DE4226266A1 - Electrically heated retroreflector for traffic signal, vehicle, etc. - has hollow housing with row of triple reflectors or prism surface sealing casing containing heating element for indirect heating via convection - Google Patents

Abstract

The retroreflector has a reflecting layered cover (3) mounted on a hollow housing, with a thermally insulating plate (2) supported on insulating struts (10, 11) inside. The electric heating element (1) is mounted on the side of the plate away from the cover, and out of contact with the plate. The plate has sufficient spacing around its edge to allow convection airstream to flow around it. The electric connections to the heater, and the thermal sensors (6) are via a multi-pin plug on the side of the housing. An optical sensor (7) inside the housing monitors the transmission of the cover, and enables condensation layers to be detected. USE/ADVANTAGE - Also for opto-electronic reflex light barriers. Compact heating control, no thermal damage risk to lens cover.

Description

Retroreflectors are used in the streets traffic at control and signaling devices, signs and motor vehicles and as a mirror for opto electronic reflex light barriers. To the retro reflectors against fogging with condensate or Retroreflectors can protect ice be heated. The invention describes one Retroreflector, for different tempera usable for many areas Areas of application without design changes suitable is.

This is how it is in Central Europe depending on the weather Misting the retroreflector with condensed Water in the fog or in the air cooling phase during the night with heating from to prevent about 15 to 20 degrees Celsius. If in Workshops the room temperature z. B. is 20 ° C, can condensate from vapors from warmer process water or chemical baths. Here the required surface temperature of the Retroreflector z. B. 40 ° C to a To prevent condensate on the retroreflector.

In laundries, condensates can be made from hot water dampen occur, which is a correspondingly higher Temperature of the heated retroreflector  require. On the other hand, the same retroreflector also used in snow areas against icing would be a surface temperature of 40 ° C or even 70 ° C completely unnecessary. In cold stores would a too high surface temperature of the Retroreflector even harmful to the refrigerated goods be. The heating must therefore be adjustable for the respective application.

As for cleaning work or damage the retroreflector has to be replaced or change the temperature setting by unauthorized persons is changed, must be secured by a device be that when a new connection of the same model, the intended surfaces temperature reached again and a temperature change is prevented by unauthorized persons.

Will the prism or the prism surface of the retro reflector formed in plastic, so was constructively not yet ensured that the Heating does not change the material to the to obtain optical properties of the prisms. Even a slight softening of the plastic surface could render the retroreflector ineffective make or deteriorate in performance.

Previous designs have these problems of Protection of the prism surface and securing the Operating temperature not solved.  

The invention therefore proposes a retro reflector with a gentle on the prism surface indirect heating. This heating is the first time the retroreflector is installed in the Power supply plug programmed so that too the same after replacing the retroreflector predetermined temperature range is reached again becomes.

Fig. 1 shows the heatable retroreflector seen in section from the side, Fig. 2 shows the opened retroreflector seen from above.

It is proposed according to the invention to arrange the electric heating element ( 1 ) on a circuit board ( 2 ) such that it faces away from the prism surface ( 3 ), which consists of triple mirrors arranged in a cube shape. This prevents direct heat radiation on the prism surface during the heating phase.

The prism surface ( 3 ) can be designed from cubic or pyramid-shaped triple mirrors.

The board ( 2 ) is placed on two carrying pins ( 10 ) and ( 11 ) so that the ambient air in the box ( 4 ) can wash around the board.

The heating element ( 1 ) can be heated above the target temperature of the prism surface without damaging the prisms ( 3 ). The heating element ( 1 ) heats its ambient air. This heated air is guided to the prism surface ( 3 ) and returns to the heating element ( 1 ) by natural thermals after the energy has been released to the prisms.

The heating element ( 1 ) carrying board ( 2 ) is arranged in a closed box ( 4 ) on the rear side of the prism surface so that the air in the box flows around the board ( 2 ) on all sides and the prism surface ( 3 ) over each Edge of the board can reach. The board ( 2 ) is therefore suspended in the box parallel to the prismatic field or attached to one or more supports so that the side walls of the box are not touched and an all-round sufficiently large gap ( 5 ) remains through which the air can circulate.

The electronic circuit components ( 6 ) for controlling the various heating temperatures, which switch the heating ( 1 ) on or off in a control circuit in order to maintain the preset temperature of the retroreflector, are also arranged on the circuit board ( 2 ). One or more light sources ( 7 ), which indicate the operational readiness and / or the selected and / or reached temperature range, are arranged on the circuit board ( 2 ).

The board ( 2 ) is electrically connected to a multi-pin socket ( 8 ) which is inserted into the wall of the box.

Box ( 4 ) and prism field ( 3 ) are airtight and watertight connected to each other and closed by gluing or welding, in particular by welding with ultrasound.

