DD296769A5 - ARRANGEMENT FOR EXAMINING THE PHYSICAL PROPERTIES OF MUENCES - Google Patents

Abstract

The invention is used in particular for detecting the diameter and the surface structure of coins. In this case, the coins are scanned by means of the light transmitter and the light receiver, and subsequently the measurement values are processed in a signal processing circuit containing a microcontroller. Fig. 10 {coin; Diameter measurement; superficies; Exam; Light source; Lichtempfaenger; Signal processing; clock frequency; Microcontroller; optoelectronics; Amplifier; Muenzendrehung; Stray light receiving}

Description

For this 4 pages drawings

Field of application of the invention

The invention relates to an arrangement for testing physical properties of coins and serves in particular for detecting the diameter and the surface structure of coins.

Characteristic of the known state of the art

Coin testing systems have the task of detecting characteristic physical parameters of coins (geometric dimensions, material, embossing, knurling) and, after analyzing the measurement results, to decide on the authenticity and the value of the test object. For this purpose, different test methods are used in the art, which can be divided into mechanical, inductive and optical methods. The most widespread are the mechanical and inductive test methods, whereas the optical ones are less common. Many applications can not be uniquely assigned to a class because they use combinations of multiple methods. Especially the optical test methods often appear as a supplement in connection with others.

By optical test methods, especially the thickness and diameter determination, the surface detection and the speed-time measurement are realized. Thus, the photocell principle is used for thickness and diameter determination and for speed-time measurement.

To determine the surface structure, the embossing of the front and / or back or the knurling of the coin is used, using the law of reflection. In this case, the relief structure can be scanned with the aid of a partially transparent mirror or, to measure the relief tilt angle, the receiving sensor is preceded by a mask which has a specific reflection characteristic. Since only significant points are scanned in this case, disturbances can be minimized.

The evaluation takes place according to various aspects. Thus, the degree of gloss is determined with the aid of different approach angle of the transmit and receive sensors, furthermore, an evaluation of the beam shift or light intensity fluctuations can be made. Finally, beam imagers, solar cell structures, photographic identification or infrared sensors can be used.

It is known, inter alia, an apparatus for determining the diameter of circular objects, such as coins, in which a pair of photoelectric transducers are disposed at a passageway past which the circular articles pass. The output signals are applied to a pair of length measuring circuits and then into

composed. With the help of two selective amplifiers 6 and 7, the signals of different frequencies are separated again. The amplitude of the received signal with the frequency f 1 contains information about the coin diameter, while the amplitude of the received signal with the frequency f 2 gives information about the jump height and thus the error of the measured diameter. After both signals have been digitized with the aid of the analog / digital converter 8,8 ', they go to further processing in the microcontroller 9. Here, the linearization by means of a calibration curve and linking of both signals for the purpose of error correction.

The timing of the light emitter additionally has the advantage of suppressing measurement errors caused by extraneous light.

In order to rule out aging phenomena of the light emitter and of the light receiver as a source of error, it is recommended to regulate the radiant intensity of the light emitter through the microcontroller. The adjustment is done at idle the measuring device, d. h., there is no coin in the measuring channel. The light receiver is fully illuminated. The microcontroller increases in small steps the current flowing through the light emitters Storm until fixed received signal levels are reached at the outputs of the selective amplifier. The set current is not changed while a coin is being run. In addition, it is possible to adjust the light transmitter frequency individually, separately for each channel, to the center frequency of the selective amplifiers. Errors resulting from the aging of frequency-determining components can thus be compensated. The microcontroller varies idle the measuring device, the clock frequencies f 1 and f 2 until maximum received signals are achieved.

The registration of the surface structure of the coin also takes place with the help of optical sensors. FIG. 5 is used to illustrate the arrangement. A punctiform light transmitter 10 and a light receiver 11, which is to be referred to as a direct light receiver, are arranged above the flat-lying coin.

