WO2005066051A1 - Verfahren und vorrichtung zur berührungslosen detektion von flächigen objekten - Google Patents
Verfahren und vorrichtung zur berührungslosen detektion von flächigen objekten Download PDFInfo
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- WO2005066051A1 WO2005066051A1 PCT/EP2004/014640 EP2004014640W WO2005066051A1 WO 2005066051 A1 WO2005066051 A1 WO 2005066051A1 EP 2004014640 W EP2004014640 W EP 2004014640W WO 2005066051 A1 WO2005066051 A1 WO 2005066051A1
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- sheets
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H7/00—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles
- B65H7/02—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles by feelers or detectors
- B65H7/06—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles by feelers or detectors responsive to presence of faulty articles or incorrect separation or feed
- B65H7/12—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles by feelers or detectors responsive to presence of faulty articles or incorrect separation or feed responsive to double feed or separation
- B65H7/125—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles by feelers or detectors responsive to presence of faulty articles or incorrect separation or feed responsive to double feed or separation sensing the double feed or separation without contacting the articles
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H7/00—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles
- B65H7/02—Controlling article feeding, separating, pile-advancing, or associated apparatus, to take account of incorrect feeding, absence of articles, or presence of faulty articles by feelers or detectors
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2511/00—Dimensions; Position; Numbers; Identification; Occurrences
- B65H2511/50—Occurence
- B65H2511/51—Presence
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2511/00—Dimensions; Position; Numbers; Identification; Occurrences
- B65H2511/50—Occurence
- B65H2511/51—Presence
- B65H2511/514—Particular portion of element
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2511/00—Dimensions; Position; Numbers; Identification; Occurrences
- B65H2511/50—Occurence
- B65H2511/52—Defective operating conditions
- B65H2511/524—Multiple articles, e.g. double feed
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2515/00—Physical entities not provided for in groups B65H2511/00 or B65H2513/00
- B65H2515/10—Mass, e.g. mass flow rate; Weight; Inertia
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2553/00—Sensing or detecting means
- B65H2553/30—Sensing or detecting means using acoustic or ultrasonic elements
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2553/00—Sensing or detecting means
- B65H2553/40—Sensing or detecting means using optical, e.g. photographic, elements
- B65H2553/41—Photoelectric detectors
- B65H2553/412—Photoelectric detectors in barrier arrangements, i.e. emitter facing a receptor element
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2557/00—Means for control not provided for in groups B65H2551/00 - B65H2555/00
- B65H2557/20—Calculating means; Controlling methods
- B65H2557/24—Calculating methods; Mathematic models
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2557/00—Means for control not provided for in groups B65H2551/00 - B65H2555/00
- B65H2557/20—Calculating means; Controlling methods
- B65H2557/24—Calculating methods; Mathematic models
- B65H2557/242—Calculating methods; Mathematic models involving a particular data profile or curve
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2557/00—Means for control not provided for in groups B65H2551/00 - B65H2555/00
- B65H2557/30—Control systems architecture or components, e.g. electronic or pneumatic modules; Details thereof
- B65H2557/31—Control systems architecture or components, e.g. electronic or pneumatic modules; Details thereof for converting, e.g. A/D converters
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2557/00—Means for control not provided for in groups B65H2551/00 - B65H2555/00
- B65H2557/30—Control systems architecture or components, e.g. electronic or pneumatic modules; Details thereof
- B65H2557/32—Control systems architecture or components, e.g. electronic or pneumatic modules; Details thereof for modulating frequency or amplitude
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2701/00—Handled material; Storage means
- B65H2701/10—Handled articles or webs
- B65H2701/19—Specific article or web
- B65H2701/192—Labels
Definitions
- the invention relates to methods for the contactless detection of flat objects according to the preamble of claims 1 and 6 and devices according to the preamble of claim 47 and
- Methods and devices of this type are e.g. used in the printing industry to determine whether a single sheet or multiple sheets or a missing sheet is present in the printing and manufacturing process for paper, foils or similar flat materials.
- a single sheet e.g. of a double sheet
- such a double sheet is normally required to protect the printing press.
- the normal printing process is changed or interrupted until a single sheet is detected again.
- these methods and devices are also used in the packaging industry, in which, for example, labels applied to base or carrier material are counted or checked for the presence or absence of them.
- Another area of application is the detection of tear threads or tear points, particularly in the case of thin foils used as wrapping, such as cigarette packs.
- metal-clad papers, flat plastic sheets or foils and sheets can also be detected in manufacturing processes without contact using such methods and devices.
- the measuring principle used in a generic method and a device when using e.g. Ultrasound and the detection of paper in sheet-like form is based on the fact that the ultrasound wave emitted by the transmitter penetrates the paper and the transmitted portion of the ultrasound wave is received by the receiver as a measurement signal and its amplitude is evaluated. If a multiple or double sheet is present, the receiver has a significantly smaller amplitude than if a single sheet was present.
- a considerable disadvantage is that a corresponding teach-in step has to be carried out and taught in again for other flat objects with different grammages, which on the one hand is complex and on the other hand usually leads to considerable downtimes in the corresponding systems.
- DIN pocket book 118 (edition 2003-06), DIN pocket book 213 (edition 2002-12), DIN pocket book 274 (edition 2003-06), DIN-Taschenbuch 275 (edition 1996-08), or with regard to corrugated cardboard to DIN 55468-1.
- a device for the detection of single sheets or multiple sheets is known from DE 200 18 193 Ul and EP 1 201 582 A. To detect these arcs, this known device has at least one capacitive sensor and at least one ultrasonic sensor.
- an evaluation unit is provided for deriving a signal for the determination of the single-factor or multiple sheet. This signal is derived from a logical combination of the output signals of the sensors, the relevant detection signal being determined in an adjustment phase.
- Another device is known as a capacitive sensor from DE 195 21 129 Cl.
- This device which is primarily aimed at the contactless detection of labels on a carrier material, works with two capacitor elements and an oscillator influencing them.
- the dielectric properties of the paper or of other flat objects therefore influence the oscillating circuit of the oscillator with regard to the frequency, which is evaluated for detection.
- the disadvantage here is that relatively thin papers are difficult or impossible to detect, just like laminated papers. Even very thin foils are difficult to detect due to their small thickness and the dielectric constant, which in some cases differs only slightly from one.
- DE 203 12 388 U1 Another device of the type mentioned is known from DE 203 12 388 U1.
- This device which works with ultrasound, determines the presence and strength of the corresponding objects via the transmission and reflection of the radiation.
- this device also uses reference reflectors, so that the device has a relatively complex structure.
- DE 297 22 715 U1 discloses an inductively operating device for measuring the thickness of metal sheets, which can consist of non-ferrous metals or ferrous metals.
- the thickness of the sheets is measured by evaluating the working frequency of a frequency generator or by evaluating its amplitude.
- a teach-in step is first required, in which a calibration plate is introduced into the measuring space and the working frequency or the amplitude of the frequency generator is set according to a standard thickness curve.
- This device is also suitable for the detection of sheet thicknesses of up to approx. 6 mm.
- DE 44 03 011 Cl describes a device for separating non-magnetic sheets. For this purpose, it is provided that a traveling field inductor, when a double sheet is present, exerts a force which is provided opposite to the conveying direction of the sheet stack, so that the present double sheet is separated into two sheets. This device is completely unsuitable for non-metallic flat objects or foils.
- DE 42 33 855 C2 describes a method for checking and recognizing inhomogeneities in sheets. This method works optically and on the basis of a transmission measurement. However, especially when checking paper sheets with regard to single and multiple sheets, there is the problem that, due to the material properties of the sheets, very large fluctuations are caused due to inhomogeneities or the reflection behavior and the fluttering of the sheets. In order to overcome this problem, this document provides for a measurement evaluation using the fuzzy logic rules.
- a method that can be used in particular for counting banknotes, but also for other papers and foils, is known from DE 30 48 710 C2.
- This method which is based on the determination of the weight per unit area or the thickness of the materials to be detected, works with pulsed ultrasound waves, with the detection of a double sheet, ie the presence of two overlapping or overlapping bank notes, in particular the evaluation of the integration of the phase shift exercise is used.
