NL8803165A - Reflective equipment with flat components - has two polarisation filters for each component with altering polarisation directions - Google Patents

Abstract

The reflective equipment has a matrix of separate flat mechanical components turning through 180 deg. on axes in their plane between end positions so as to look bright in one and dark in the other. Each component has a first linear polarisation filter whose direction is at 45 deg. to the axis of rotation. At a distance from this filter sufficient not to impede its rotation is a second such filter of direction also at 45 deg. to the axis. This in one end position the directions of the filters are parallel, and in the other at right angles to each other. The first filter has a non-transparent layer covering part of its surface and with a light-coloured reflective surface on one sided and a dark light-absorbent one on the other. The reflective surface is visible when the two polarisation directions are parallel, and the absorbent one when they are at right angles. A light source is mounted behind the filters.

Description

Display device

The invention relates to a display device with a matrix of separate planar mechanical elements, which are arranged at least substantially in their plane

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rotary axis can be rotated by 180 between two end positions, in one of which the elements have a light appearance and in the other of which the elements have a dark appearance.

In a known display device of the type mentioned in the preamble, the planar mechanical elements consist of opaque discs, one side of which has a light color and the other side has a dark color. By a suitable choice of the position of these discs in the matrix, various images can be formed with the aid of this known display device, such as numbers or letters.

Under daylight conditions, the difference between the light and dark sides of these known discs is very clear; however, in poor lighting conditions, such as at night, this difference is significantly smaller. Although the known display devices are usually provided with light boxes at their front for this purpose, the light of which is directed to the front side of the display device, but also in such a case the effectiveness of the display device at night is significantly lower than during the day.

The object of the invention is to provide a display device of the type mentioned in the preamble, wherein this drawback is eliminated in a simple, yet effective manner.

To this end, the display device according to the invention is characterized in that each mechanical element comprises a first linear polarization filter, the polarization of which

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towards an angle of 45 with the axis of rotation, while at a distance from each first polarization filter sufficient to not hinder the rotation of this first polarization filter, a second linear polarization filter is placed, the one projected from the polarization direction on the first polarization filter also an angle o of 45 encloses with the axis of rotation, such that the polarization direction and the said projected polarization direction of the first and second polarization filter respectively run parallel to each other and in the other end position perpendicular to each other, the first polarizing filter having an opaque layer covering a part of the surface of the polarizing filter, having a reflecting surface provided with a light color on one side and a dark light-absorbing surface on the other side the reflecting surface is visible when the polarization r direction and said projected polarization direction of the first and second polarization filter, respectively, run parallel to each other, while the light absorbing surface is visible when the polarization direction and said projected polarization direction are perpendicular to each other, and a light source is disposed behind the polarization filters.

When the first polarization filter is in such a position that its polarization direction is parallel to the projection of the polarization direction of the corresponding second polarization filter onto the first polarization filter, the light-colored reflective surface of the first polarization filter is visible. Under good lighting conditions, such as during the day, this reflecting surface reflects the light falling on the first polarizing filter, giving this polari filter a slightly colored appearance. At night, when no or almost no light from outside falls on the display, the light source is ignited. wherein the light exits through both polarization filters and through the uncoated portions of the first polarization filter, thus again providing this first polarization filter with a slightly colored appearance. Therefore, a first polarization filter located in said position has a light appearance both during the day and at night.

When the first polarization filter is in the end position, the direction of polarization of which extends perpendicular to the projection of the polarization direction of the second polarization filter on the first polarization filter, the dark light absorbing surface of the first polarization filter is visible. During the day, this means that incident light is largely absorbed by the first polarizing filter, so that it has a dark appearance. At night, when the light source in the display is lit, this light cannot pass through both polarization filters, since the light is almost completely extinguished by the polarization directions perpendicular to each other. Therefore, in such a case, the first polarizing filter also has a dark appearance when the light source is lit.

As a result of the measures mentioned, the display device has a good recognizability of the individual planar mechanical elements, which can be clearly seen, both under conditions in which sufficient light falls on the display device from the outside, and under conditions in which no or almost no light falls on the display device. different stand with a light appearance and another stand with a dark appearance.