The light emitter 10 radiates at a certain angle to the surface of the coin 3. In the beam path of the light reflected from the surface of the direct light receiver 11. During the measurements, the coin is rotated about its center. The arrangement scans a concentric circular ring of the coin surface. Height differences on the surface result in a modulation of the light emanating from the light emitter, which is most pronounced in the passage of edges (Figures 6A-6C). After one revolution of the coin, the complete picture of a circular section 12 of the surface structure of the coin is obtained. The associated signal processing circuit is shown in FIG. 7. The light transmitter 10 is operated in a clocked manner in order to achieve good interference immunity against extraneous light. The received signal detected by the direct light receiver 11 is selectively amplified 13 and supplied to an analog / digital converter 15. Subsequently, the further processing takes place in the microcontroller 9. For the rotation of the coin, a motor with drive circuit 14 is present, which is monitored by the microcontroller.

The metallic surfaces of the coins have different reflectivity depending on the material, the degree of soiling and the surface roughness. Particularly localized contaminants result in dynamic reflectivity within a single coin. This can lead to measurement errors that are difficult to locate. The problem can be counteracted by the installation of a further measuring receiver (16, Fig.8), which carries the designation scattered light receiver. This detects the incident from the point of incidence of the light beam vertically upward light. The measured light intensity is also a measure of the reflectivity at the measuring point. The received signal processing is carried out separately for both received signals by means of selective amplifiers 13, 13 '; 9 after their digitization 15,15 ', the link in the microcontroller 9 is such that a reflection-independent signal is available. This passes through special filter programs that perform a flank steepening and then a comparison with stored pattern curves to identify the coin.

Both measuring systems, diameter classification and embossing scanning, can be advantageously controlled by a microcontroller. In modern devices of this type analog / digital converter with input multiplexer and digital / analog converter are already integrated, which are in conjunction with existing timers for controlling the light emitter. Thus, the system can be realized with a reasonable economic effort. Fig. 10 shows the block diagram of a possible implementation. The selective amplifiers are advantageously implemented as operational amplifiers, the amplifiers 13 and 13 'having an identical edge circuit due to the same center frequency. As an advantage of the embodiment according to the invention over the prior art arise in detail:

- The use of only one light receiver and greatly reduced in effort Signalauswerteschaltungen work cost-reducing;

- The use of an analog light receiver allows a higher resolution and greater accuracy;

the principle of integral area measurement reduces the measurement acquisition times and allows a higher throughput speed of the coins;

- The arrangement of the sensors allows a shift of the limit for the smallest measurable coin diameter;

- The integrated automatic drift correction increases the reliability of the arrangement and reduces the maintenance and service costs;

- The timing of the light emitter combined with the selective received signal amplification guarantee high security against incident external light;

- By using a microcontroller results in a high variability in the adjustment of the arrangement to higher-level function blocks and the possibility of uncomplicated parameter setting (for example, teach-in programming).

an addition circuit and a maximum value storage circuit detected. Subsequently, the measured values are applied to a circuit in which the diameters are determined. Furthermore, a material determination and a count of the number of coins is made with the proposed circuit (DE-OS 3302757).

The disadvantage here is the arrangement of several photoelectric transducers and the circuit complexity for the Signierauswertung, which leads to considerable costs in the production of the device.

Object of the invention

The aim of the invention is to minimize the cost of scanning the coins and to achieve a simple signal evaluation.

Explanation of the essence of the invention

The invention has for its object to provide an arrangement for testing physical properties of coins, in particular for diameter and surface structure detection, which operates on an optical basis and in which an electronic evaluation of the measured signals takes place.

According to the invention the object is achieved in that an optoelectronic sensor is used, which consists of a light emitter with a light receiver for detecting the diameter of the coin, that the coin is rotated by a motor, wherein a clocked signal of another light emitter in a second light receiver for Determining the surface structure of the coin is detected and the measurement results are evaluated in a microcontroller contained signal processing circuit.