- the field of application of this method is therefore primarily aimed at counting banknotes or comparable papers and foils, taking into account the basis weights of such materials. This method therefore appears unsuitable for use with packaging materials or counting labels.
- Comparable methods and devices are known in the field of application for the detection or counting of labels.
- the difference in a label can be seen here first, since it is provided on a base or carrier material as an applied material layer.
- this layered material behaves externally like a connected piece of material, so that with these detection options there is only a comparatively low attenuation, which, however, can still be evaluated.
- DE 199 21 217 AI together with DE 199 27 865 AI and EP 1 067 053 B1 discloses a device for detecting labels or flat objects.
- This device uses ultrasonic waves with a modulation frequency, a threshold value being used to differentiate between single and multiple bends during an adjustment process or a teach-in step is determined.
- the detection can be set on the special flat object in the sense of a label.
- this teach-in step makes the device more complex and requires longer setting times when changing to another flat object. This shows that a larger range of materials cannot be detected per se, but only in line with the specific individual material.
- the invention is therefore based on the object of conceiving a generic method and a device for the contactless detection of flat objects, the or ' which very flexibly and over a wide range of materials enables reliable detection of single, missing or multiple sheets with different flat materials on the one hand, in particular with papers, foils, sheets and the like, on the other hand with labels and similarly layered materials, whereby largely without teaching can be managed in one step and different beams or waves such as optical, acoustic, inductive or the like can be used.
- An essential core idea of the invention can therefore be seen in specifying a correction characteristic curve for the evaluation of the measurement signal over a grammage and basis weight range in order to achieve a target characteristic curve with a largely linear or almost linear course over the intended material range or also one of the papers and similar materials ideal characteristic curve for the detection of the single sheet to achieve approximate characteristic curve, which is a clear difference when the amplified measurement signal is being evaluated for amplitude tion, in particular with respect to a corresponding threshold value for air, as a threshold for a missing sheet or versus a threshold value for double sheets.
- a further important core idea of the invention is that when the received measurement signal is amplified, the correction characteristic of the corresponding signal amplification is specified statically or dynamically in order to achieve a target characteristic that can be easily evaluated.
- the invention also takes into account that an immediate conversion of the measurement signal can be carried out as part of an A / D conversion, the digital values obtained in this way being subjected to the measurement signal characteristic curve to the corresponding purely digital correction characteristic curve, so to speak, so to speak, the evaluable target characteristic curve to reach.
- This principle of using a correction characteristic also has the great advantage that different sensor devices, in particular as a barrier or barrier arrangement, e.g. in fork form can be used, whereby advantageously ultrasonic sensors, optical, capacitive or inductive sensors can be used, wherein the same method can equally be used for these sensors.
- sensor devices in particular as a barrier or barrier arrangement, e.g. in fork form can be used, whereby advantageously ultrasonic sensors, optical, capacitive or inductive sensors can be used, wherein the same method can equally be used for these sensors.
- the correction characteristic is chosen to be inverse or almost inverse to the characteristic of the input voltage U E of the measurement signal.
- the target characteristic curve that runs ideally for single sheet detection over a relatively large grammage or basis weight range of the objects to be detected, in particular between see 8 g / m 2 to reach 4000 g / m 2 .
- Inverse is seen as an inverse function.
- the method according to the invention is therefore not only suitable for the detection of single sheets, multiple sheets or missing sheets of thin to thick papers which are in the above-mentioned grammage range. Rather, stackable, box-shaped packaging made of paper or plastic or labels applied to carrier material, or adhesive, tear-off or tear-open points of paper or foils can also be detected.
- the corresponding correction characteristic which can also consist of a combination of several correction characteristics, is preferably impressed on the output side to obtain an easily evaluable target characteristic curve over the entire basis weight range for further evaluation.
- This target characteristic can then be used in a subsequent process step, e.g. can be realized in a microprocessor, the detection of the corresponding flat object takes place with regard to certain threshold values, so that a clear detection signal is obtained for single sheets, missing sheets or multiple sheets.
- the method also provides that the measurement signal or its measurement signal characteristic curve received in the receiver is subjected directly to an analog-digital conversion, these digital values taking into account a corresponding purely digital correction characteristic curve to a target characteristic curve with generation of a corresponding one Detection signals are processed.
- the advantage of these measures is that reliable detection of the corresponding flat objects over a very large grammage and basis weight area is reached without the need for a teach-in process, which would lead to system downtimes.
- the dynamic range of the evaluation device is expanded considerably, so that the detection of very thin or very inhomogeneous materials, which tend to flutter behavior, can be implemented with good certainty.
- the method according to the invention therefore makes it possible, on the basis of the amplitude evaluation of the measurement signal received in the receiver, by means of a correction characteristic and target characteristic, to reliably distinguish single sheets, missing sheets and multiple or double sheets, and this for very thin or very sound-transmissive objects, for example with a basis weight of 8 g / m 2 or approx. 10 ⁇ m thickness, up to relatively thick and strongly sound-transmissive objects up to 4000 g / m 2 , e.g. with a thickness of 4 mm, without a prior teach-in process differ.
- the invention also provides for correction characteristic curves to be taken into account, which represent a combination of different correction characteristic curves, these combined correction characteristic curves also only in sections over partial areas of the entire grammage range can be applied.
- the correction characteristic can also be used in sections as a linear or non-linear characteristic, as a single or multiple logarithmic characteristic, as an exponential characteristic, as a hyperbolic characteristic, as Polygon course, be designed as a function of any degree or as an empirically determined or calculated characteristic curve or as a combination of several of these characteristic curves.
- the correction characteristic it is preferred here to specify the correction characteristic as an approximately linearly increasing and weighting or exponentially or similarly increasing characteristic or as a logarithmic, multiple-logarithmic or similarly running nonlinear characteristic, also designed in combination with the first mentioned correction characteristics.
- the basis weight range for labels and similar materials can be set from approximately 40 g / m 2 to approximately 300 g / m 2 , that is to say is relatively narrow.
- labels may have slight grammage differences between the base or backing material and the multi-layer materials, such as e.g. Labels, a relatively small difference in damping, e.g. the ultrasonic waves are present, so that the aim is to achieve the greatest possible voltage swing of the target characteristic ZK in the target characteristic with a small voltage swing of the measured value characteristic MK.
- the correction characteristic for the detection of labels is therefore preferably at least linear, this linear correction characteristic KK having a weighting function, or is chosen to increase exponentially.
- evaluation is primarily carried out for the presence or absence of the multiple layers, or for the multiple layers reduced by at least one layer.
- the invention also allows such a combination of correction characteristics, e.g. can also be implemented in separate paths or channels.
- the logarithmic and / or double-logarithmic correction characteristic e.g. be embossed in the first channel so that primarily double sheet detection can be reliably achieved.
- the second channel can then e.g. with an exponentially or linearly increasing correction characteristic curve in order to be able to optimally implement the detection of labels, glue points or thread detection in this path.
- This combination of the two opposing methods with a logarithmic correction characteristic in combination with an exponentially increasing correction characteristic therefore creates an optimal detection possibility for labels and materials such as tear or tear points and / or tear threads and single, missing and multiple sheets ,
- the method of the correction characteristic curve for the detection of single, missing and multiple sheets is based on a configuration of the target characteristic curve, in which the entire curve
- the smallest possible change in the amplitude values, or dU z 0, is achieved, ideally a constant size or a target characteristic curve with a gradient of approximately 0.
- a linear signal amplifier can, for example, achieve a voltage-signal ratio of the order of 50: 1, which corresponds to approximately 34 dB.
- a logarithmic signal amplifier achieves a voltage-signal ratio of 3 ⁇ 10 4 : 1, which corresponds to approximately 90 dB.
- logarithmic and / or multiple logarithmic signal amplifiers can also be used in the method according to the invention and the corresponding device, so that the possible spectrum of materials is expanded to thin or very light arcs. This is due to the fact that with an increasing signal level in these signal amplifiers, the characteristic of the signal amplification saturates and there is practically no signal swing anymore.
