EP0080073A2 - Method and apparatus for controlling the degree of filling of cigarette ends - Google Patents

Abstract

The invention relates to a method and a device for checking the filling level of cigarette ends by means of reflection light barriers (41), with extraneous light compensation with regard to the measured value generated by the reflection light barrier (41) for each measurement, a self-check between two measurements using a basic reflection, and also one Averaging is carried out over the measured values of those cigarettes (43) which are recognized as good. The mean value is then used to form the threshold value which the measured values must exceed so that the cigarettes (43) are recognized as good. Both cigarette blocks (44) and single cigarettes (43) can be checked.

Description

The invention relates to a method and a testing device for testing the degree of filling of cigarette ends according to the preambles of claims 1 and 9.

From DE-OS 28 13 866 a device for checking the filling level of cigarette ends is known, in which the light exit and entrance surface of the light transmitter or receiver are arranged transversely to the cigarette axis and separated from each other by a neutral zone and together within the end face lie on a fiber optic plate to which the cigarette end to be tested is brought to the system. Here, the light passes through multiple reflection in the region of _d Zigarettenen it from the light transmitter to the receiver, whereby the light intensity is greatly reduced. The weaker the signal received, the more tobacco fibers there are. If a preset threshold value for the light intensity is exceeded, the cigarette in question is considered a committee. Disadvantages here are the complex design and the particularly complicated structure of the reflection light barriers, the use of a small signal as an indicator for intact cigarettes, possible interference from extraneous light and possible contamination of the contact surface of the fiber optic plate for the cigarette ends, as a result of which the received signal can be influenced.

Another disadvantage is that this device works in the rising branch of the illumination curve of the reflection light barrier. This makes an ambiguous measurement possible: if a cigarette goes through If the break or severe damage is at a relatively large distance from the test head, the reflected signal on the falling branch of the curve can be the same size as with a good cigarette.

The object of the invention is to provide a method and a test device of the type mentioned at the outset in which a falsification of the signals is switched off or checked, a simple structure of the test device being made possible.

This object is achieved in accordance with the characterizing parts of claims 1 and 9, respectively.

This not only enables the use of commercially available reflective light barriers - consisting of a light-emitting diode and a phototransistor, which are arranged next to each other on one level - but also compensates for the incidence of extraneous light and checks for contamination, in order to stop the cigarette transport device, usually a cigarette packaging machine, if necessary, and to detect the Eliminate errors.

Further embodiments of the invention can be found in the following description and the subclaims.

The invention is explained below with reference to the embodiments shown in the accompanying figures.

• Fig. 1 shows a block diagram for a cigarette block tester.
• FIG. 2 shows an embodiment of an optical block test head for the device of FIG. 1.
• FIG. 3 shows the illuminance B of the reflected light from a cigarette end plotted against the distance d of the cigarette end from the light receiver of a reflection light barrier.
• 4 shows a circuit diagram (schematic) for an external light suppression circuit.
• 5 shows the temporal course of the suppression of extraneous light.
• 6 shows an embodiment for an averaging circuit.
• 7 shows a further embodiment for an averaging circuit.
• FIG. 8 shows a diagram relating to the statistical distribution of the cigarette quality plotted against the number of cigarettes in%.

According to the block diagram shown in Fig. 1, the cigarette block test device consists of an optical block test head 1 ₀ , which is connected to a dual multiplexer 11. The signals generated by the block test head 10 are fed via a line 12 to an external light suppression circuit 13, from which a line 14 to four test circuits 15, 16, 17 and 18 connected in parallel for checking for missing cigarettes, for checking for bad cigarettes, for checking, whether the basic reflection exceeds an upper limit and leads to a check whether the basic reflection falls below a lower limit. The test circuits 15 to 18 each have a threshold input 19. The outputs of the test circuits 15 to 18 are connected to a digital evaluation circuit 2o.

The evaluation circuit 20 also receives signals from an external light test circuit 21, the input of which is connected to the line 12 and which also has a limit value input 22. To control the extraneous light suppression circuit 13, the evaluation circuit 20 outputs signals to the extraneous light suppression circuit 13 via a line 23.

The evaluation circuit 2o also has inputs 24 for signals from a machine, for example a cigarette packaging machine, with which the cigarettes to be tested are transported along the optical block test head 1o. In the case of a packaging machine having a revolver, in which the cigarette blocks are picked up by cells of a revolver, these signals are those which relate to the angular position of the cells.