In an expedient development of the invention, the diameter detection is carried out with two light emitters and a light receiver, a clocking of the two light emitters takes place with different frequencies and then the signal parts of the light receiver are separated by means of selective amplifier. It is further conceivable to use a scattered light receiver for detecting the surface structure next to the second light receiver, wherein the two received signals are linked in the microcontroller and an evaluation of the measured values using filter programs by comparing the specific location of the edge information of the coin to each other with known patterns becomes. Finally, by the microcontroller in idle control of the beam intensity of the light emitter and / or an automatic tightening the clock frequencies of the light emitter can be done.

embodiments

The invention is explained in more detail below with reference to the drawing of several embodiments. In the drawing show

Fig. 1 to 3: optoelectronic sensor for diameter detection

Fig. 4: Block diagram for signal processing according to Fig. 5

Fig. 5: optoelectronic sensor for detecting the surface structure

6 A to 6C: beam path of an arrangement according to FIG. 5

Fig. 7 is a block diagram for signal processing according to Fig. 5;

Fig. 8: another variant for the detection of the surface structure

Fig.9: Block diagram for signal processing according to Fig

Fig. 10: Block diagram for combined diameter and surface detection.

With the invention, the geometric diameter and the shape of the surface structure (embossing) of coins can be determined. For this purpose, measured values are recorded with the aid of optical sensors and then evaluated by a microcontroller. As a result, there is a statement about the authenticity and value of the examined coin.

The measurement of the geometric diameter takes place with the aid of an optoelectronic sensor system, which is shown in FIGS. 1 and 2. A strip-shaped light emitter 1 illuminates a light receiver 2, which has a geometrical structure matching the transmitter. The coin 3 passes between the light transmitter 1 and the light receiver 2 and shadows the light receiver 2 according to their diameter. The electrical received signal at the light receiver 2 passes through a minimum, the amount of which is a direct measure of the diameter of the coin. In this case, a constant emission power of the light emitter 1 is assumed during the coin passage.

In practice, it may happen that the coin due to their high kinetic energy when passing through the sensor has no contact with the track 4. When a light receiver having a linear receiving characteristic is available over the entire area, jumping a coin does not adversely affect the result. The received signal is only weakened by the part relevant to the coin diameter, regardless of where the coin shadows the light receiver.

As a receiver, discrete structures (photodiode arrays or CCD lines) can be used. These have excellent linearity, but are quite expensive and therefore not attractive for this application. Alternatively, homogeneous semiconductor structures (surface diodes, photoelements) can be used as the optical receiver. Unfortunately, their linearity in the edge region is insufficient.

The problem can be solved with a sensor arrangement according to FIG. 3 and a signal processing circuit according to FIG.

Compared to the arrangement in FIG. 1 and FIG. 2, a second light transmitter 5 has been introduced in FIG. Both light transmitters are clocked at a different frequency (switched on and off). The clock generation is performed by the microcontroller 9. The received signal measured with the light receiver 2 contains a frequency mixture consisting of frequencies f 1 and f 2

Claims (5)

1. Arrangement for testing the physical properties of coins, characterized by the following features: Use of an optoelectronic sensor system consisting of a light transmitter (1) and a light receiver (2) for detecting the diameter of the coin (3), - Rotation of the coin (3) by means of a motor (M), wherein a clocked signal of another light emitter (10) in a second light receiver (11) for determining the surface structure of the coin (3) is used. - Evaluation of the measurement results in a microcontroller (9) contained signal processing circuit. 2. Arrangement according to claim 1, characterized in that - Acquisition with two light transmitters (1,5) and one light receiver (2) a timing of the light transmitters (1, 5) with different frequencies (f 1, f 2) - A separation of the signal components of the light receiver (2) in the signal processing circuit by means of selective amplifier (6,7) takes place. 3. Arrangement according to claim 1, characterized in that a scattered-light receiver (16) is used to detect the surface structure next to the second light receiver (11), - a combination of the two received signals (f 3) in the microcontroller (9) is performed, - An evaluation of the measured values using filter programs takes place, in which the specific position of the edge information of the coin (3) is compared to each other with known patterns. 4. Arrangement according to claim 1 and 2, characterized in that a regulation of the beam intensity of the light transmitter (1,5) by the microcontroller (9) takes place in idle. 5. Arrangement according to claim 1 and 2, characterized in that an automatic tightening of the clock frequencies (f 1, f 2) of the light transmitter (1,5) for the diameter detection by the microcontroller (9) is carried out at idle.