- Another advantage of using nonlinear, in particular logarithmic and / or multiple logarithmic signal amplifiers is that the detectable material spectrum is expanded to thicker or heavier arcs. This results from the fact that with a low signal level the amplification is very high and even the weakest signals, which still penetrate a heavy or thick single sheet, are amplified sufficiently and can be evaluated. This property is used in particular for the detection of stacked packaging or also for the detection of single sheets, missing or multiple sheets.
- a further expedient development of the invention consists in that the correction characteristic curve is determined or calculated empirically, in particular empirically.
- the transmission attenuation or the resulting measurement signal voltage can be plotted as a function of the grammage or the basis weight of the object or objects to be detected, and in this way the characteristics of the measurement signal of a plurality of different objects can be determined and the optimal inverse or almost inverse correction characteristic curve can be computed or empirically created in order to achieve a target characteristic curve that is at least approximated to the ideal target characteristic curve for the detection of single sheets.
- a microprocessor for this control or regulation, a microprocessor, a corresponding electrical network for adjusting the correction characteristic, an additional application-specific component or a resistor network can be used.
- the target characteristic for different material spectra is divided into several sections, in particular three sections or five sections.
- a partial target characteristic curve for the grammage range above 1200 g / m 2 for very thick papers and another section below 20 g / m 2 for a very thin paper spectrum can be formed.
- the introduction of sections of the target characteristic curve therefore enables improved reliability with regard to single, missing or multiple sheet detection.
- At least one detection threshold For labels, adhesive and tear-off points or tear threads, it is expedient to specify at least one detection threshold, this being evaluated as a “multiple layer” when the detection threshold is undershot and as a “carrier material or as a multiple layer reduced by at least one layer”.
- the amplitude value is compared with threshold values on the basis of the target characteristic. These are in particular an upper threshold for air and a lower threshold for double or multiple sheets.
- the received measurement signal with the corresponding value of the target characteristic is greater than the upper threshold value, this is evaluated as a "missing sheet".
- a received measurement signal less than the lower threshold means a "multiple or double sheet”. In the case of a received measurement signal with the corresponding value on the target characteristic between the threshold values, this is detected as a "single sheet".
- the threshold values in particular for multiple sheets, can be defined continuously or in sections, or can be designed to be dynamic.
- a dynamic double sheet threshold can be used to further expand the measurable grammages.
- the single sheet value measured and with the associated multiple sheet value e.g. be evaluated as a polygon function if it is a simple function, e.g. a falling straight line or a constant value for the single arc.
- the method and the device can be implemented particularly well by means of at least one ultrasound sensor device.
- the sensor device preferably has at least one pair of coordinated and coaxially aligned ultrasound transducers.
- the method and device according to the invention can also be used with optical, capacitive or inductive sensors.
- the operating mode of the sensor device is expediently selectable or switchable as a pulse operation or continuous operation depending on the material spectra to be detected and the operating conditions.
- the pair of sensors In the case of continuous operation, it is preferable to mount the pair of sensors at an angle to avoid interference or standing waves using this measure.
- the continuous operation is expediently designed as a quasi-continuous operation, for example, in that the signal is switched off and on again periodically, in comparison with short periods of time compared to the evaluation time.
- phase jumps can also be provided in the transmission signal.
- the inclined mounting of the pair of sensor elements is particularly suitable for the detection of thicker materials, e.g. single-wall or multi-wall, in particular double-wall corrugated cardboard, in order to achieve better material penetration and to avoid interference.
- Two pairs of sensor elements in particular two ultrasonic sensors, can advantageously be used for the detection of incorrect, single or multiple layers of corrugated cardboard and their direction of transport.
- These ultrasonic sensors work in the detection of corrugated cardboard using the transmission method and the principle of correcting the characteristic curve.
- the two pairs of sensors are arranged orthogonally to one another.
- this sensor is preferably arranged at an optimal angle, based on the sheet normal of the corrugated cardboard, usually perpendicular to the largest surface section.
- An evaluation of the orientation or the transport direction of a corrugated cardboard designed as a single sheet can be realized by means of two sensors arranged orthogonally to one another, with one sensor always displaying a "single sheet” for a given transport direction, while the other always indicates “multiple sheets", in particular double sheets.
- the sensor arranged in the running direction of the corrugated cardboard would always display “single sheet”, while the sensor offset by 90 ° for this purpose would always display “multiple sheet”.
- This "multiple sheet” display results from the fact that with this corresponding alignment of the second sensor, no sufficient through-coupling of the sound energy can take place via the corrugated webs of the corrugated cardboard.
- the material spectrum of low grammages e.g. very fine and thin corrugated cardboard, so-called microwave cardboard
- large grammages or very large material thicknesses e.g.
- microwave cardboard for large grammages or very large material thicknesses, e.g.
- the first sensor e.g. according to the ultrasonic transmission method, and the principle of the characteristic curves - correction work -, while the second sensor would work according to the scanning principle.
- such an embodiment offers the advantage that the first sensor, which works on the principle of the correction characteristic, does not require a teach-in process and all mechanical materials which measure below the local resolution of the thickness second sensor lies, can be detected practically without exception.
- a local resolution of the thickness-measuring second sensor of approximately 0.3 mm to 0.5 mm is assumed.
- the second sensor which is expediently corrected with a metal bracket, therefore does not necessarily require a teach-in process, since it is due to the generous minimum resolution, e.g. 0.5 mm, missing, single and multiple sheets can be detected as layer height.
- Teaching-in of the second sensor can be dispensed with in the case, for example, if the distance from the second sensor to the material carrying floor material of the machine is known and if it is ensured that a single sheet is present for a defined minimum period when the machine is switched on.
- the transmission signal has also proven to be advantageous to modulate the transmission signal with at least one modulation frequency.
- Tolerances of the transducers can be corrected or compensated, in particular in the case of ultrasonic sensors.
- the sensor elements are matched to one another, they generally have different resonance frequencies. If a frequency sweep f s with a frequency significantly lower than the exciting frequency is used for frequency modulation, the resonance maximum of the sensor elements is periodically exceeded. If the response time of the sensor is significantly less than l / f s , the transducer properties of each individual sensor element or sensor pair can be optimally used for ultrasound transmission in this way.
- the * frequency sweep will normally be up to some 10 kHz.
- the tolerances of the sensor elements are expediently corrected automatically before or during operation. This is done by normalizing the sensor element pairs to a fixed value at a predetermined fixed distance, in particular the optimal mounting distance. As a result, bad sensor elements are made better and good sensor elements or transducers are made worse. A correction factor is necessary to compensate for this. According to the method, this can be done by using a straight line which is stored or calculated as value pairs in the microprocessor, since the measurement signal is already with e.g. a simple logarithmic correction characteristic is evaluated and the correction characteristic generates an approximately linearly falling target characteristic over the transducer or sensor element distance. That the input signal at the microprocessor of an evaluation device drops linearly with the transducer distance in a good approximation.
- the correction of the values is easy even with a variable distance, since when a corresponding device is switched on, only a straight line function for the correct initial value has to be calculated or stored as a pair of values.
- the correct determination of the sensor head distance is carried out by running time measurement.
- the method according to the invention is advantageously further developed in that not only one sensor of a particular one Type, for example an ultrasonic sensor or an optical sensor, are used, but that different sensors are combined with one another depending on the specific criteria of the flat objects to be detected.
- a particular one Type for example an ultrasonic sensor or an optical sensor
- one sensor device can consist of several sensors of the same type, such as Ultrasonic sensors with transmitter and receiver exist.
- the sensor device can have several sensors in a line, preferably transversely to the running and conveying direction of the flat objects.
- a sensor device attached in the longitudinal direction of the conveyed flat objects with several sensors connected in series, of the same or different type, is suitable.
- a sensor device with ultrasonic sensors and a upstream or downstream sensor device with optical sensors are recommended in particular for the detection of paper sheets and such materials.
- the type-specific sensor devices are preferably used with different correction characteristics.
- Digitization by analog-digital conversion of the measurement signals at the output of the individual sensors with subsequent digital evaluation in the evaluation device or a microprocessor is also expediently possible.