The evaluation circuit 2o also has an output 25 for stopping the machine, an output 26 for ejecting the tested cigarette block and an output 27 which is a pulsed constant current source 28 for the Controls block test head 1o, which in turn is connected to the block test head 1o via the dual multiplexer 11. Another output 29 of the evaluation circuit 2o controls the dual multiplexer 11.

In addition, an averaging circuit 3o is provided which is controlled via lines 31 by output signals of the evaluation circuit 2o and by the signals of line 14. Furthermore, the averaging circuit 3o has an input 32, via which the number of cigarettes to be used for averaging is predetermined, for example with the aid of a potentiometer 33, and an input 34, via which the ejection rate is predetermined, for example with the aid of a potentiometer 35. The output 36 of the averaging circuit 3o is connected via an analog switch 37 to the threshold value input 19 of the test circuit 16 for testing for bad cigarettes. The switch 37 has an input 38, to which it can be switched over and which supplies a fixed value, for example predetermined by a potentiometer 39, as a threshold value.

An embodiment for a block test head 10 is shown in FIG. 2, it comprises a mounting plate 40, which is provided with a row of receiving openings into which a corresponding number of reflective light barriers 41 are inserted, which are components consisting of a Light diode acts as a light transmitter and a photo transistor as a light receiver, which are arranged in a plane next to each other.

A plane-parallel transparent plate 42 made of glass, for example, is fastened in front of the mounting plate 4o and covers the reflection light barriers 41 to the outside. The thickness of the plate 42 is such that when the cigarette ends of cigarettes 43 of a cigarette block 44 which are located, for example, are located in a cell 45 of a revolver 46 of a cigarette packaging machine, the distance d of the cigarette ends from the respective photo transistors of the reflection light barriers 41 is greater as M, cf. Fig. 3, that is, when the cigarette ends rest on the plate 42, the largest signal (of course, depending on the degree of filling of the cigarette end) is generated in each case, and one becomes larger with increasing distance d on the falling branch K _from the curve K of Fig. 3 moves. The plate 42 prevents the purchase of curve K from entering the ascending region, so that ambiguities are eliminated. The reflection light barriers 41 are connected via a schematically indicated interface 47 to an evaluation circuit 48, as is shown as a block diagram in FIG. 1.

The extraneous light suppression is explained below with reference to FIGS. 4 and 5.

Each reflection light barrier 41 is scanned in three phases Ph1, Ph2 and Ph3. In the first phase Ph1, the light transmitter 41a remains switched off. The signal SF received by the light receiver 41b is measured and stored in an analog manner. This signal SF corresponds to the proportion of extraneous light. During the second phase Ph2, the light transmitter 41a is switched on. The first stored signal SF is subtracted from the signal SL measured here, the resulting signal SR then corresponds to the light reflected from the end of the cigarette to be tested without any extraneous light component. At the beginning of the third phase Ph3, the outputs of the test circuits 15 to 18 are queried and digitally evaluated. During the third phase Ph 3, the light transmitter 41a is switched off again, so that the input multiplexer of the double multiplexer 11 can be switched over at the end thereof.

According to FIG. 4, the signal received by the reflection light barrier 41 passes through the double multiplexer 11 to an input amplifier 50 which amplifies the signal to the correct level, correct polarity and sufficient power in order to be able to charge a subsequent capacitor 51. Behind the capacitor 51 there is an analog switch 52, which is turned on during the first phase Ph1, so that the capacitor 51 must charge up to the level SF generated by the extraneous light. During the second phase Ph2, in which the actual measurement takes place with the light transmitter 41a switched on, the analog switch 52 is again high-resistance. The capacitor 51 can now change its charging voltage SF only insignificantly during this period, especially since a subsequent amplifier 53 - connected as a voltage follower - is also very high-resistance. At the beginning of the second phase Ph2, the voltage at amplifier 53 is always zero, while at the same time the voltage at the output of input amplifier 5o already corresponds to extraneous light SF.

Until the end of the second phase Ph2, the voltage only increases by the amount corresponding to the more light received due to the light transmitter 41a being switched on. Because the voltage at the amplifier 53 was zero at the beginning of the second phase Ph2, a voltage SR is now present at it, which corresponds only to the light reflected from the light transmitter 41a to the light receiver 41b. The capacitor voltage SF corresponding to the external light is now subtracted from the received and amplified total voltage SL. The second phase Ph2 must last long enough to bridge the delay times of light transmitter 41a and light receiver 41b.