In a preferred embodiment of the display device according to the invention, the opaque layer covers 50% of the area of each first polarization filter.

In this way, a balanced ratio is obtained between the resulting light appearance of the first polarization filter during the day and at night.

A constructionally advantageous embodiment of the display device is characterized in that all second polarization filters form part of a single plate-shaped polarization filter.

The invention is explained in more detail below with reference to the drawing, in which an embodiment of the display device according to the invention is shown.

Fig. 1 shows a perspective view of a display device according to the invention;

Fig. 2 schematically shows a detail of the display device of FIG. 1, and

Figures 3 and 4 show the basic operation of the display device according to the invention.

The display device shown in figure 1 has a box-shaped casing 1, which is provided at the front with regularly arranged openings 2. Flat disc-shaped elements 3 are arranged in each of the openings 2, which axis has a rotation axis R located in their plane (fig. 2) rotatable by 180 between two end positions. In one end position, the disc-shaped elements 3 have a light appearance, while in the other end position these elements 3 have a dark appearance. This is clearly visible in figure 1, whereby due to the difference in appearance of the elements placed in a matrix 3 indications can be formed, such as numbers, letters or other signs.

Figure 2 schematically shows a detail of the display device of figure 1. The disc-shaped element 3 is rotatable about the axis of rotation R. This rotation can be caused in known manner by electro-mechanical or electromagnetic actuation elements. However, other drives are also conceivable. The element 3 consists of a linear polarization filter, of which the

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direction of polarization encloses an angle of 45 with the axis of rotation R. In the position of element 3 shown, the direction of polarization is indicated, for example, by the line P, the angle oi between the axis of rotation R and the polarization direction o being 45 . When the disc-shaped element

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Rotated through 180 about the axis of rotation R, the polarization direction extends along the line P ', where the 10 angle ((1 between the line P' and the axis of rotation R is again 45.

At some distance behind the element 3 there is a second linear polarizing filter 4, which in the embodiment shown extends in the two end positions of the element 3 parallel to it. The polarization direction of this second polarization filter is indicated in Figure 2 by the line P, the axis of rotation R (or a parallel to it extending through the polarization direction P and the

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line R ') enclosed angle doll is again 45.

In the one end position of the element 3, the polarization direction of this element being indicated by P.

it therefore holds that the polarization directions of this element 3 and of the polarization filter 4 are perpendicular to each other.

The light emanating from a light source 5 placed behind the second polarizing filter 4 cannot therefore pass the two polarizing filters 4 and 3. When the element 3 is in the end position, with the polarization direction P ', the polarization directions P' of this 1 element 3 and P of the second polarization filter 4 extend parallel, so that the light from the light source passes through both polarization filters 4 and 3 can penetrate.

It should be noted that the distance between the first polarizing filter (disc-shaped element) 3 and the second polarizing filter 4 must be such that the rotation of the first polarizing filter about the axis of rotation R is not impeded.

The disc-shaped element 3 is provided with an in this case arranged in a regular pattern and a part of its surface covering opaque layer 6. In the embodiment according to figure 2 (and as will appear from figures 3 and 4) this opaque layer is arranged in a diamond pattern, in which 50% of the surface of the first polarizing filter 3 is covered by this opaque layer.

The opaque layer applied to the first polarizing filter 3 has a light-colored reflective surface on one side, while the other side has a dark light-absorbing surface. When the polarization directions P 'and P of the first polarization element 3 and second polarization element 4 run parallel to each other, the light-colored reflective surface of the opaque layer is visible. However, when the polarization directions P and P are perpendicular to each other, the dark light absorbing surface of this layer 6 is visible. This is explained in more detail with reference to Figures 3 and 4.