- the evaluation of individual sensors, but especially different sensor devices with different types of sensors, is suitably carried out via separate channels.
- bus lines can be provided, for example, which feed the corresponding signals to the evaluation device with a microprocessor.
- optical sensors are particularly suitable, in which the light intensity I in cd is recorded as the received signal or ultrasonic sensors with the detection of sound pressure p in Pa.
- Capacitive sensors in which the change in the capacitance C in F or the frequency f in Hz of the signal voltage U is determined, are particularly suitable for very thin and transparent sheets, that is to say materials which are very optically and acoustically permeable.
- Inductive sensors in which the magnetic flux Phi is determined in the size A / m, are suitable for a large range of materials, but in particular for metallic objects, e.g. Sheet metal sheets, can be used advantageously.
- a sensor device based on ultrasonic sensors which is combined downstream with mechanical, capacitive, optical and / or inductive sensors, is particularly suitable for simple, faulty or multiple material detection.
- the signals detected in the individual different sensor devices and fed to one or more evaluation devices are logically linked, for example by means of an AND / OR link, so that incorrect detection signals can be excluded for the presence of single or multiple sheets.
- Selection and evaluation of output signals from various sensors can also be carried out to determine the detection signal.
- a teach-in process or a teach-in step can also be provided, by means of which threshold values for the subsequent determination of the detection signal or digitized values, also for the logical connection of the output signals, are determined and defined.
- a combination of a sensor device with ultrasonic sensors together with inductive sensors is particularly suitable for the detection of very thin to very thick metal sheets, with reliable detection of single, missing or double sheets being made, in particular taking into account a logical combination of the corresponding output signals can.
- the construction of the sensor device in particular with ultrasound sensors, can advantageously take the form of a fork.
- the transmitter and receiver are coaxially opposite in their main radiation direction. Cylindrical housings can also be used here.
- the sensor device with transmitter and receiver e.g. be soldered or glued to a printed circuit board, the sheets to be detected being guided in the free gap between the transmitter and receiver.
- a particular advantage of the method using ultrasound can be seen in the fact that the distance between transmitter and receiver in the sensor device can be configured variably for this teach-in-free method.
- the sensor device can be used in different applications With regard to their spacing, they can be adjusted relatively quickly without the measuring precision of the method being impaired.
- a further improvement of the method can be brought about by monitoring the distance between transmitter and receiver and determining it. This determination of the distance between the transmitter and the receiver can be achieved on the one hand by reflection of the radiation between the transmitter and receiver and on the other hand by means of reflection between the transmitter and receiver despite a flat material present in the space, even a thick sheet. If it is determined that the permissible maximum sensor distance has been exceeded, the evaluation device, for example a microprocessor, can carry out a corresponding correction of the determined amplitude values of the measurement signal depending on the distance between the transmitter and receiver.
- the transmitter and receiver are aligned with one another in the main radiation direction, in particular coaxially, with one another, with almost any angle of inclination to the plane of the arc being able to be provided.
- a method can also be used to provide feedback between the transmitter and the evaluation device, in particular a microprocessor, in order to obtain a maximum amplitude at the output, taking into account the material specification of the flat objects to be examined and other operating conditions. It is also possible to regulate the optimum transmission frequency. With this measure, aging effects of the sensor elements can also be compensated for and a product test of the device according to the invention, in a particularly advantageous embodiment of the invention, can be fully automated during series production.
- a feedback is provided between the evaluation device and the transmitter, by means of which the amplitude of the received measurement signal can be maximized. It is also preferred to provide a self-alignment between the transmitter and the receiver with regard to an optimal transmission frequency and / or amplitude. This self-adjustment can be carried out in times synchronized with the transmission frequency, in defined pause times or also via a separate input provided externally on the sensor device.
- the activation and selection of the corresponding channels and signals is preferably carried out via time-division multiplexing devices.
- At least one aperture and / or slit diaphragm between the transmitter and the elongated object to be detected to provide spatial resolution and to continuously detect the presence of the object.
- Tear-open threads in packaging foils for cigarettes are arranged in the thread running direction, and in particular the slit diaphragms. This is usually an arrangement of the aperture by 90 ° to the direction of the elongated objects.
- slit or perforated diaphragms are aligned by 90 ° to the direction of movement of the sheets.
- the elongated object guided between the transmitter, receiver and diaphragm e.g. a thread laminated onto a carrier material, hovering as close as possible over the screen or slidingly touching it.
- the arrangement of the transmitter especially in the case of ultrasound sensors, is advantageously carried out below the sheet to be detected, since in this case the maximum transmission energy can be coupled out and self-cleaning effects on the sensor head can be used.
- FIG. 1 shows the principle of a method according to the invention and block-like a corresponding device including voltage diagrams according to Figures la, lb, lc, which illustrate the structure of the characteristic curves in the detection of sheets of paper, foils or similar materials.
- FIG. 2 shows the principle of a method according to the invention and a corresponding device in block diagram form, including voltage diagrams according to FIGS. 2a, 2b, 2c, 2d, which illustrate the structure of the characteristic curves in the detection of labels, tear-open points and similar materials;
- 3a shows a curve diagram which shows the schematic dependency of the output voltage of an amplifier, as shown by way of example in FIG. 1, as a function of the grammage or the basis weight of materials to be detected, idealized target characteristics being included;
- Fig. 3b is a schematic diagram analogous to Fig. 3a with the output voltage of an amplifier as a function of the grammage or the basis weight of the materials to be examined, with several target characteristics together with corresponding threshold values, e.g. Air threshold, double arch threshold are shown;
- threshold values e.g. Air threshold, double arch threshold are shown;
- 4a shows a schematic representation of how the correction characteristic curve can be determined in the Cartesian coordinate system in the case of a known measured value characteristic curve and ideal target characteristic curve for single or double sheet detection;
- 4b shows a schematic illustration, based on the label recognition with ideal target characteristic curve, known measured value characteristic curve and a correction characteristic curve required for transformation
- Fig. 4c is a schematic representation of the characteristics
- Double sheet detection if there is no ideal target characteristic; 4d shows characteristic curves for double sheet detection with reflection on an imaginary axis, including the transformation according to FIG. 4f;
- FIG. 4e shows a schematic illustration of characteristic curves for label recognition with reflection on the imaginary axis, taking into account FIG. 4f;
- 4g shows a schematic representation of the ideal target characteristic and real target characteristics in double sheet detection
- 4h shows a schematic representation of an ideal target characteristic and a realistic target characteristic for label recognition
- 4j shows a schematic representation of a measured value characteristic derived from a weighted hyperbola and a correction characteristic derived from a logarithmic function with the target characteristic determined therefrom for single or double sheet detection
- 5a is a schematic illustration of the principle of the measurement criteria present as an example in the detection of a double sheet of material by means of ultrasound waves;
- FIG. 5b in a manner comparable to that in FIG. 5a, the schematic representation of an adhesive point between a double sheet of material and the measurement criteria that arise in this case when recorded by means of ultrasound;
- 5c shows the schematic representation of materials adhered to a base or carrier material, partly as single-layered and partly as multi-layered materials, this structure showing the structure of a label
- FIG. 6 shows the method and a device in the form of a block diagram using the example of a combination of different correction characteristic curves
- FIG. 7 shows a schematic illustration similar to FIG. 6, the principle for the setting of a correction characteristic curve and the calculation of a correction characteristic curve having a reaction on the circuit blocks being shown;
- 9 shows a schematic block diagram representation of a method or the corresponding device with the combination, for example, of multiple sheet detection with the detection of material layers or labels adhered to carrier material; 10 schematically shows a diagram of the standardized output voltage U A over the grammage range with constant or dynamic double arc waves,
- FIG. 12 with the representations of Fig. 12a, 12b and 12c the arrangement of a sensor with optimal alignment with a single-wall corrugated cardboard, Fig. 12a, and corresponding to Fig. 12b, the analog alignment of a sensor with double-wall corrugated board and according to Fig. 12c schematic representation of the arrangement of two sensors for detecting the running direction of a sheet of corrugated cardboard,
- Fig. 13 is a plan view of the diagram of a device with two sensor devices and
- FIG. 14 shows a vertical section through the device according to FIG. 13 in the region of the two sensor devices.