Fig. 5 shows the time functions in the suppression of extraneous light, namely the multiplex channel width S for a measurement, the voltage at the output of the input amplifier 5o (I), the voltage at the input of the amplifier 53 (II), the capacitor charge (III), the state of Switch 52 (IV), the state of the light transmitter 41a (V), the evaluation (VI) and the phases (VII).

While the extraneous light is suppressed in the manner described, the extraneous light test circuit 21 serves to compare the extraneous light signal coming from the line 12 with a predetermined limit value, which can be set, for example, via a potentiometer and which is present at the limit value input 22. If the external light is so great that it threatens to control the light receiver 41b supplies the evaluation circuit 2 ₀ which is connected to the output of Fremdlichtprüfkreises 21 on its output 25 a stop signal.

The extraneous light corrected signals on the line 14 are compared in the test circuit 16 with a predetermined threshold value. If one or more cigarettes of a cigarette block falls below this threshold value, the output of the test circuit 16 causes the evaluation circuit 2 ₀ to generate an ejection signal on its output 26 for ejecting the cigarette block as a committee.

If one or more cigarettes are missing in a cigarette block, then the signals received by the corresponding light receivers 41b are significantly lower than in the case of a bad cigarette, even if neighboring cigarettes partially cover the empty space due to displacement in the block. A significantly lower threshold value at the input 19 of the test circuit 15 in comparison to the threshold value for the test circuit 16 is also compared to the signals on line 14 so that all locations within a cigarette block where cigarettes are missing are recognized. If a predefinable number of cigarettes is missing in a block, which is determined by the evaluation circuit 20, this generates a stop signal at its output 25 and at the same time an ejection signal at the output 26.

The test circuits 17 and 18 are used for self-monitoring. Here, the basic reflection that occurs on the transparent plate 42, which is arranged in front of the reflection light barriers 41, is used when there are no reflecting objects (cigarettes) in front of the plate 42. This basic reflection is low in itself, but can change to lower or higher values depending on the type of contamination present on the plate 42 that arises during operation.

If the basic reflection rises above an upper predefined threshold value that is present at the input 19 of the test circuit 17 and thus cigarettes are recognized as too good, or falls below a lower predefined threshold value that is present at the input 19 of the test circuit 18 (contamination or parts of the Device failed), the test circuits 17 and 18, acting as comparators, generate an output signal, which causes the evaluation circuit 20 to generate a stop signal at its output 25.

This self-monitoring is carried out in the times when no cigarettes are arranged in front of the block test head 10. As a result, all reflex light barriers 41 are also checked for different types of failure after each measurement.

Since the evaluation circuit 2o can generate stop signals for various reasons, it is expedient to provide a display which stores and displays the cause of the respective stop. Before each new start of the machine, these stop displays must be cleared via a reset input 24a.

In the embodiment shown in FIG. 1, a double multiplexer 11, that is to say one multiplexer each for the light transmitters 41a and one for the light receivers 41b, which operate synchronously, is provided, but a simple multiplexer can also be used, which then each reflection light barrier 41 (Supply voltage from transmitter 41a and receiver 41b) switches with a switch. In the embodiment shown, it is particularly advantageous that the multiplexer 11 can be switched over in the third phase Ph3 of the scanning.

FIG. 6 shows an embodiment for the averaging circuit 30. This consists of an analog switch 6o with two inputs, namely line 14, via which an analog voltage value A of the cigarette currently being measured is applied, and one of lines 31, via which a digital control signal C is applied by evaluation circuit 2o , which causes the analog switch 6o to be opened, for example, during the last 3/5 of the transmission time of each reflection light beam 41. Behind the analog switch 6o there is a capacitor C ₁ and a further analog switch 62 with a further input, to which a digital control signal D is supplied from the evaluation circuit 2o via one of the lines 31, which causes the analog switch 62 to then always open for a constant time when the test of a cigarette is finished and this cigarette was found to be good by test circuit 16. The analog switch 62 is followed by an RC element 63 with a capacitor C ₂ and a resistor R, the output of the RC element 63 having an input of an operational amplifier 64 connected as a voltage follower.

Furthermore, an analog switch 65 is provided, from which an input is acted upon by an analog voltage value H, which is specified as the mean value when the device is switched on, while a second input is supplied via one of the lines 31 with a digital control signal E, which is provided by the evaluation circuit 2o is generated and opens the analog switch 65 for a short time after application of the operating voltage by a master reset pulse.

