EP3362998A1 - Testing device for testing coin blanks - Google Patents

Abstract

The invention relates to a testing device (10), which can be a component of a feed device for supplying coin blanks (11) to an embossing press or press station (12). The testing device (10) has a first sensor device (30), which measures in a contactless manner and/or a second sensor device (40). Each available sensor device (30, 40) controls an assigned ejection device (32 or 41). By means of the sensor device (30, 40), a respective certain property of the coin blank is detected and compared to a corresponding specification. If an inadmissible deviation from the specification is detected, the relevant sensor device (30, 40) actuates the respectively assigned ejection device (32, 41) in order to remove the coin blank from a main conveying device (13) which transports the coin blanks from a feed end (14) to a discharge end (15).

Description

 Test device for testing coin blanks

The invention relates to a test device for testing coin blanks. When embossing coins it is necessary to monitor their shape and size. This is important because many slot machines have inspection and control equipment to determine the authenticity of the coin.

So far, the embossed coins have been successively promoted in different containers for quality assurance. The last embossed coin of a filled container was tested. If this coin was fine, it was concluded ge ^¬ that all coins are in the tank in order.

A similar sampling test is described for example in DE 34 37 847 AI. There, the coin blanks are transported via a feeder to a stamping press. The embossed coins are removed via a discharge device from the embossing tool. For this purpose, a slide is present ^¬ through which the embossed coins are fed directly to a storage or control station. There, for example, a coin tray may be present, wherein in each recess of the coin tray each coin is ge ^¬ promotes. There is a visual inspection carried out. The finished coins, which are not checked by visual inspection, are conveyed to an additional, separate storage station. In such a test, a 100-percent control can not be done. The quality of the coins can only be checked at random. On this basis, it can be regarded as an object of the present invention to improve the assurance of the quality of the embossed coins.

This object is achieved by the test device having the features of patent claim 1.

The testing device according to the invention is to be ^¬ aimed to examine coin blanks during feeding to an embossing station. The testing apparatus has a main conveyor which conveys a disordered amount of coin blanks provided at a feeding end in a conveying direction to a discharge end. The main conveyor may for example be a conveyor belt. Preferably, the coin blanks lie during the promotion on a conveying surface of the main conveyor on one side, while the other side facing upwards. The main conveyor ^¬ direction is preferably driven without a standstill for promoting the coin blanks.

At the feed end, the coin blanks are provided unsorted in an ^exemplary embodiment. In conveying Rich ^¬ tung behind the feed end is preferably a Vereinze- conversion or arranged guide means which consecutively arranges the coin blanks in the conveying direction and stringing, so to speak in the conveying direction. The distances between the coin blanks do not have to be the same.

The test device also has a first sensor to soreinrichtung, which is preferably arranged in the conveying direction behind the separating or guiding device. The first sensor device is ^adapted to detect a shape and / or a dimension of the coin blank during the ^¬ sen promotion in the conveying direction without contact and preferably optically. The first sensor device may, for example, have a camera. The detected shape and / or dimension is compared with at least one predetermined comparison model and / or at least one predetermined comparison value. If the detected shape and / or dimension is within the tolerance specified by the comparison model or the comparison value, the coin blank is conveyed further via the main conveyor device. Is an unacceptably large deviation of the shape and / or dimension of the comparison model or the Wenig ^¬ least determined at least one comparison value, the first Sen ^¬ soreinrichtung is adapted to control a first Ausschleu ^¬ seeinrichtung to the coin blanks of the before reaching To remove dispensing from the main conveyor. Preferably, the coin blanks that do not meet the specifications are removed via a first discharge opening from the main conveyor and collected for example in a container for rejects.

In this way, coin blanks whose contour does not correspond to the desired contour or whose diameter is too large or too small at one or more locations, sorted out. The change in shape when embossing in the embossing station is always the same. Due to the fact that faulty coin blanks are sorted out before embossing by means of the testing device, a random quality control of the embossed coins is sufficient in order to ascertain with very high probability the correctness of any embossed coins to be able to.