- the diagram according to FIG. 1 shows schematically the method according to the invention and a device with a block-type structure and the voltage curves that can be achieved at certain points in the sense of characteristic curves over a grammage or basis weight range g / m 2 of a material spectrum to be detected.
- a corresponding sensor device 10 has, on the one hand, a transmitter T and an aligned, opposite lying receiver R, between which the flat objects to be detected, in the example in the form of an arc, are moved without contact.
- a multiple sheet as double sheet 2 is shown as an example.
- a possible voltage curve U M is dependent on the grammage or the basis weight g / m 2 for the measurement characteristic MK shown in FIG.
- the aim of the invention is to take into account threshold values, such as e.g. for the air threshold or as a double-arch threshold, to obtain clear intersections with these threshold values or the largest possible voltage distances from these threshold values.
- the principle according to the invention is therefore to take into account a correction characteristic curve and to impress this, for example, on the evaluation circuit following the receiver, for which purpose the following amplifier device is particularly suitable for using to achieve a target characteristic that can be easily evaluated for the desired grammage range for reliable detection by deciding whether a single sheet, no sheet or a multiple, in particular double sheet, is present.
- Such a correction characteristic KK is shown in Fig. lb shown schematically.
- This correction characteristic curve which only shows in principle the dependence between the output voltage U A and the input voltage U E in FIG. 1b, illustrates in comparison with the measurement characteristic curve MK according to FIG. 1 a, which likewise only shows the course of the measurement signal schematically
- U M shows that relatively high tension values U M seen over the grammage range experience no or only a slight gain, while smaller tension values, for example with relatively large basis weights (g / m 2 ), experience a significantly higher, possibly exponential gain.
- the resulting target characteristic curve ZK with the voltage U z as a function of the grammage (g / m 2 ) is also only shown schematically in FIG. 1c.
- the desired target characteristic ZK can also be transformed from a point-by-point mapping of the measurement signal U M to the desired output signal U s and the desired target characteristic ZK can thus be achieved. This requires an amplifier with adjustable gain, which then receives the correction characteristic from a microprocessor.
- the measurement signal U M can be mapped to the desired output signal U z on the basis of the correction characteristic KK, instead of being value-discrete or point-by-point also continuous.
- This target characteristic curve shown in FIG. 1 c could have, for example, the curve shown by the solid line, which has three areas. A first and a third relatively steeply sloping area and a middle area, which is inclined only relatively slightly to the abscissa and which comprises a large grammage area. Since the first and the third area could show a more optimal course with regard to a reliable detection display or unambiguous switching behavior of the device, a linearly decreasing target characteristic ZK2 going through the end points of the first target characteristic ZK1 is shown with an interrupted line as an improved target characteristic.
- the measurement signal U M received at the receiver R is fed to an evaluation device 4.
- the evaluation device 4 is shown in a simplified manner with the amplifier device 5 and downstream of a microprocessor 6.
- the correction characteristic KK is specified or impressed in the amplifier device 5, so that the target characteristic ZK1 or ZK2 is obtained at the output for further evaluation in the microprocessor 6.
- the microprocessor 6 can then, taking into account stored or dynamically calculated data, such as threshold values, generate a corresponding detection signal with regard to single sheets, missing sheets or multiple sheets, in particular double sheets.
- FIGS. 2a, 2b, 2c, 2d schematically show the method and a device for the detection of labels and similar materials without a teach-in step having to be carried out.
- the reference symbols here correspond to the reference symbols from FIG. 1.
- the block-circuit-like structure shows a transmitter T, for example for the emission of ultrasonic waves, and an assigned receiver R as sensor device 10. Labels 7 are passed between transmitter T and receiver R.
- the aim of the device is therefore on the one hand to recognize whether labels or no labels are present. On the other hand, it is also possible to determine the number of labels passed through the sensor device.
- the measurement signal U M or U E obtained when a label is present in the receiver R can, for example, have the schematically indicated course of the characteristic curve over the grammage, with a course that declines in a linear, non-linear, exponential or similar manner.
- the following evaluation device which e.g. can have an amplifier device 5 and a microprocessor 6 connected downstream, receives a correction characteristic in the amplifier 5, which e.g. linearly increasing (I.) or exponentially increasing (II.) as shown in FIG. 2b.
- a correction characteristic in the amplifier 5, which e.g. linearly increasing (I.) or exponentially increasing (II.) as shown in FIG. 2b.
- the correction characteristic e.g. a target characteristic over the grammage range as shown in FIG. 2c by the curve shape I or II.
- This target characteristic ZK ! has the course of a negative falling straight line, from smaller grammages to larger grammages, whereby optimally a constant slope and a maximum voltage difference for the output voltage U z with small grammage differences should be achieved over the entire grammage or basis weight range intended for the detection of labels.
- correction characteristic curve KK can also be a combination of individual different characteristic curves.
- Other correction characteristic curves such as logarithmic or multiple logarithmic values, can also be used depending on the characteristic curve profile of the measurement signal U M and the gain characteristic curve. The aim here is to achieve an ideal characteristic Z i, as shown in FIG. 2, if possible.
- the output voltage U A of an amplifier device over the grammage range is shown in a schematic representation in FIG. 2 d with an exemplary course of a measured value characteristic MK E for a label and the target characteristic ZK E , as is taken into account with a correction impressed on the amplifier.
- Characteristic curve KK can be reached. The illustration applies to the recognition of labels or glue points.
- the measured value characteristic MK E is transformed by means of a suitable correction characteristic KK.
- every point of the measured value characteristic MK E is transformed continuously or discreetly in digital systems into a corresponding value on the target characteristic ZK E. This is illustrated by the arrows for clarification.
- the amplifier voltage can very easily be in the saturation range.
- the use of foils for labels can also quickly reach the limit range of the amplifier for noise, since foils vaporize very strongly.
- the method of correcting the characteristic curve can be used particularly advantageously, so that saturation of the measurement signal is avoided in the case of very thin and strongly damping materials, as a result of which ultimately a flawless detection of the presence or absence of labels is guaranteed.
- FIG. 2d also shows a possible course of the measured value characteristic MK DB for a double sheet, which approaches the double sheet threshold DBS approximately asymptotically in the upper grammage range.
- FIG. 3a shows a schematic representation of the basic dependency of a standardized output voltage signal U A / pu of a signal amplifier as a function of the basis weight or the grammage (g / m 2 ) in the case of differently designed signal amplifiers for single and multiple sheets, especially double sheets.
- the line I in FIG. 3a symbolizes a largely idealized course in the output voltage of single sheets as a function of the grammage when using an approximately linear signal amplifier 5, with an approximately exponential drop in the voltage line.
- This voltage characteristic I does not take into account any correction characteristic KK.
- the target characteristic curve II thus symbolizes a characteristic curve for the output signal for single sheets when using a logarithmic signal amplifier, the target characteristic curve II exhibiting an approximately linear drop.
- the air threshold and, on the other hand, the double arc threshold are entered as examples in the diagram according to FIG. 3a.
- the intersections of the target characteristic curve II 3a with the air threshold or the double-arch threshold show a sufficiently large slope around a defined, relatively small material area.
- This ideal target characteristic is marked I in Fig. 3b.
- curve Ia which shows a multiple arc signal, in particular a double arc signal when using an approximately linear signal amplifier, curve Ia having an approximately double-exponential drop in the multiple arc characteristic.
- the curve Ila which is also shown by way of example, symbolizes a multiple arc signal, in particular a double arc signal, with a logarithmic correction characteristic curve, as a result of which an approximately exponential drop in the multiple curve characteristic curve Ila is achieved.
- 3b shows several target characteristics of single sheets with the representation of the normalized output voltage U A / pu of the signal amplifier as a function of the grammage or area. weight (g / m 2 ) when using different signal amplifiers.
- the top horizontal line with a broken line marks the saturation limit or maximum supply voltage for a signal amplifier used.
- the threshold value for air or a missing sheet is shown as an example at about 0.7 U A / pu. At a value of U A of approximately 0.125, the double arc threshold and, below that, the threshold for the noise of electrical signal amplifiers are shown as examples.
