DE29707066U1 - Microretroflector - Google Patents

Description

Microret rof1ector

Description:

In measurement technology, optical mirrors are used for example for light barriers, whose retroreflection (also called retroreflection) is carried out by triples, which are joined together in large numbers to form the reflective surface, so-called triple mirrors. Triple mirrors with pyramid-shaped triples, which are also called cube-corner pyramids, are also used.

However, this pyramid shape of the triple is not often used for retroreflectors that are manufactured using plastic injection molding because it has about 33% non-retroreflective surfaces. Far more efficient systems are known. This simple pyramid shape was only used again during the development and manufacture of reflective foils because the more efficient triple shapes could not initially be manufactured using microsystem technology.

In order to produce the master models for the imprinting of very small triples, a

- 6 high-precision microsystem technology required.

So far, only thin and flexible film material with a thickness of < 1 mm, usually even < 0.5 mm, has proven suitable for forming the triples by embossing. For the final application and attachment, additional punching, treatment with adhesive or mounting on a plastic or metal body is then necessary. A particular disadvantage is that the film is not a rigid body that guarantees exactly the same beam path at every point.

The microretroflector according to the invention can, however, be manufactured economically as a mass product using plastic injection molding, for example, and immediately takes on its final design and/or fastening appropriate to the application. In addition, due to its construction, it can reflect significantly more light in a targeted manner than conventional, elastic reflective foils, because it is a rigid, i.e. inflexible body, so that light rays can be directed extremely precisely. The total microtriple surface is uninterrupted, so that fine scanning and recognition of printed codes are possible in the sensor technology.

In order to achieve these higher performance characteristics of retroflexion and cost-effectiveness, the following procedure is used. The surfaces that shape the retroflexion are manufactured as a galvanic mirror copy made of nickel and/or copper. This mirror copy is copied from a master surface. The master surface is made of nickel and/or copper. The microtriple structure in the form of microtriples in pyramid shape is cut into the master surface with a diamond. The microtriples are also called cube corner pyramids. The microtriples should have a key width of < 1.2 mm, which describes the edge length of the base of the pyramid.

The plastic plate or glass plate that carries the microtriple structure is referred to here as the light passage body, because the incoming light must first pass through the light passage body in order to reach the microtriple. The light then returns from the microtriple through the light passage body to the light source. The microtriples are therefore firmly connected to the light passage body to form a single plastic body or glass body. The total microtriple surface formed from the pyramidal microtriples must be continuous without

interruptions to ensure trouble-free scanning using sensors. The thickness of the plastic plate or glass plate without the adjacent microtriples is referred to as the height of the light passage body. The height of the light passage body should be at least 2.7 times the geometric pyramid height. The pyramid height is the vertical path from the top of the pyramid to the center of the base of the pyramid. In addition, the height of the light passage body should be > 0.8 mm.

The surface of the light transmission body facing the incoming light is flat. However, it can be concave or convex in order to focus or scatter the light rays. The focal point of the microretroflector can thus be determined for a given observation distance.

In order to use the microretroflector in road traffic, it is recommended to further improve visibility by curving the light-transmitting body. One property of the microretroflector is that it rotates polarized light in the polar direction without canceling the polarization itself. The microretroflector can therefore be used with 0 the well-known polarizing filter processes of sensor technology.

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observed and disruptive extraneous light is switched off. This is particularly important for light barrier sensors when they have to observe reflective surfaces, such as glass bottles or packages with plastic surfaces.

If these polarization-rotating properties are to be eliminated, the back side of the microtriple, which faces away from the light, is vapor-coated with aluminum, copper, silver or gold.

When observing motor vehicles in traffic for traffic counting or toll calculation, it is also advisable to attach this microretroflector according to the invention to the motor vehicle and to observe it with sensors. Extraneous light can be blocked out by a polarizing filter. For example, the registration stamp on the car number plate can be designed as a microretroflector according to the invention and/or as a microretroflector with additional printing for vehicle identification or for checking that a toll has been paid. The number plate itself can also be designed as a microretroflector according to the invention.

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The microretroflector is very well suited for reflective surfaces on roads, for example reflectors for road marker posts or reflectors on motor vehicles or bicycles, because its lower overall height and the very low microtriple height mean it can be manufactured much faster and with less material, and therefore more cost-effectively, than conventional reflectors with microtriple sizes over 1.2 mm.