The test device is preferably part of a feeding device for feeding coin blanks to the embossing station. Between the embossing station and the discharge end of the main conveyor, there may be another conveyor such as a revolving dish or the like.

Preferably, the first sensor device is directed to a ^¬ to compare the size and / or shape of the coin blank to be tested in an image processing method comprising at least one predetermined comparison model and / or a comparison value. For example, the te erfass- contour of the edge of the coin blank can be compared with a pre give ^¬ NEN desired contour and checks whether the deviations are within predetermined tolerances or not. The detection of the dimension or the shape can be done without stopping the Münzrohlings during promotion by the main conveyor. The evaluation is very quickly possible in particular via an image processing method. The evaluation time is sufficiently short to control the first discharge device arranged behind the first sensor device in the conveying direction and to discharge a defective coin blank.

The first sensor device is preferably disposed immobility ^¬ Lich on a frame of the testing device. The coin blanks are moved past the first sensor device by means of the main conveyor.

It is also advantageous if the main conveyor has a main conveyor extending from the feed end to the discharge end, through a conveyor drive is driven in the conveying direction. As long as the coin blanks are not ejected, they lie with one side on the conveying surface of the main conveyor belt.

The conveying in conveying direction can take place continuously and without standstill phase. This ensures that a sufficient number of coin blanks per unit time can be transported to the embossing station.

It is also advantageous if a second Sen ^¬ soreinheit is present, which is adapted to detect a characteristic of the upwardly facing side of the coin blank during its promotion in the conveying direction without contact. The second sensor unit can have a camera for this purpose. As a characteristic, which is detected by the second sensor unit, preferably the color of the upward-facing side of the coin blank will he ^¬ sums. This is important if coin blanks are to be embossed, which have differently colored sides. The sides of the coin blank need not each have only a single color, but may also consist of two or more colors. If the arrangement of the different color areas on both sides of the coin blank is different, the coin blank must be fed with the one side up and the other side down the embossing station to make the embossing on the correct side. The correct position of the coin blank is ermit ^¬ telt means of the second sensor unit.

The two sensor units have a non-contact sensor and in a preferred example an optically operating sensor such as a camera. Age- natively or additionally, it is also possible to use sensors which transmit other waves and / or reflect waves, for example an ultrasound sensor, a laser scanner or a radar sensor. The waves can be sound waves and / or electromagnetic waves.

The second sensor unit can preferably be to be ^¬ aimed to compare the detected characteristics with at least one predetermined reference characteristic, and depending on the comparison result to control a second Ausschleu ^¬ seeinrichtung. By means of the second discharge device, a coin blank whose upwardly facing side has a characteristic which does not coincide with the comparison characteristic and deviates ^{inappropriately} from the main conveyor device and, for example, are removed from the main conveyor belt. The second Ausschleu ^¬ seeinrichtung can eject this coin blank through a discharge opening or feed a secondary conveyor.

The secondary conveyor may, for example, have a secondary conveyor belt. The main conveyor belt and the ^secondary conveyor belt can be driven by a common conveyor drive.

In a preferred embodiment, a turning device is present. The turning device is adapted to turn a coin blank, which is supplied to the turning device. In this case, his previously down-facing side is aligned upward and aligned his previously upwardly facing page down. In this ge ^¬ applied position of the coin blank can be fed back to the main conveyor. Preferably, such coin blanks whose Charak ^¬ teristik deviates impermissibly by the comparison characteristic can be supplied via the second ejection device of the flipping means.

It is further preferred if the turning device has a secondary conveying device. As explained, the secondary conveyor may comprise a secondary conveyor belt. The auxiliary conveyor transports a coin blank to be turned during or during the turning in the conveying direction. The turning device can feed the turned coin blank of the main conveyor in the conveying direction before the discharge end.