Another analog switch 66 is connected, on the one hand, to a constant current source 67 and, on the other hand, to one of the lines 31 via which it receives a digital control signal F from the evaluation circuit 2o, as a result of which it is opened for a constant time whenever a cigarette from the test circuit 16 is considered bad was found. The outputs of the analog switches 65, 66 are connected to the capacitor C ₂ , so that the capacitor C _{2 is} discharged by opening the analog switch 66 in the presence of a bad cigarette by the constant current source 67 by a smaller but constant amount.

The averaging circuit 3o generates a signal G which represents the threshold value for the input 19 of the test circuit 16 and is formed from an average value and an ejection rate.

The averaging takes place as follows: During the last part of each measurement (while a light transmitter 41a is on), the capacitor C _{1 is} connected to the output of the amplifier circuit (m output of the voltage follower 53) via the analog switch 6o and is charged to the voltage value that the Corresponds to the quality of the cigarette just tested. The voltage across the capacitor C ₂ corresponds to the mean value and was initially specified by the signal H. If the cigarette is found to be good after the evaluation of the measurement, the interposed analog switch 62 opens for a constant time. During this constant time, the mean value is approximated by a small part of the voltage difference of the capacitors C ₁ and C ₂ to the measured voltage at the capacitor C ₁ . This adjustable fraction of the voltage determines the proportion with which each individual can find the average value to be good.

wobei U₁ der Meßwert, U_2alt der alte Mittelwert vor Änderung durch U₁, Δ U₂ der Bruchteil, um den sich der Mittelwert an den Meßwert U₁ an - gleicht, und U₁ - U_2alt die Differenz zwischen Mittelwert und Meßwert ist. Um einen annähernd linearen Zusammenhang zwischen dem Verhältnis, mit dem der Meßwert den Mittelwert verändert und einer Veränderung des Widerstandes R zu bekommen, muß die öffnungszeit T viel kleiner sein als die resultierende Zeitkonstante τ_res.

für T << τ_res. Diese Mittelwertbildung entspricht einer arithmetischen Mittelwertbildung, bei der durch jeden neuen Wert der Mittelwert mit einem konstanten Faktor modifiziert wird.The relationship with which a single measured value is included in the mean is as follows:

where U _{1 is} the measured value, U _{2 is} the old mean before change by U ₁ , Δ U _{2 is} the fraction by which the mean adjusts to the measured value U ₁ , and U ₁ - U _{2 is} the difference between the mean and the measured value . In order to obtain an approximately linear relationship between the ratio with which the measured value changes the mean value and a change in the resistance R, the opening time T must be much less than the resulting time constant τ _res .

for T << τ _res . This averaging corresponds to an arithmetic averaging, in which the average is included with each new value is modified by a constant factor.

ergibt sich die größte Zeitkonstante bei kleinsten Kapazitäten, wenn C₁ = C₂ ist.Through the relationship for the resulting time constant

the greatest time constant results with the smallest capacitances if C ₁ = C ₂ .

für C₁ = C₂ =C.Then the calculation of the mean factor is simplified

for C ₁ = C ₂ = C.

If, for example, a ratio of 1: 100, i.e. averaging over 100 cigarettes in each case, is set with the resistor R, it is also desired at the same time that the cigarette blocks of the first 100 cigarettes are ejected. For this it is necessary to count the checked cigarettes with a counter, which is queried at the number 100. If you want to change the mean factor, you have to change the resistance R on the one hand and query the counter accordingly on the other.

In order to correctly measure these two values through an input, a resistor R controlled by a digital counter can be used. However, in order to ensure that the mean value from the second cigarette is already formed correctly, an R-2R network of a D / A converter 7o can be used instead of the resistor R, which is controlled by the counter 71, cf. Fig. 7.

During the measurement of the first cigarettes and only in this case, the two analog switches 6 ₀ , 62 are open. The R-2R network is set to 0 ohms by the counter 71. Both capacitors C ₁ and C ₂ are charged to the first measured value.

