The present invention relates to an electronic coin tester.
Electronic coin testers are generally known, and usually comprise a housing which is provided with a coin insert to which a coin run-in connects. Usually, test sensor arrangements are provided in the region of the coin run-in channel, which test an inserted coin with regard to its material characteristics, its size or other characteristics. A switching mechanism is activated by a control device, depending on the results of the testing, wherein the switching mechanism usually comprises a deflection element and an electromagnet. The deflection element is actuated by the electromagnet, between a position releasing an acceptance channel and a return position. In the known manner, the deflection element may be designed as a strip-like runner track piece which in the idle condition of the electromagnet is a component part of a return channel or return runner track, and which is retracted, i.e. pulled out of the return channel on activation of the electromagnet, in a manner such that the acceptance channel is released. With the known electronic coin tester, the return channel ends in a return opening, which is accessible to the user at a narrow front plate, for the removal of returned coins.
It has been found that false coins, with malicious intent, have been inserted through the return opening into the return channel up to the deflection element, and that a valid coin has been inserted into the coin insert channel, so that the deflection element has been retracted and the false coin gotten into the acceptance channel, and was then acknowledged by the light sensor below the deflector. On account of this, the subsequent authentic coin hits the deflector and thus rolls again into the return. In this manner, false coins may circumvent the testing by way of testing sensor device.
The present invention relates to a coin tester with a return channel open to the front plate of the coin tester, with which one avoids a false coin getting into the acceptance channel via the return channel.
By way of the fact that the deflector comprises means for clamping a coin introduced through the return opening, preferably an upright edge, on activating an electromagnet which is in connection with the deflector and which brings the deflector into the retracted position, the coin located on the deflector is clamped such that the acceptance channel is not released and an authentic coin inserted through the insert slot is ejected together with the false coin through the return opening after the deactivation of the electromagnet. A manipulation of the coin tester is avoided in this manner.
One embodiment example of the invention is represented in the drawing, and is explained in more detail in the subsequent description. There are shown in:
A coin tester is represented in
A deflector 10 which is in connection with the electromagnet and is actuated between two positions by this, is inserted into the runner track 9 of the return channel. The deflector 10 is also shown in detail in
As has already been specified, false coins with malicious intent are inserted through the return opening 8 by way of wire or other tools, wherein this false coin has fallen through the acceptance channel 11 on activation of the magnet 5. In order to prevent this, the deflector 10 is provided with an edge 12, which on excitation of the magnet 5, clamps a present coin, so that the acceptance channel 11 is not released.
Such a manner of functioning may be recognized in more detail in
As may be recognized, recesses 17 are provided in the housing walls 16, in which the edge 12 is accommodated.
In the represented embodiment example, the edge 12 is designed as a continuous edge over the whole length of the deflector, but of course only webs or part elements of an edge may be provided.
Number | Date | Country | Kind |
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10 2005 001 088.1 | Jan 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP06/00109 | 1/3/2006 | WO | 00 | 11/12/2008 |