The first discharge device and / or the second discharge device are equipped in a preferred embodiment with a controllable blowing unit. The blowing unit discharges compressed air at an angle or at right angles to the conveying direction. As a result, a coin blank can be moved obliquely or at right angles to the conveying direction and discharged, for example, through a discharge opening or fed to the turning device.

The checking of the characteristic with the aid of the second sensor device and the feeding of coin blanks to be turned to the turning device can also be carried out separately and independently of the detection of the shape and the dimension of the coin blank by means of the first sensor device and the activation of the first ejection device. The testing device could also have the second sensor device and the turning device without the first sensor device and the first ejection device. Advantageous embodiments of the invention will become apparent from the dependent claims, the description and the drawings. Hereinafter, preferred embodiments of the test apparatus will be explained in detail with reference to the accompanying drawings. Show it:

1 is a block diagram of an embodiment of a test device and an adjoining embossing station,

2 is a highly schematic perspective view of ^¬ a coin blank,

3 shows an embodiment of a coin blank in a cross section,

Fig. 4 is a perspective schematic representation of an embodiment of the test apparatus and

5 is a schematic, block diagram similar Dar ^¬ position of a turning device of the test device.

Fig. 1 shows a block diagram for a Prüfvorrich ^¬ tung 10 for checking coin blanks 11 during the conveying movement to an embossing station 12. The testing device 10 forms an integrated test and delivery device. It has a main conveyor 13, which transports the unsorted coin blanks 11 provided at a feed end 14 in a conveying direction F and emits a dispensing end 15 of the testing device 10. The coin blanks 11 can at the discharge end 15 preferably are transported via a further För ^¬ dermittel, such as a revolving plate or the like to the embossing station 12 next. The main conveyor 13 has in the embodiment, a main conveyor belt 19, which is performed by a conveyor drive 20 umlau ^¬ fend to roles not shown. The rollers of the main conveyor belt 19 are at least at Zufüh ^¬ rende 14 and the discharge end 15. The main conveyor belt 19 may have between the feed end 14 and the discharge end 15 more rollers or other means for support.

The coin blanks 11 can, for example, schematically illustrated in Figs. 2 and 3 form aufwei ^¬ sen. Each coin blank 11 has a first side IIa and a second side IIb. During transport by means of the main conveyor ^{¬ device} 13 of the coin blank 11 with one of these two sides IIa, IIb on a conveying surface 21 of a main conveyor 13 and according to the example on the conveying surface 21 of the main conveyor belt 19. The respective ^¬ oner side is directed away from the conveying surface 21 upwards.

The coin blanks 11 need not necessarily have a circular ^¬ round contour. The contour of the edge of a coin blank 11 can also be polygonal or another have a lovely shape. Viewed in cross-section (FIG. 3), the coin blank can have an annular elevation in the region of its edge on the two sides IIa and IIb.

In the conveying direction F following the feed end 14, the test device 10 has a first guide 22. The first guide device 22 ensures an arrangement of the coin blanks 11 approximately in a row in the conveying direction F one behind the other. In the conveying direction F juxtaposed coin blanks 11 are thereby avoided.

For this purpose, the first guide 22 has at least one guide body 23, each with a guide surface 24. The guide surface 24 of the at least one guide body 23 is oriented obliquely to the conveying direction F. The guide surface 24 serves as a stop for the main conveyor belt 19 be ^¬ wegten coin blanks 11. The movement of the main conveyor belt 19 in the conveying direction F, the coin blanks 11 can slide along the guide surface 24 of guide body 23 and at the end of the guide body 23 and the guide surface 24 released again. In the exemplary embodiment, the first guide device 22 has two guide bodies 23, between which there is a gap 25 in the conveying direction F, through which the coin blanks 11 are conveyed and placed approximately in a row in the conveying direction F on the main conveyor belt. The two guide bodies 23 have viewed in the conveying direction F with spaced ends.