While the second cigarette is being measured, only the analog switch 6o controlled by the signal C is open and C ₁ is loaded to the second measured value. If the cigarette is found to be good, the

Analog switch 62 opened by signal D. The R-2R network is still 0 ohms. As a result, an average value is formed on the capacitor C ₂ , which corresponds to the first two measurements:

The index in brackets means the number of measurements. In the first measurement, U _{1 (1)} = U _{2 (1)} . The second measurement is the factor

When averaging with the third measured value, the R-2R network with the smallest value is switched on for the first time. The smallest resistance value must now reduce the mean value factor to 1/3 with the capacitors, so that the following results after n measurements:

The averaging must be limited to a desired number n, since there is no point in averaging over any number of measurements. If, for example, an average of over a hundred cigarettes is provided, the counter is counted up to 98 and from then on the resistance is kept constant. For the mean factor, this means that it changes from 1/1, 1/2, ... to 1/1 ₀₀ during the first hundred measurements and thus always forms the current mean (if you ignore the error that this causes comes about that with small ratios the function U _{2 =} f (t) is less linear because it runs over a larger part of the e-function). All other measurements than the 1 ₀ 1. have a constant mean factor of 1/1 ₀₀ .

If cigarettes recognized as poor do not influence the averaging, the statistical distribution of the measured values results in the mean value to the right of the maximum, as shown in FIG. 8, the mean value also being influenced by the setting of the potentiometer 35 for the ejection rate (below provided that the ejection rate is set to greater than zero).

This operating condition is usually satisfactory. However, the case can occur that with a high ejection rate and sudden change of the tobacco color towards the dark all cigarettes are recognized as bad due to the insufficient reflection. Then no measured value would influence the mean value, so that it cannot adapt to the new color of the tobacco. In order to prevent such a wrong reaction, it can be provided that the cigarettes recognized as bad also influence the mean value. This can be done in such a way that in the embodiment of FIG. 7 the constant current source 67 and the analog switch 66 controlled by the signal F are used.

Here, whenever a cigarette is recognized as bad by the test circuit 16, the analog switch 66 is opened by the signal F for a constant, very short time. During this time, a constant current flows into the capacitor C ₂ in a direction that the average is slightly lowered. Every bad cigarette (but no missing or broken one) reduces the mean by a small (adjustable) constant amount, no matter how bad it is.

This enables the device to adjust itself to such a dark tobacco color, in which the cigarettes are initially rated as bad, without having to use the measured values of the cigarettes recognized as poor for averaging. The constant amount by which the mean value is reduced can be set at the constant current source 67. Since the value of the constant amount is related to the mean value, this constant amount should not be chosen too large, in order to avoid an increased influence on the mean throw by bad cigarettes, but rather, for example, in accordance with the influence of the mean value by a good cigamte slightly below the mean value.

The device is also suitable for testing single cigarettes, in which case the dual multiplexer 11 is omitted and can be replaced by a simple circuit for the one input and output channel.

So that there is no double basic reflection on the plate 42, which could lead to an unfavorable ratio of signal to basic reflection, the plate 42 is to be arranged immediately in front of the reflection light barriers 41. In the event that the basic reflection is still too large, a plate 42 can be used which produces a diffuse reflection on the side facing away from the reflection light barriers 41, so that the proportion of light reflected from the glass surface, which forms the basic reflection, is reduced. The plate 42 can be milky there, for example, but in order to avoid contamination it must not have a rough surface since the cigarette ends lie there.

Claims (21)