Figure 3 shows a first polarization filter 3, which is in the position in which the direction of polarization thereof runs parallel to the direction of polarization of the second polarization filter 4 placed behind this first polarization filter 3. The opaque layer is now light-colored reflective surface 6 'visible. This means that (daytime) light (daylight) incident on the element 3 is reflected by the reflecting surface 6 'and the element 3 acquires a light appearance. Also (at night) light emitted behind the second polarization filter 4, light passing through the second polarization filter 4 can pass both polarization filters 4 and 3 (since the polarization directions are parallel) and exit through the transparent element sections 7 located between the opaque layer 6 '.

Thus, a disc-shaped element 3 in the position shown in Figure 3 has a light appearance both at night and during the day.

In the position of the disc-shaped element 3 shown in figure 4, the polarization directions of the element 3 and the second polarization filter are perpendicular to each other. The dark light-absorbing surface 6 "is now visible. Light incident on the element 3 (during the day) is absorbed by the light-absorbing surface 6", so that the element 3 has a dark element. The light from the light source (not shown) located behind the second polarization filter is blocked by both polarization filters, since their polarization directions are perpendicular to each other. Therefore, the element sections 7 located between the opaque layer 6 "in this position of the disc-shaped element 3 also have a dark appearance.

An element 3 in the position shown in figure 4 therefore has a dark appearance both during the day and at night.

All second polarizing filters 4 can form part of a single plate-shaped polarizing filter, so that the structural design of the display device according to the invention is further simplified. It is also noted that in the display device only one light source has to be provided, the light of which can cover all openings 2.

When a strong light source is used, it may happen that light incident through the second polarizing filters 4 is partially reflected by the first polarizing filters 3 and then again reflected by the second polarizing filter. In this case, this light partially loses the polarization caused by the second polarization filters 4, so that part of this light can pass through the first polarization filters even when the polarization directions of the polarization filters 3 and 4 are perpendicular to each other. To overcome this problem it is possible to place the second polarizing filters 4 with respect to the first polarizing filters 3 at an angle, for example 45e. Light reflected from the first polarization filters 3 is then no longer reflected by the second polarization filters back to the first polarization filters, but is deflected, for example towards absorbing elements. The placement of the second polarization filters 4 must, however, be such that in the two end positions of the first polarization filters 3 the projected direction of the polarization of the second polarization filters 4 on the first polarization filters is parallel to or perpendicular to the polarization direction of the first polarization filters 3.

The invention is not limited to the embodiment described above, which can be varied in many ways within the scope of the invention.

Claims (6)

1. Display device with a matrix of separate planar mechanical elements rotatable by at least about an axis of rotation in their plane through 180 between two end positions, in one of which the elements have a light appearance and in the other of which the elements have a dark appearance, characterized in that each mechanical element comprises a first linear polarization filter whose polarization direction includes an angle of 45 with the axis of rotation, while at a distance from each first polarization filter sufficient to rotation of this first polarization filter is not impeded, a second linear polarization filter is placed, the projection of the direction of polarization on the first polarization filter also enclosing an angle of 45 with the axis of rotation, such that the direction of polarization and said projected direction of polarization of the first and second polarization filter respectively in the one end position parallel g run together and are perpendicular to each other in the other end position, wherein the first polarizing filter is provided with an opaque layer covering a part of the surface of the polarizing filter, which has a reflecting surface provided with a light color on one side and the other side has a dark light-absorbing surface, the reflecting surface being visible when the polarization direction and said projected polarization direction of the first and second polarization filter respectively run parallel to each other, while the light-absorbing surface is visible when the polarization direction and said projected polarization directions are perpendicular to each other, and a light source is placed behind the palarisation filters. 2. Display device according to claim 1, characterized in that the opaque layer covers about 60% of the surface of each first polarization filter. Display device according to claim 1 or 2, characterized in that all second polarization filters form part of a single plate-shaped polarization filter. Display device according to claim 1, 2 or 3, characterized in that between the light source and the second polarization filter there is an element which spreads the light evenly, such as milky white perspex. Display device according to any one of claims 1-4, characterized in that in the two end positions the two polarization filters enclose an angle. 6. Display device according to claim 5, characterized in that the angle is 45e.