Subsequent to the guide device 22, a first sensor device 30 is arranged immovably on a frame or the like of the test device 10. The first sensor device 30 has a non-contact measuring sensor, eg an optically measuring sensor, such as a cable. mera 31 on. The camera 31 or the sensor of the first sensor device 30 is arranged above the conveying surface 21 of the main conveyor belt 19 so that the coin blanks 11 leaving the Leitein ^¬ direction 22 below the sen ^¬ sensor or the camera 31 by means of the main conveyor belt 19 in the conveying direction F. to be moved. There is no standstill for detection, but the coin blanks 11 are transported continuously in the conveying direction F by means of the main conveyor 13 or the main conveyor belt 19.

The first sensor device 30 is configured to detect the shape or contour of the coin blank 11 and / or one or more dimensions of the upwardly facing side IIa or IIb of the coin blank 11. The sensor or the camera 31 generates a corresponding sensor signal which is compared in the first sensor device 30 with a predetermined comparison model and / or comparison value to determine whether the detected shape or at least one dimension corresponds to the comparison model and / or the comparison value within the given tolerance. If this is not the case, but the coin blank 11 has an impermissibly large deviation with respect to the shape and / or at least one dimension of one of its two sides IIa, IIb, the first sensor device 30 generates a first drive signal AI for driving a first discharge device 32 ,

The first discharge device 32 is arranged behind the first sensor device 30 when viewed in the conveying direction F. In the embodiment described here, the first discharge device 32 includes a blowing nozzle 33, by means of which a short-term compressed-air flow is inclined and preferably at right angles to the conveying direction F. can be encountered. The blower nozzle 33 is aligned with the coin blanks 11 leaving the first sendor device 30. By means of the first discharge device 32 and, for example, the compressed air blast from the blowing nozzle 33, a coin blank 11 which does not correspond to the desired shape or does not have the desired dimensions can be removed from the main conveyor 13 and the main conveyor belt 19, respectively.

Example According to the first Ausschleuseeinrich ^¬ tung 32 therefore preferably operates without contact and in particular without moving parts such as slides or derglei ^¬ chen. Instead of a nozzle 33 that moves the coin blank 11 with compressed air and mechanical means prior ^¬ hands may be to sort out the relevant non-dimensionally stable coin blanks 11, as the like for example, mechanical valves or movable points or. The tuyere 33 has the advantage that the movement of the coin blanks very wear-free without moving mechanical elements he can follow ^¬ and is also easily possible if the coin blanks have a very small distance in the conveying direction F. The blast of compressed air can be spatially very limited and delivered specifically to a coin blank 11.

In the preferred embodiment, the inspection apparatus 10 has a sub-conveyor 34 in addition to the main conveyor 13. To the secondary conveyor 34 includes a secondary conveyor belt 35 which is arranged ^immediacy bar adjacent to the main conveyor belt 19. The main conveyor belt 19 and the secondary conveyor belt 35 extend in a common plane and are as far as possible ^¬ freely guided side by side. The secondary conveyor belt 35 preferably moves in the conveying direction F with the same Speed as the main conveyor belt 19. In the execution ^¬ example, both the secondary conveyor belt 35, and the main conveyor belt 19 is driven jointly by a conveyor drive 20 ^¬ . The secondary conveyor belt 35 starts at the feed end 14, but does not have to extend to the discharge end 15.

By means of the first discharge device 32, a coin blank which is not in accordance with the specifications is moved from the main conveyor belt 19 to the secondary conveyor belt 35. In conveying ^¬ direction F after the first ejection device 32 to the branch conveyor belt 35 a second guide 36 having at least one guide body 23 and at least one routing ^¬ surface 24 is present, which serves a Move ^¬ th through the first ejection device 32 to the branch conveyor belt 35 coin blank auszuschleusen through a discharge opening 37. The coin blanks 11 which do not meet the dimensional requirements are sorted out as rejects and are not fed to the embossing station 12.