- the horizontal line I in Fig. 3b indicates an ideal target characteristic for single sheets.
- This ideal target characteristic shows no saturation for thin materials and is at a high distance from the noise threshold or the double-arc threshold.
- This ideal target characteristic curve means that the output voltage U A of the signal amplification would ideally result in a constant signal if a wide variety of grammages or basis weights were entered.
- Curve II shows a non-linear target characteristic with two branches Ila and Ilb, which is relatively difficult to implement due to the turning point, but can be regarded as a characteristic approximating the ideal target characteristic I for single sheets.
- the area Ila for lighter grammages can be advantageously implemented via an almost linear signal amplification.
- the area Ilb for heavier grammages can, for example, by means of a double logarithmic see signal amplification can be realized, whereby the sharp downward kink due to the damping properties of papers with very high grammage proves to be too complex in the technical implementation.
- Curve III represents a target characteristic curve which approximates the end points of curve II in the simplest way by means of a 2-point straight line connection to an ideal course as shown in curve I.
- This can be achieved by using a minimum of simple logarithmic signal amplifiers and shows the linearization of the measured values for single sheets over a large grammage range taking into account a corresponding correction characteristic.
- Curve III has clear passages for the threshold values for air or for a double sheet, so that there are clear switching points and detection criteria in relation to these threshold values.
- Target characteristic curves according to curves I, II and III therefore allow unambiguous detections over a material spectrum that is broadened compared to the prior art.
- Curve IV which is also shown, shows an unsuitable target characteristic for single sheets.
- Such an asymptotic course should also be avoided with respect to the switching thresholds for air or for double arcs, since a clear distinction of the states, missing arcs or double arcs, would then be problematic because of the small signal differences to these thresholds.
- the steep drop in curve IV in the middle area covers only a small grammage area with a clear distinction from missing sheets or double sheets. Since, according to the invention, the target characteristic curve over a very large material spectrum provides unambiguous detection for single sheets, A curve according to curve IV should be avoided if a missed or double sheet is to be permitted.
- FIGS. 1, 2, 3a and 3b therefore show that when evaluating the received measurement signal, a signal strengthening is used, which is given a correction characteristic curve, which depends on the characteristic curve of the output voltage U A / pu reproduces the grammage of the flat objects inversely or almost inversely over a large grammage range or the ideal characteristic curve approximating the ideal characteristic curve for single sheet detection in a suitable manner.
- a linear or almost linear dependency is achieved between the measurement signal U E received by the receiver and the signal voltage U A at the output of the signal amplifier.
- FIG. 4a schematically shows in the Cartesian coordinate system with the material spectrum g / m 2 on the abscissa and the percentage signal output voltage U A on the ordinate an exemplary course of a measured value characteristic MK DB for the detection of single or double sheets.
- the required correction characteristic KK DB is also shown for this example. From this it can be seen that first the points of the measured value characteristic MK are transformed in the direction of the arrows P downward and then for larger grammages a transformation upward in order to achieve the ideal target characteristic ZKi for single sheet detection.
- the example according to FIG. B shows corresponding courses of the characteristic curves for labels.
- the measured value characteristic MK E is shown as an example with a solid line.
- the ideal target characteristic ZK E represents a straight line with a negative slope or high stroke.
- the correction characteristic KK E required for the transformation is shown with a broken line and points in this In this case, there is a point of discontinuity at the intersection between the measured value characteristic MK E and the target characteristic ZK E.
- FIG. 4c schematically shows the course of the characteristic curves for single or double sheet detection for a case in which not the ideal target characteristic, but a real target characteristic ZK DBr is achieved.
- the real target characteristic ZK DBr therefore has a stroke H DBr / which is greater than 0.
- the drawn-in measured value characteristic curve MK DB could be transformed into the target characteristic curve ZK DBr by impressing, for example, the correction characteristic curve KK DB as an upper, continuous line. This transformation is indicated by the arrows P.
- the diagram according to FIG. 4d schematically shows the transformation of a measured value characteristic MK DB for single or double sheet detection to the desired target characteristic ZK DB .
- the abscissa marks the material spectrum g / m 2 , the realistic measuring range M DBr being indicated.
- the signal output voltage U A of the measured value is indicated as a percentage on the ordinate. This corresponds approximately to the attenuation measure dB.
- the virtual end points E1 and E2 are shown as imaginary intersections of the measured value characteristic MK DB with the target characteristic ZK DB .
- measuring value characteristic MK DB in the double sheet detection of a linear target characteristic ZK DB is a correction characteristic KK DB necessary to achieve, as in broken line between the end points El and E2 shown.
- the measured value characteristic MK DB is transformed in the direction of the arrows to the real target characteristic ZK DB . This is achieved, so to speak, by mirroring the measured value characteristic MK DB on the ZK D B axis after coordinate transformation.
- FIG. 4f This coordinate transformation from the Cartesian coordinate system into a new coordinate system x 1 , y 'is shown in simplified form in FIG. 4f.
- the further representation according to FIG. 4e schematically shows the transformation of the measured value characteristic MK E for labels into the desired, ideal target characteristic ZK E by means of the required correction characteristic KK E.
- the correction characteristic KK E can be achieved by mirroring MK E on the axis of the target characteristic ZK E after the coordinate transformation (see FIG. 4f).
- the coordinate transformation shown in FIG. 4f shows, in a simplified manner, the shift for a rectilinear coordinate system x, y by an angle ⁇ .
- X, y are, for example, the axes of the Cartesian rectilinear coordinate system.
- the new coordinate reference system is specified by the imaginary reference axis of the target characteristic curves ZK DB or ZK E through the coordinate transformation.
- the arrow in the diagram indicates the transition from the ideal target characteristic ZKi to real target characteristics, e.g. ZKi or ZK 2 .
- the ideal target characteristic Ki for label recognition here has a maximum stroke Hi over a relatively large range of the material spectrum, which is characterized as the ideal material spectrum Mi.
- Real target characteristics ZKi in label recognition deviate from the ideal target characteristic ZKi. in the direction of the arrow. Accordingly, the more realistic target characteristic ZK X has a smaller stroke Hi and also a smaller material spectrum Mi.
- 4i and 4j exemplarily show measured value characteristic curves and correction characteristic curves and target characteristic curves derived therefrom.
- the correction characteristic KK has the function
- the target curves ZKi and ZK 2 shown can therefore be derived essentially from the difference from the measured value characteristic MK and the correction characteristic KK.
- the example according to FIG. 4j also schematically shows characteristic curves for single or double sheet detection.
- the measured value characteristic curve MK is approximately derived from a weighted hyperbola.
- Characteristic curve KK is a correction characteristic curve derived from a logarithmic function.
- the measured value characteristic MK can be transformed into a target characteristic ZK, taking into account the correction characteristic KK, which approximately corresponds to an ideal target characteristic for single or double sheet detection.
- 5a, 5b and 5c are some basic principles of the method according to the invention and the corresponding device using the example of an ultrasonic sensor device and the essential physical differences for clear detection using a double sheet, a double sheet with adhesive and using the example of labels briefly explained.
- FIG. 5a schematically shows the overlap of two single sheets, so that one can speak of a double sheet 11 in the overlap area.
- This double sheet 11 is to consist of two sheets of paper, the space between the two single sheets being a medium different from their material. Since contactless detection is provided, it can be assumed that air with the parameter Z 0 is present on both sides of the double sheet and also the intermediate medium in the overlap area of the single sheets of air with Z is 0 , which is present as an air cushion due to the surface roughness of the materials in this double sheet.
- the direction of action of the measuring method e.g. by means of ultrasound, is perpendicular to the double sheet region in the example, so that a transmitted ultrasound signal in such a "real double sheet" becomes very small due to the multiple refraction over at least three interfaces, i.e. the transmission factor ideally approaches zero over three layers.
- a double sheet or multiple sheet can therefore be regarded as a material structure which has a sheet stratification or a box stratification and in one of the spaces between the sheet stratification there is at least one medium, in particular air, which differs from the different sheet materials and which is related to the sheet materials has a clearly different acoustic resistance in the case of an ultrasound measurement method and thus leads to signal reflections.