The heatable retroreflector is connected to the socket ( 8 ) by a multi-pin plug for power supply. In Fig. 1 four connecting pins ( 9 ) are shown by way of example, one of which can be used for grounding and three for temperature selection.

By appropriate number of pins ( 9 ) and resistors assigned in the control circuit of the heating electronics, the control circuit can be influenced by selection and / or combination of the connection pins for power supply from the outside. This is done during the initial assembly of the system, for example by selecting the plug connection cable or by soldering bridges in the power supply plug.

If the power supply plug is now plugged into the connection box ( 8 ) of the heatable retroreflector, the power supply takes place for a certain temperature range. Pulling out and reinserting the plug does not change the temperature setting of the heatable retroreflector according to the invention.

It is also possible to replace the retroreflector with an identical model, for example due to damage. The temperature range is always reached, which was programmed in the connector by selecting the connecting pins ( 9 ).

This prevents incorrect operation. The identical retroreflector can therefore from Manufacturers are delivered as spare parts, both a cold store and a hot one laundry facility without change, provided the program mated connector at the user is present and unchanged.

The heatable retroreflector according to the invention can be fastened on a base by screwing the holes ( 12 ). So that the heat transfer from the box ( 4 ) to the base remains as low as possible, the mounting tabs ( 13 ) containing the holes ( 12 ) are arranged so that the rear wall ( 14 ) of the box when mounting on a flat surface, the base not touched.

In a further embodiment according to the invention, the box ( 4 ) can be provided on the inside with a heat-reflecting coating ( 15 ), in particular by mirroring with gold, silver, copper or aluminum. This reduces unwanted heat transfer to the housing.

In a further embodiment according to the invention, the prism plate ( 3 ) can be provided on the inside ( 16 ) with a reflective coating of gold, silver, copper or aluminum and a subsequent dark-colored heat-absorbing coating. This is how this mirroring acts on incoming light from outside. In conjunction with the additional paint, the heat is absorbed by the interior of the box ( 4 ) and contributes to an even more even heating of the prism surface ( 3 ).

The mirroring and varnishing of the prism surface ( 3 ) on the inside ( 16 ) is left out compared to the signaling light elements ( 7 ), so that their light can penetrate through the prism plate ( 3 ) to the outside.

In a further embodiment according to the invention the prismatic plate can be made from one plate Plastic or metal are made that additionally is covered with a reflective film. These Foil should preferably be a prism foil.  

In a further embodiment according to the invention, the prism plate ( 3 ) can also consist of glass prisms and / or reflex lenses encased in plastic.

Claims (12)

1. Heated retroreflector, characterized in that the retroreflector forms a closed hollow body, consisting of an outward lining up of triple mirrors and / or a prism surface ( 3 ) which closes a box ( 4 ) arranged behind, in which the heating of the The prism surface is made indirectly with air as the heat transfer medium. 2. Heated retroreflector according to claim 1, characterized in that the circuit board ( 2 ), which carries the heating element ( 1 ), can be washed free of air. 3. Heated retroreflector according to claim 1 and 2, characterized in that the circuit board ( 2 ), which supports the heating element ( 1 ), is attached to one or more support pins ( 10 , 11 ). 4. Heated retroreflector according to claim 1, characterized in that the temperature control and / or temperature selection via the power supply socket ( 8 ) can be influenced. 5. Heated retroreflector according to claim 1 and 4, characterized in that the power supply via a multi-pin connector ( 8 ). 6. Heated retroreflector according to claim 1, characterized in that the prism surface ( 3 ) is mirrored on the back and is provided with a heat-absorbing coating ( 16 ). 7. Heated retroreflector according to claim 1 and 6, characterized in that the mirroring and heat-absorbing coating ( 16 ) of the prism surface ( 3 ) relative to the lighting elements ( 7 ) is recessed so that the signal light of the lighting elements can penetrate to the outside. 8. Heated retroreflector according to claim 1, characterized in that the inside of the box ( 4 ) is provided with a heat-reflecting paint or mirror. 9. Heated retroreflector according to claim 1, characterized in that the box is provided with fastening tabs ( 13 ) which carry the fastening bores ( 12 ). 10. Heated retroreflector according to claim 1 and 9 characterized in that the mounting tabs ( 13 ) are so offset that when mounting the box with its rear wall ( 14 ) does not touch the mounting pad. 11. Heated retroreflector according to claim 1 to 10, characterized in that the prism surface ( 3 ) consists of a plate which is provided with a prism sheet. 12. Heated retroreflector according to claim 1 to 11, characterized in that the box ( 4 ) is additionally equipped with thermal insulation and / or its walls are themselves heat-insulating.