From the feed end 14 to the first discharge device 32 or the discharge opening 37, the test apparatus 10 forms a first test section PI, in which the first sensor device 30 is arranged. In this first test section PI, the coin blanks 11 are checked by means of the first sensor device 30 for compliance with the shape and / or dimension.

Immediately after the first ejection device 32 or the Ausschleuseöffnung 37, the discharge end 15 could be in front ^¬ hands in one embodiment of the test apparatus 10th In the embodiments illustrated in FIGS. 1 and 3, the test apparatus 10 has a further, second test section P2, which additionally or alternatively be used independently of the first test section PI. Thus, the second checking section P2 may also be arranged un ^¬ indirectly after the first guide 22nd

In the second test section P2 of the test device 10, a second sensor device 40 with a touch ^¬ los measuring sensor and in particular a camera 31 is arranged ^¬ assigns. The sensor or the camera 31 are arranged above the main conveyor 13 or the main conveyor belt 19 in order to be able to detect the coin blanks 11 conveyed underneath. The second sensor means 40 is arranged to detect a characteristic of the upward white ^¬ send page IIa or IIb of the coin blank 11 during the promotion ^¬ sen in the conveying direction F. This detected characteristic is different from the detection of the shape and / or at least one dimension by the first sensor device 30. The characteristic describes an optically perceptible property of the upwardly facing surface of the coin blank 11. By means of the second Sensorein ^¬ direction 40 is preferably the The color of the upwardly ^facing side IIa or IIb of the coin blank 11 is detected.

The second sensor device 40 is also adapted to compare the detected characteristic and, for example, the color or color arrangement with a comparison characteristic ^¬ ristik and depending on a second Ausschleuseeinrichtung 41 to control. The second sensor means 40 generates a second drive signal A2 to betae ^¬ account the second ejection device 41 when the ER summed color or color arrangement does not correspond to the comparative ^¬ color or colors comparison arrangement. The second discharge device 41 is in the conveying direction F is arranged behind the second sensor device 40 and moves the coin blank leaving the second sensor device 40 obliquely or at right angles to the conveying direction F onto the secondary conveyor belt 35 if a deviation of the color or color arrangement has been detected.

This color recognition and ejection of the main conveyor 13 to the side conveyor 34 may for example be used in coin blanks 11, in which the first page IIa and the second side IIb differing ^¬ che colors or different color arrangements or color patterns have. When embossing, it is crucial that the embossing station 12 of the coin blank 11 with the correct side IIa and IIb is fed upwards or downwards.

Coin blanks with the wrong orientation in the

Main conveyor 13 are transported, are therefore discharged in the second test section P2 by the second off ^¬ sluice 41.

Both sensor devices 30, 40 are configured, for example, to carry out the comparison of the detected sensor data with the specifications on the basis of an image processing method.

The two discharge devices 32, 41 are constructed identically according to the example. They each have a respective blowing nozzle 33 for moving the respective coin blanks transversely to the conveying direction F from the main conveyor belt 19 onto the secondary conveyor belt 35.

In the exemplary embodiment of the testing device 10 described here, a turning device 45 is additionally provided, which is assigned to the secondary conveying device 34 and is in the conveying direction F behind the second Ausschleuseeinrichtung 41. Those coin blanks 11, which have different colored or colored patterned sides IIa, IIb and are conveyed with the wrong orientation in the main conveyor 19, are fed for turning over the secondary conveyor 34 of the turning device 45. The turning device 45 is adapted to turn the supplied coin blanks, so that the hitherto the respective conveyor belt 19, 35 facing side IIa or IIb has after turning upwards. The turned coin blanks 11 are then fed back to the main ^¬ conveyor 13 and, for example according to the main conveyor belt 19 and finally discharged at the discharge end 15 °.