- the signal attenuation due to signal refraction and reflection is so great that the transmitted signal is attenuated disproportionately.
- Such a double sheet also includes a connection of sheets that is not designed to be adhesive, e.g. by means of a mechanical interlocking or fluting of arches, since the corresponding intermediate medium would also be air. This consideration also applies to multiple sheets in which three or more individual layers of sheet materials are stacked on top of one another.
- FIG. 5b schematically shows a double sheet 12 with an adhesive point 13.
- the direction of action of the measuring method used, again using ultrasound, is indicated by arrows.
- the point of glue is considered to be blunt, more or less overlapping or such connections of sheets, in particular sheets of paper, plastics, foils and fabrics (nonwovens).
- the connection takes place predominantly by means of at least one partial or full surface adhesive medium, in particular by means of adhesive and adhesive strips or adhesive provided on one or two sides.
- an adhesive point for a method using ultrasound means an "acoustic short circuit" through which layer of adhesive material which fills the space between the upper sheet Z x and the lower sheet Z 2 and connects them intimately, air above and below the single sheet with Z 0 Is accepted.
- a glue point could therefore be detected in the detection method using ultrasound essentially as a single sheet with a high grammage.
- 5c schematically shows two embodiments of labels 15, 17.
- label is understood to mean at least one or more layers of material or layers of material adhering to a base or carrier material.
- the layered material behaves like a connected piece of material, for example with regard to sound transmission to the outside, so that in some cases there is no significant damping of the respective physical quantities, but only a comparatively low, but still evaluable damping. Possible inhomogeneities in the carrier material or applied material are not taken into account in this consideration, since a faultless material can be assumed in particular for labels.
- the label 15 has an upper material with the parameter Z 2 applied to a carrier material by means of an intimate adhesive bond. There is air with parameter Z 0 on both sides of the label. As a result of this intimate adhesive connection, there is an acoustic short circuit between the materials in a detection method by means of ultrasound, so that there is an analogy to glue points according to FIG. 5b.
- FIG. 6 schematically and in block-like fashion shows a device for missing, single and multiple sheet detection, the correction characteristic being generated as a combination of individual characteristics.
- the sheet materials or sheets to be detected are guided between the transmitter T and the receiver R.
- the correction characteristic curve resulting after the amplifiers is realized in the example with a first correction characteristic curve in the amplifier device 21 and at least one second correction characteristic curve in the amplifier device 22, which is connected in parallel.
- the measurement signal present at the output of the receiver R or its characteristic curve over the grammage is therefore a combined correction characteristic subjected in order to obtain an easily evaluable target characteristic curve 23, which is further evaluated in a microprocessor 6.
- correction characteristic curve can therefore be implemented in a wide variety of ways, since the essential basic idea of the invention is to carry out a detection of single sheets, missing sheets or multiple sheets, and this over a large grammage range without having to integrate a teach-in process ,
- FIG. 7 shows the schematic and block-circuit-like structure of a modified device for realizing the invention.
- the measurement signal of the receiver R is subsequently passed to an amplifier device 24, the signal output of which is directed to a microprocessor 6.
- the microprocessor 6 allows a predetermined correction characteristic to be set via the symbolized potentiometer 25 via the feedback in path A.
- a corresponding correction characteristic curve is calculated by means of the microprocessor 6 and the data received or stored and is fed back and impressed on the amplifier device 24 via the path B.
- the determined correction characteristic curve C can be impressed discreetly or continuously over the path B of the amplifier device 24, or the evaluation of the amplified output signal can be carried out directly in the microprocessor 6 on the basis of the correction characteristic curve C.
- the empirical determination of a measurement signal characteristic is shown in a schematic representation in FIG. 8. For this purpose, a large number of materials customary on the market are passed between the transmitter T and the receiver R and the corresponding measurement signal characteristic curve is determined. Usually, the measuring range will be determined by introducing the thinnest sheet material A available and the thickest sheet material B to be detected.
- the measurement signal characteristic curve determined in this way can then be sent to the further processing system, e.g. a microprocessor, in order to determine a largely optimal correction characteristic curve for this measurement signal characteristic curve in order to achieve the required target characteristic curve.
- the further processing system e.g. a microprocessor
- FIG. 9 schematically shows a device 40 according to the invention for the contactless detection of multiple sheets A, without carrying out a teach-in step, and for the detection of material layers B adhered to a carrier material, e.g. Labels.
- a carrier material e.g. Labels.
- An important idea here is to forward the measurement signal evaluation for multiple sheets to a separate channel A with a corresponding correction characteristic curve and, in parallel, to feed the measurement signal evaluation for labels B to a separate channel B with an adapted correction characteristic curve.
- the measurement signal obtained at the output of the receiver R is therefore switched to the corresponding channel A or channel B via a multiplexer 34 controlled by the microprocessor 6.
- the signal amplification in channel A is subject to a separate correction characteristic with an optimal design for multiple sheet detection.
- the signal amplification in channel B is subject to a correction characteristic for the label measurement signal.
- Both channels A, B are fed via a subsequent multiplexer 35, which is also microprocessor-controlled, to the downstream microprocessor 6 for further evaluation and detection of multiple sheets or labels.
- This device 40 is suitable both for the detection by means of ultrasonic waves.
- the main advantage is the The aim was to include the most suitable correction characteristic curves for the fundamentally different measuring tasks, namely for the most diverse types of material, such as multiple sheets and labels in the present case, for evaluation.
- FIG. 10 schematically shows a diagram of the normalized output voltage U A in% as a function of the grammage.
- the target characteristic curve 42 of a single sheet is entered with logarithmic amplification over the grammage range.
- the air threshold LS is shown in the upper area with a solid line and the double arch threshold DBS in the lower area with a broken line.
- the double-arch threshold can be provided dynamically, and this can take place constantly over sections of the grammage range. This is illustrated by the lines B1, B2 and B3.
- the dynamic setting of the double arc threshold can also be set linearly or as a polynomial train of any degree, as is shown, for example, between points P1, P2, P3 and P4.
- FIG. 11 relates to a diagram which is largely similar to that of FIG. 10, the course of the target characteristic curve 42 for the single sheet largely coinciding over the entire grammage range.
- the dynamic threshold MBS for the multiple sheet and its course between the points Pia, P2a and P3a are shown on the one hand.
- FIGS. 12a, 12b, 12c schematically show the basic arrangement for the detection of single-wall corrugated cardboard 51 or double-wall corrugated cardboard 60 and the running direction L, taking into account two sensors 61, 62, in particular ultrasonic sensors.
- the corrugated cardboard 51 according to FIG. 12a is single-corrugated and has adhesive areas 54 at its adhesion points with a lower bottom layer 52 or an upper cover layer 53. These adhesive areas 54 between the cardboard shaft and the corresponding, e.g. horizontally running floor or top layers represent, so to speak, an "acoustic short circuit" when using ultrasound.
- the sensor used in the example according to FIG. 12a has on the one hand the transmitter T and the receiver R, which are aligned coaxially to one another in their main axis.
- the transmitter T and receiver R are preferably aligned approximately perpendicular to the largest corrugated surface 55 or at an angle ⁇ i to the perpendicular of the single-corrugated cardboard.
- the angle ß 2 also indicated marks the angle between the perpendicular to the corrugated cardboard and the surface direction of the main surface of the shaft.
- the optimum angle ⁇ x for sound coupling in an ultrasonic sensor onto a single-wall corrugated cardboard, which has a required acoustic short circuit AK between the bottom layer 52 and the top layer 53, is determined by the slope t / 2h.
- t is the distance between two wave crests
- h is the height of the wave or the distance between the bottom and top layer.
- FIG. 12b A two-ply corrugated cardboard 60 with the lower first shaft 58 and the upper second shaft 59 is shown in FIG. 12b.
- the arrangement of an ultrasonic sensor T, R corresponds to that according to FIG. 12a.