1. Method for checking the degree of filling of cigarette ends with the aid of reflection light barriers (41), a threshold value being specified which is compared with the signal generated by the reflection light barrier (41) and which causes the cigarettes (43) to be rejected if the threshold value is undershot, characterized in that extraneous light compensation is carried out with respect to the signal generated by the reflection light barrier (41) by measuring the extraneous light falling on the reflection light barrier (41) when the light transmitter (41a) is switched off and by the signal of the reflection light barrier (41) from the measurement of the degree of filling is subtracted, and a self-check of the measuring device is carried out between two measurements of the degree of filling. 2. The method according to claim 1, characterized in that a second threshold value, which is lower than the first, is predetermined, the shortfall of which indicates missing or broken cigarettes (43). 3. The method according to claim 1 or 2, characterized in that when arranging a translucent plate (42) in front of the reflection light barrier (41) between two measurements of the degree of filling, the basic reflection on the plate (42) measured with the light transmitter (41a) switched on and with two a threshold value defining a window is compared, a stop signal being generated if the basic reflection is outside the window. 4. The method according to any one of claims 1 to 3, characterized in that the external light measurement is compared with a limit value, when it is exceeded, a stop signal is generated. 5. The method according to any one of claims 1 to 4, characterized in that a mean value is formed from a predetermined number of measurements of the degree of filling, which is used to form the threshold value for the degree of filling. 6. The method according to claim 5, characterized in that the mean value is changed by each new measurement of the degree of filling of a cigarette end above the threshold value to an extent corresponding to the predetermined number of measurements for averaging. 7. The method according to claim 6, characterized in that the mean value is changed by each new measurement of the degree of filling of a cigarette end below the threshold for the degree of filling and above the threshold for missing or broken cigarettes. 8. The method according to claim 7, characterized in that the mean value is decreased in each case by a constant amount which corresponds to a filling level below the threshold for the filling level and above the threshold for missing or broken cigarettes (43). 9. test device for the degree of filling of cigarette ends with one or more reflection light barriers (41), each consisting of a light transmitter (41a) that irradiates the end of the cigarette to be tested, and a light receiver (41b) that receives the light reflected from the end of the cigarette, and are connected to an evaluation circuit in which the signal generated by the light receiver (41b) is compared with a threshold value, characterized in that the evaluation circuit has a device for external light compensation (13) in which a measured value corresponding to the light received when the light transmitter (41a) is switched off stored and subtracted from a subsequent measured value with the light transmitter (41a) switched on and the ambient light-corrected measured value is fed to a test circuit (16) for comparison with the threshold value, and a device (17, 18, 42) for self-checking between two successive measurements and a clock generator (2o) for switching the light transmitter (41a) in succession. 1 ₀ . Test device according to Claim 9, characterized in that the device (13) for extraneous light compensation has a capacitor (51) which can be charged via an analog switch (52) which conducts during a phase (Ph1) during which the light transmitter (41a) is switched off and followed by a voltage follower (53), the capacitor (51) and the voltage follower (53) being arranged in the line (12) from the light receiver (41b). 11. Testing device according to claim 9 or 1 ₀ , characterized in that the device (17, 18, 42) for self-checking has a transparent plate (42) in front of or the reflection light barriers (41) and two test circuits (17, 18) in which the ambient light-corrected measured value are compared with an upper and a lower threshold value. 12. Test device according to one of claims 9 to 11, characterized in that a test circuit (15) is provided in which the ambient light-corrected measured value is compared with a threshold value, the shortfall of which indicates missing or broken cigarettes. 13. Test device according to one of claims 9 to 12, characterized in that an averaging circuit (30) is provided in which an average is formed from a predetermined number of measurements. 14. Testing device according to claim 13, characterized in that the averaging circuit (30) has a capacitor (C ₂ ), the charge of which represents the average and can be changed in a fraction in accordance with the predetermined number of measurements in accordance with the deviation from the average for each new measurement . 15. Test device according to claim 14, characterized in that a second capacitor (C ₁ ) is provided, the charge of which corresponds to the respective measurement and which is connected to the first capacitor (C ₂ ) for a period of time corresponding to the fraction corresponds to the specified number of measurements. 16. Test device according to claim 15, characterized in that the capacitor (C ₁ ) is only connected (in Ph3) with the capacitor (C ₂ ) after the respective measurement when the measured value exceeds the threshold value of the test circuit (16) Has. 17. Testing device according to one of claims 14 to 16, characterized in that a constant current source (67) is provided which, when the threshold value of the test circuit (16) is undershot and the threshold value of the test circuit (15) is exceeded, the charge of the capacitor (C ₂ ) reduced by a predetermined amount. 18. Test device according to one of claims 14 to 17, characterized in that the capacitor (C ₂ ) with an R-2R network of a D / A converter (7o), which is controlled by a counter (71), an RC Member forms. 19. Testing device according to one of claims 9 to 18, characterized in that when using a plurality of reflection light barriers (41) a double multiplexer (11), which works synchronously for light transmitter (41a) and light receiver (41b), is provided for the purpose of continuous Adjustment of the mean value when running through the first cigarettes up to the number over which the mean value is to be formed when the machine is started. 2 ₀ . Test device according to Claim 19, characterized in that the double multiplexer (11) connects the light transmitters (41a) to a constant current source (28) in the de-energized state. 21. Testing device according to one of claims 11 to 20, characterized in that the plate (42) in front of or the reflection light barriers (41) is arranged such that the cigarette ends to be tested when in contact with the plate (42) at a distance in Area of the falling part (K _ab ) of the curve (K) of the illuminance of the reflecting light plotted against the distance (d) of the cigarette end from the light receiver (41b).

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