in advance.

With a high traffic intensity, constant "blinking" of the suppressed radiation can tire the driver and he sets up a mirror (5) with a second polarization filter at least sequentially mounted with the maximum suppression plane shifted relative to the first one, which will make it possible to obtain a "band-pass" polarization filter that sharply reduces the modulation of the residual blinding radiation [1]. The passage of radiation through polarizing filters is shown in figure 3 - 10.

Figure 3 shows the operation of the filter on the separators of the orthogonal polarization components of the radiation of the sawtooth profile [3, 4] when unpolarized or partially polarized and similarly polarized radiation falls on its surface, as well as the orientation direction (10) in the space of the polarization planes for the incident and reflected waves radiation corresponding to the angle of total polarization and a given angle of incidence of the radiation wave on the surface of the separators of polarization components, which allows filters with minimal losses. The separator allows you to implement a thin "band-pass" filter that suppresses or transmits radiation in a given sector of the roll of vehicles.

On figa, b shows the operation of such a filter from the sawtooth profile (side view and full face).

On figa, b shows the passage of radiation through a filter consisting of two sequentially installed separators of polarizing components (8), the plane of polarization of which can be mutually deployed to obtain a "smooth band" transmission characteristics (front view and side view).

To align the polarization planes of the filter and the incident polarized radiation wave, a polarization plane rotator (12) (6, 7) was introduced at the filter input, for example, on nematic liquid crystals with a twist effect, which rotates the polarization plane of the radiation wave, orienting it relative to the vertices of the separators polarization components, and at large angles of incidence of the radiation wave on the mirror surface, the plane of polarization of the output wave at the output of the rotator can be set near the angle of total polarization and for incident radiation, an additional rotator (14) is installed on the mirror (Fig. 8), for example, a quarter-wave plate or a film of a birefringent substance, which, like the input rotator of the plane of polarization, matches the plane of polarization of the wave of radiation reflected from the mirror (3) and the polarizer separator narrowing thus filter bandwidth, which allows to implement a narrow-band filter.

With low requirements for transparency of the device, the second filter can be performed using the polaroid (13) (Fig.9).

Depending on the device requirements, in the first separator of polarizing components (8), the light absorbers (9) may not be installed or may be installed under the vertices on only one side of the separator of polarizing components of radiation. When using large mirrors, the separators of the polarization components of radiation and the director of the rotator of the plane of polarization at the output are oriented relative to the radiation receiver (Fig. 10a, b).

To obtain a more uniform characteristic in the passband (within the permissible angle of the vehicles), the orientation of the directors at the input of the rotator of the polarization plane can be somewhat chaotic, in which the deviation of the axes of the directors from the average position of the plane of polarization of the wave of incident radiation does not exceed the specified angles. In addition, filters with a controlled degree of polarization can be installed [4], which will automatically control the suppression of glare radiation depending on its intensity. To eliminate glare, accompanied by a double image, the input surface of the filter (base (11)) is located at an angle to the mirror.

To protect against glare radiation, the plane of polarization of which corresponds to the plane of polarization of the filter, a controllable rotator of the plane of polarization [4] can be introduced, which in the presence of such radiation (manually, by the driver or automatically) rotates the plane of polarization of the radiation wave transmitted through the first filter by 90 degrees ., which is then rejected by the second filter. To automatically control the rotator of the plane of polarization, a sensor has been introduced for the degree of polarization of the wave of incoming radiation, which, in the presence of glare radiation and when it exceeds a predetermined threshold, gives a corresponding signal.

If necessary, giving the image a color tone, the mirrors may contain a color correction filter. To prevent reflections from surfaces and optical matching, polarizing filters and rotators of the plane of polarization have an antireflection coating.

Using the invention will allow to create a convenient design of a universal multifunctional mirror.

Information sources

1. RF patent No. 2124161, F 21 V 9/14, 04/15/1997.

2. DE patent No. 4330708, F 21 V 9/14, 03.16.1995.

3. US patent No. 5168378, G 02 F 1/13, 12/01/1992.

4. RF patent No. 2173472, G 02 B 5/30, 07/07/1999.

Claims (14)

1. Universal switchable mirror, including a mirror, a housing, a holder and a radiation receiver, characterized in that it contains at least two mirrors, at least one polarizing filter and a device for sequentially installing the mirrors in the working position, while the polarizing filter is strengthened on at least one of the mirrors, while the specified device is made for installation in the working position of the mirror without a filter or at least one mirror with at least one polarizing filter, and the mirror in the working position, it is possible to reflect the radiation incident on it to the radiation receiver. 2. The mirror according to claim 1, characterized in that it contains at least one more polarizing filter, the plane of polarization of which is deployed relative to the set. 3. The mirror according to claim 1, characterized in that it contains a third mirror on which at least two sequentially installed polarizing filters are located, the polarization planes of which are mutually deployed. 4. A mirror according to any one of claims 1 to 3, characterized in that at least one polarizing filter is made on the basis of separators of the orthogonal polarizing radiation components of the sawtooth profile, the surfaces of which are mounted so that the input beam of incident radiation and the output beam of the reflected from the surface of the mirror, radiation passes through them at an angle close to the angle of total polarization, and contains at least one side under the vertices of the sawtooth profile. 5. The mirror according to claim 4, characterized in that the input surface of the polarizing filter contains a rotator of the plane of polarization. 6. The mirror according to claim 4, characterized in that the surface of the mirror contains a rotator of the plane of polarization. 7. The mirror according to claim 4, characterized in that the input surface of the polarizing filter contains a polarization plane rotator, the input directors of which are oriented relative to the polarized radiation incident on them, and the output directors are oriented relative to the vertices of the separators of the orthogonal polarized radiation components of the sawtooth profile. 8. The mirror according to claim 7, characterized in that the output directors and the vertices of the separators of the orthogonal polarizing radiation components of the sawtooth profile are oriented relative to the radiation receiver. 9. The mirror according to claim 4, characterized in that a controlled rotator of the plane of polarization is introduced between the polarizing filters. 10. The mirror according to claim 4, characterized in that it contains polarizing filters with a controlled degree of polarization. 11. The mirror according to any one of claims 1 to 3, characterized in that the input surface of the polarizing filter is located at an angle to the mirror. 12. The mirror according to any one of claims 1 to 3, characterized in that it contains a sensor of the degree of polarization of radiation. 13. A mirror according to any one of claims 1 to 3, characterized in that it contains at least one color-correcting filter. 14. The mirror according to any one of claims 1 to 3, characterized in that the optical surfaces contain an antireflection coating.

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