- the acoustic short circuit AK1 and AK2 between the individual layers is also essential for the detection of double-wall or multi-wall corrugated cardboard, i.e. a material connection in the sense of an adhesive between the shafts and the individual cover layers. In this way, it is possible to transmit a high sound energy to the multi-corrugated corrugated cardboard in an ultrasonic sensor, so that a maximum force effect is achieved approximately perpendicular to the spanned surface of the shaft.
- FIG. 12c shows the basic scheme according to which the running direction L, e.g. a single-wall or multi-wall corrugated cardboard can be detected.
- Two sensors 61, 62 are required for this.
- a first sensor 61 e.g. is designed as an ultrasonic sensor, is provided in the arrangement, as previously shown in FIGS. 12a and 12b.
- a second sensor 62 is used rotated through 90 °. In this position, which is oriented, so to speak, along the wave depression or the direction of the wave crest, only the "multiple sheet” signal is detected. Even if there is even a "single sheet". These conditions can be used to evaluate errors in the case of incorrectly inserted corrugated cardboard sheets, that is to say that the direction of the corrugation does not match the drawing direction or running direction of the corrugated cardboard.
- Fig. 13 shows a schematic representation of a top view of a device 1 for the contactless detection of flat objects, e.g. Sheets of paper or metal-clad sheets. Sheets of paper 3 or alternatively sheet metal sheets are transported as single sheets in the conveying direction F.
- the device 1 consists, for example, of three first sensors 9 arranged transversely to the conveying direction F of a sensor device 10 which is equipped with ultrasonic sensors. Upstream in the conveying direction F there are also three optical or e.g. three inductive or three capacitive sensors 44 of a second sensor device 45 are arranged.
- the sensors 9, 44 are guided via a bus line 46 to an evaluation device 4, which has an amplifier device 5 and an evaluation unit, e.g. has a microprocessor 6.
- the amplifier device 5 can be dispensed with if amplification and signal processing up to the output signal display in the sensors 9 and 44 take place, so that the output signals are directly applied to the evaluation unit 6.
- the areas 2 represent a multiple sheet, in particular a double sheet 2.
- FIG. 14 shows the vertical section through the device 1 according to FIG. 13 schematically.
- the transmitters T of the sensors 9, 44 are arranged very close below the sheets to be determined. This applies in particular to ultrasonic sensors. At a distance from the transmitters T, receivers R of the various sensors 9, 44 are arranged above the transport path.
- the sensor 44 with transmitter T and receiver R is directed at a double sheet 2, so that the transmitted signal is damped relatively strongly and a corresponding detection signal is subsequently generated in the evaluation device 4.
- the particularly advantageous combination of the sensors results in such a way that if a multiple sheet is not detected by the sensor 44, this is detected with greater certainty by the sensor 9 operating according to a different physical sensor principle.
- further sensors can be arranged in the same analogy over the flat sheet material.
- inductive sensors in combination with ultrasonic sensors can also be used for sheet metal sheets. It proves to be particularly advantageous here if the ultrasonic sensor and the inductive sensor operate according to the correction characteristic curve. For both physical sensor principles, this expands the sheet metal spectrum in terms of thickness and material, the very thin sheets preferably being able to be checked for missing, single and multiple sheets with the ultrasonic sensor, and the very thick sheets being detected by the inductive sensor.
- the combination of at least two ultrasonic sensors can also be used, for example, according to the transmission principle and the reflection principle.
- the signals fed to the evaluation device 4 can be processed channel by channel, additively or logically linked, different correction lines being able to be used depending on the sensor types.
- the sensor combination for faulty, single and multiple sheet detection does not necessarily have to work contact-free, then at least one mechanical sensor can be added to the contact-free sensors in order to ensure the detection of very thick and stable materials in a simple and inexpensive manner.
- the mechanical multiple sheet control can be set to a minimum distance, e.g. 2 mm. Missing, single and double sheet detection below the minimum distance of the mechanical multiple sheet control is guaranteed by the contact-free sensors, such as optical, capacitive, inductive or by ultrasound.
- the method and device provides a solution for the reliable detection of single sheets, missing sheets and multiple sheets, especially double sheets, this not only applying over a very wide grammage and basis weight range, but also with regard to flexible application options and different ones material spectra.
- the already expanded material spectrum of an individual sensor which is based on the method of characteristic curve correction, is advantageously. works, expanded again by adding at least one further sensor.
- the addition of at least one other sensor and the logical combination of the output signals improve the redundancy and thus the detection reliability.
- the method of correcting the characteristic curve means that there is no need to teach-in the sensors that work according to the method. For this purpose, combined sensors without correction of the characteristic curve, ie according to the state of the art, still require a learning process.
- the teach-in process is, however, significantly simplified, since the sensors which work according to the characteristic curve correction process need not be taken into account in a teach-in process of the sensor combination.
Landscapes
- Controlling Sheets Or Webs (AREA)
- Geophysics And Detection Of Objects (AREA)
Abstract
Description
Claims
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
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JP2006548163A JP4917438B2 (ja) | 2004-01-07 | 2004-12-22 | 平面物体の非接触検出のための方法およびデバイス |
EP04804234.5A EP1701902B1 (de) | 2004-01-07 | 2004-12-22 | Verfahren und vorrichtung zur berührungslosen detektion von flächigen objekten |
US10/597,027 US7526969B2 (en) | 2004-01-07 | 2004-12-22 | Method and device for the contactless detection of flat objects |
Applications Claiming Priority (4)
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DE102004001314 | 2004-01-07 | ||
DE102004001314.4 | 2004-01-07 | ||
DE102004056743A DE102004056743A1 (de) | 2004-01-07 | 2004-11-24 | Verfahren und Vorrichtung zur berührungslosen Detektion von flächigen Objekten |
DE102004056743.3 | 2004-11-24 |
Publications (1)
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WO2005066051A1 true WO2005066051A1 (de) | 2005-07-21 |
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PCT/EP2004/014640 WO2005066051A1 (de) | 2004-01-07 | 2004-12-22 | Verfahren und vorrichtung zur berührungslosen detektion von flächigen objekten |
Country Status (3)
Country | Link |
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US (1) | US7526969B2 (de) |
EP (1) | EP1701902B1 (de) |
WO (1) | WO2005066051A1 (de) |
Cited By (3)
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EP1731455A1 (de) | 2005-06-07 | 2006-12-13 | Pepperl + Fuchs Gmbh | Detektion und Vorrichtung zur Detektion von Aufzeichnungsträgern |
JP2007045146A (ja) * | 2005-08-09 | 2007-02-22 | Man Roland Druckmas Ag | フィルムガイドの監視装置 |
DE102007046769A1 (de) * | 2007-09-29 | 2009-04-16 | Leuze Electronic Gmbh + Co. Kg | Sensoranordnung |
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JP4618286B2 (ja) * | 2007-10-01 | 2011-01-26 | 富士ゼロックス株式会社 | ラベル紙の重送検知装置 |
JP4960466B2 (ja) * | 2010-03-18 | 2012-06-27 | 株式会社東芝 | 紙葉類処理装置 |
FR2960068B1 (fr) * | 2010-05-12 | 2013-06-07 | Senstronic | Dispositif de detection et de denombrement d'elements metalliques |
CN107741381B (zh) * | 2017-09-28 | 2023-10-27 | 江苏省建筑科学研究院有限公司 | 用于检测浆锚搭接连接节点灌浆密实度的装置和方法 |
JP6982275B2 (ja) * | 2017-11-20 | 2021-12-17 | ブラザー工業株式会社 | 制御装置、および、コンピュータプログラム |
CN114441305B (zh) * | 2021-12-22 | 2024-04-09 | 淮安市飞翔高新包装材料有限公司 | 瓦楞纸板抗压强度测试装置 |
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EP1731455A1 (de) | 2005-06-07 | 2006-12-13 | Pepperl + Fuchs Gmbh | Detektion und Vorrichtung zur Detektion von Aufzeichnungsträgern |
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Also Published As
Publication number | Publication date |
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US20070251311A1 (en) | 2007-11-01 |
EP1701902B1 (de) | 2014-07-09 |
US7526969B2 (en) | 2009-05-05 |
EP1701902A1 (de) | 2006-09-20 |
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