Fig. 1 shows a microtriple in pyramid shape. This microtriple for retroflection is also called a cube corner triple because it resembles the corner section of a cube.

The light emitted by the light transmitter enters the base of the pyramid and is redirected via the surfaces (1), (2) and (3) and sent back to the light transmitter. The base of the 0 pyramid has the same format as the base of the

Microtriples and forms a triangle. This microtriple form should not be confused with cubic fullcubes, whose base forms a hexagon.
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Fig. 2 shows the microretroflector according to the invention with the total reflecting surface (4), which consists of microtriples in pyramid shape.

0 Fig. 3 shows the function of the microretroflex

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tor in a simplified two-dimensional representation. The light beam (5) emitted by the light transmitter first hits the surface (6) of the light passage body (7), passes through it, passes through the base of the microtriple pyramid (8) and is deflected over three surfaces in the microtriple (9). The light beam is displaced by the distance (10) and leaves the microretroflector in the direction of the light transmitter as a retroreflected beam (11).

Fig. 4 shows the microretroflector in an exemplary design from the light-exposed front side. The pyramidal microtriples are arranged firmly connected behind the light passage body (7), which is designed as a plate. At the edge (12), the light passage body is connected to the rear wall box by ultrasonic welding. Screw holes (13) for fastening are provided at two corners of the microretroflector.

Fig. 5 shows a section through a microretroflector according to the invention. The light transmission body (7) faces the light transmitter, behind which the pyramidal microtriples (4) are arranged. The surface 0 (6) of the light transmission body is here

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shown flat, but it can also be concave or convex if a focal point of retroreflection is desired. At position (13) the rear wall box (14), which is intended to protect the pyramidal microtriples, is connected to the edge (12) of the light passage body so that no water, water vapor and/or dirt can penetrate into the cavity (15), which would impair the function of the microtriples.

Claims (4)

Utility model application Applicant: IMOS Gubela GmbH Schleifweg 2 77871 Renchen Microretroflector 1. Microretroflector made of plastic or glass for light retroreflection for use in sensors, such as light barriers, optical distance sensors and motion sensors, data acquisition systems in industry and road traffic, for traffic counting, toll calculation and light retroreflection for traffic safety characterized, that the microretroflector is designed as an inflexible, rigid body and that
the shaping elements for retroflexion Surfaces in the form intended for the molding are produced as a galvanic mirror copy of nickel and/or copper, copied from a master surface made of nickel, copper or plastic, in which the micro-triple structure has been cut in mirror image using a diamond and that
the light retroreflection of the microretroflector is caused by microtriples in pyramid shape, which are also called cube corner pyramids, and these microtriples have a key width of < 1.2 mm, which describes the edge length of the base of the pyramid,
and that the retroreflective total surface formed by the microtriples is uninterrupted and that a light passage body is arranged above the light entry surface of the pyramids, which is firmly connected to the pyramids, the height of which, which describes the length of the simple light path, is at least 2.7 times the geometric pyramid height and measures at least > 0.8 mm, and that the light entry surface of the light transmittance entrance body is flat and the light entrance body is flat. 2. Microretroflector made of plastic or glass for light retroreflection for use in sensors, such as light barriers, optical distance sensors and motion detectors, data acquisition systems in industry and road traffic, for traffic counting, toll calculation and light retroreflection for traffic safety according to claim 1
characterized, that the light entry surface of the light transmission body is convex or is concavely curved.
20 3. Microretroflector made of plastic or glass for light retroreflection for use in sensors, such as light barriers, optical distance sensors and motion sensors, data acquisition systems in industry and road traffic, for Traffic counting, toll calculation and light retroreflection for road safety according to claim 1
characterized, that the light transmitting body is convex or concave. 4. Microretroflector made of plastic or glass for light retroreflection for use in sensor technology, such as light barriers, optical distance sensors and motion detectors, data acquisition systems in industry and road traffic, for traffic counting, toll calculation and light retroreflection for traffic safety according to claim 1
characterized, that the back of the microtriples is coated with aluminium or copper or silver or gold.
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