An embodiment of a turning device 45 is illustrated in FIG. 4. The turning device 45 has a roller assembly 46 having a plurality of rollers 47, to guide the branch conveyor belt 35 from the common plane with the main conveyor belt ^¬ 19th A roller is arranged on the input side 47 above the secondary conveyor belt 35 at the turn ^¬ device 45th Another roller 47, which is designed as a turning roller 48, is arranged in the conveying direction F at a distance ^¬ . The axes of rotation of the input side roller 47 and the turning roller 48 are offset in a direction perpendicular to the conveying surface 21 of the main conveyor belt 19, wherein the turning roller 48 has a greater distance from the conveying surface 19 than the input side roller 47. The Nebenför ^¬ derband 35 is outside the turning roll 48 guided and returned via other rollers 47 of the roller assembly 46 to the feed end 14th

The turning roller 48 is enclosed in a peripheral portion of a guide body 49. The guide body 49 has a guide surface 50 facing the turning roller 48 (FIG. 5). The guide surface 50 has in cross-section at right angles ^¬ angled to the axis of rotation of the turning roller 48 seen a circular arc-shaped course and extends in an angular range of preferably at least 120 °. Between the guide surface 50 and guided around the turning roller 48 secondary conveyor belt 35 remains a gap 51, the thickness of which is measured at right angles to the axis of rotation of the turning roller 48 in approximately the thickness of a coin blank 11. A coin ^¬ blank 11, is thus guided through the gap 51 about the turning roller 48 around. As a result, its hitherto upwardly facing side IIa or IIb reaches in an orientation downward and the coin blank 11 is turned accordingly.

Below the turning roller 48 is a chute 52 before ^¬ hands, having oblique or perpendicular to the conveying direction F and the main conveyor 13 and the main conveyor belt 19 towards a slope. The turned coin blanks 11 slide along the chute 52 out of the turning device 45 back onto the main conveyor 19.

In the conveying direction F immediately following the chute 52, a third guide device 55 with at least one guide element 23 is provided according to the example. Those coin blanks that rely on the chute 52, the turning device 45, as well as those coin blanks 11, the main conveyor were supported 19 unturned by means of the main conveyor 13 and to be strung through the third guide means 45 and individually at the discharge end 15 abgege ^¬ ben.

In the embodiment shown in Fig. 4 also has a fourth guide 56 is provided, which the other guide devices has at least one guide body 23 with a guide surface 24. The fourth Leitein ^¬ direction 56 is arranged in the conveying direction F following the second Ausschleuseeinrichtung 41. Those coin blanks 11, which are ^conveyed along the main conveyor belt 19, come into contact with the third guide device 55 and are moved further inwards onto the main conveyor belt 19 by the secondary conveyor device 34 or the turning device 45. As a result, collisions with coin blanks 11 can be avoided, which are moved back to the main conveyor 13 at the output of the turning device 35.

The invention relates to a testing device 10, which may be part of a feeding device for feeding coin blanks 11 to a stamping press or press station 12. The test device 10 has a non-contact first sensor device 30 and / or a second sensor device 40. Each existing sensor device 30, 40 controls an associated Ausschleuseeinrichtung 32 and 41. About the sensor device 30, 40 each a specific property of the coin blank is detected and compared with a corresponding specification. If an impermissible deviation from the specification is detected, the ^relevant sensor device 30, 40 actuates the respective associated discharge device 32, 41 in order to remove the coin blank from a main conveyor 13, which transports the coin blanks from a feed end 14 to a delivery end 15. Reference sign list:

10 test device

 11 coin blank

 IIa first page of the coin blank

IIb second side of the coin blank

12 embossing station

 13 main conveyor

 14 feeders

 15 dispensing end

19 main conveyor belt

 20 conveyor drive

 21 conveying surface

 22 first guide

 23 guide body

 24 guide surface

 25 gap

30 first sensor device

 31 camera

 32 first Ausschleuseeinrichtung

33 blowing nozzle

 34 secondary conveyor

 35 secondary conveyor belt

 36 second guide

 37 discharge opening

40 second sensor device

41 second discharge device

45 turning device 46 roller arrangement

 47 role

 48 turning roll

 49 guide body

 50 guide surface

 51 gap

 52 slide

55 third guide

F conveying direction

 PI first test section

P2 second test section

Claims

Claims:

A testing apparatus (10) for inspecting coin blanks (11) on feeding to a stamping station (12), comprising main feeding means (13) for feeding the coin blanks (11) provided at a feeding end (14) in a conveying direction (F) a delivery end (15), with a first sensor device (30) which is adapted to detect a shape and / or a dimension of the coin blank (11) during its promotion in the conveying direction ^¬ (F) without contact, with at least one predetermined Comparing comparison model and / or comparison value, and depending on the result of the comparison, a first discharge device (32) to control coin blanks (11) with an inadmissibly large ^¬ ßen deviation of the shape and / or dimension before reaching the discharge end (15) from the main conveyor (19 ) to remove.

2. Test device according to claim 1,

 characterized in that with a in the conveying direction (F) behind the feed end (14) and in front of the first sensor means (30) arranged first guide means (22) which emits the coin blanks (11) arranged one behind the other in the conveying direction (F).

3. Test device according to claim 1 or 2,

characterized in that the first Sensoreinrich ^¬ device (30) ^comprises a camera (31).

4. Test device according to one of the preceding claims,

characterized in that the first Sensoreinrich ^¬ device (30) is ^adapted to compare the dimension and / or the shape of the coin blank to be tested (11) in an image processing method with at least one predetermined comparison model and / or comparison value.

5. Testing device according to one of the preceding claims,

characterized in that the first Ausschleuseein ^¬ device (32) is adapted to coin blanks (11) having an unacceptably large deviation of the form

 and / or dimension before reaching the discharge end (15) in a discharge opening (37) to move.

6. Test device according to one of the preceding claims,

 characterized in that the main conveyor (13) comprises a main conveyor belt (19) extending from the feed end (14) to the discharge end (15), driven by a conveyor drive (20) in the conveying direction (F).

7. Test device according to one of the preceding claims,

characterized in that a second Sensoreinrich ^¬ device (40) is provided which is ^{adapted to} ei ^¬ ne characteristic of the upwardly facing side (IIa, IIb) of the coin blank (11) during its promotion in the conveying direction (F) to detect contactless ,

8. Test device according to claim 7,

 characterized in that the characteristic of the upwardly facing side (IIa, IIb) of the coin blank (11) whose color is detected.

9. Test device according to claim 7 or 8,

characterized in that the second Sensoreinrich ^¬ device (40) which is adapted to compare the detected Cha ^¬ characteristic with at least one predetermined comparison characteristic, and depending on the comparison result, a second Ausschleuseeinrichtung (41) to control.

10. Test device according to claim 9,

characterized in that the second Ausschleuseein ^¬ direction (41) is adapted to remove Münzrohlinge (11) with an inadmissibly deviating from the comparison characteristic characteristics of the main conveyor (13).

11. Test device according to one of the preceding claims,

 characterized in that a turning means (45) is provided to turn a coin blank (11) so that its one side (IIa or IIb) faces upward and its hitherto upwardly facing other side (IIb or IIa) faces downward ,

12. Test device according to claim 10 and claim 11, characterized in that the second Ausschleuseein ^¬ direction (41) is adapted to coin blanks (11) with one of the comparative characteristic inadmissible divergent characteristic of the turning device (45) supply.

13. Test device according to claim 11 or 12,

 characterized in that the turning device (45) is associated with a secondary conveyor (34) which transports a coin blank to be turned (11) when turning in the conveying direction (F).

14. Test device according to one of claims 11 to 13, characterized in that the turning device (45) feeds a turned coin blank (11) back to the main conveyor (19).

15. Test device according to one of the preceding claims,

characterized in that the first and / or second ejection device (31, 41) has a drivable slide and / or a controllable nozzle (33) on ^¬ that for the displacement of a coin blank (11) obliquely or at right angles to the conveying direction (F) of compressed air can blow out.