US20100066011A1 - Device and method for detecting and counting articles, released by a feeder device, in particular sheet articles released by a sheet feeder - Google Patents
Device and method for detecting and counting articles, released by a feeder device, in particular sheet articles released by a sheet feeder Download PDFInfo
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- US20100066011A1 US20100066011A1 US12/595,535 US59553508A US2010066011A1 US 20100066011 A1 US20100066011 A1 US 20100066011A1 US 59553508 A US59553508 A US 59553508A US 2010066011 A1 US2010066011 A1 US 2010066011A1
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- Prior art keywords
- sheet
- sheet articles
- detecting
- articles
- feeder
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65B—MACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
- B65B57/00—Automatic control, checking, warning, or safety devices
- B65B57/20—Applications of counting devices for controlling the feed of articles
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65B—MACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
- B65B25/00—Packaging other articles presenting special problems
- B65B25/14—Packaging paper or like sheets, envelopes, or newspapers, in flat, folded, or rolled form
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65B—MACHINES, APPARATUS OR DEVICES FOR, OR METHODS OF, PACKAGING ARTICLES OR MATERIALS; UNPACKING
- B65B65/00—Details peculiar to packaging machines and not otherwise provided for; Arrangements of such details
- B65B65/08—Devices for counting or registering the number of articles handled, or the number of packages produced by the machine
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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
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01P—WAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
- H01P7/00—Resonators of the waveguide type
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03H—IMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
- H03H2/00—Networks using elements or techniques not provided for in groups H03H3/00 - H03H21/00
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65H—HANDLING THIN OR FILAMENTARY MATERIAL, e.g. SHEETS, WEBS, CABLES
- B65H2301/00—Handling processes for sheets or webs
- B65H2301/50—Auxiliary process performed during handling process
- B65H2301/54—Auxiliary process performed during handling process for managing processing of handled material
- B65H2301/541—Counting
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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
- B65H2511/30—Numbers, e.g. of windings or rotations
-
- 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
-
- 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
- B65H2553/20—Sensing or detecting means using electric elements
- B65H2553/22—Magnetic detectors, e.g. Hall detectors
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N22/00—Investigating or analysing materials by the use of microwaves or radio waves, i.e. electromagnetic waves with a wavelength of one millimetre or more
Definitions
- the present invention relates to the technical field of packaging machines of piles of sheet articles, for example of paper documents, inserts or the like, which piles, when packaged, are intended to be sent by post; in particular, the invention relates to devices for detecting and counting the sheet articles released by feeder devices, included in the same packaging machines.
- a known packaging machine of the above-described type comprises: a conveyor member, which, by means of shaped strikers, spaced at a predetermined distance, moves corresponding article piles forming in an advancement direction; a first feeder device arranged upstream of the conveyor member, which above the latter, intermittently releases a sheet article at the time (that is a magazine, a bundle or the like) intended to be intercepted by a corresponding shaped striker; a plurality of feeder devices arranged in cascade along the development of the conveyor member to release, in suitable phase relation and above the latter, respective sheet articles (sheet articles, as for example paper inserts or the like) in order to progressively form piles in advancement; and a station, arranged downstream of the conveyor member, for packaging the thus formed piles, for example for their introduction in envelopes or their winding by means of a film or sheet, of plastic or paper respectively.
- a feeder device comprises two endless belt conveyors, mutually arranged to provide as many active counter-faced branches, a lower and an upper one, intended to drag gripped sheet articles towards an output section communicating with said conveyor member;
- the upper conveyor has the driven gear, defined by a much greater dimensioned drum than that of the remaining driving gears, driven gears and snub pulleys and is provided with suction means intended to take an article at the time from the base of a thereon arranged pile, which is integral to the frame of the feeder, according to known ways, and to drag the article until the two counter-faced branches, which extend partially around a section of the lower profile of the same drum, grip it.
- Such feeder device is associated with means, which interact with a determined lower portion of such counter-faced branches, which is in contact with the drum, these means being intended to detect the passage of none, one or more superimposed sheet articles; their control function being aimed at the generation of an error signal in case instead of a single sheet article, no sheet article passes or two or more superimposed sheet articles pass.
- these control means comprise: a mechanic amplifier, which interacts with said belt portion of the lower conveyor, intended to induce a rotation of one detecting arm of its own, proportionally to the shifting undergone by the same belt portion, after the passage of one or more sheet articles; a proximity sensor, sighting a direction perpendicular to the area interested by the same arm and interfering with the latter.
- the mechanic amplifier can be for example a shaft, rotatably carried on the frame of the feeder device, constrained on one side at a transversal detecting arm and on the other one at a little arm, which on the opposing end, comprises an idle roller (so-called “feeler”), which rolls on said belt portion of the lower conveyor and is in contact thereon by means of elastic means, interposed between the same little arm and the frame. Therefore, following the passage of a sheet article above the belt portion intercepted by the roller, the detecting arm carries out a temporary rotation from a stable rest position to a first angular position, carrying out an excursion as much marked as greater the thickness of the passing article is; when the passage is ended, the detecting arm comes back to its original, stable balancing position.
- the sensor is disposed such that its optic beam sights the detecting arm when the latter is stable in the first angular position, in order to break the light beam, for a minimum predetermined time, only when a sheet article passes.
- a local computer unit for example associated to the feeder device, receives the signals supplied by the proximity sensor; by way of example it can define an error state, to which the production stop might follow, if, when a sheet article is required to the output of the feeder, the relative signal generated by the proximity sensor, indicating the passage of a single sheet article in a determined time, does not correspond.
- the position of the sensor emitted light beam has also to be adjusted every time a format change of the loaded articles in the feeder device is required, as a thickness variation of the passing article between the counter-faced branches corresponds to a different angular excursion of the detecting arm; clearly, this operation requires expert personnel, a great number of technical tests, suitable devices and a remarkable time in comparison to the pressing requirements of a productivity, which is higher and higher.
- the required adjusting times increase according to the total number of feeder devices associated to the conveyor member (being not possible the usage of an operator and the required equipment for every conveyor, for obvious cost reasons), and become therefore unsustainable as the packaging machine becomes more complex.
- the devices for detecting and counting sheet articles released by feeder devices are disadvantageous because they are subjected to detecting errors and because they define, in order to properly function, a significant limit to the productivity of the packaging machine.
- an object of the present invention is to provide a device for detecting and counting sheet articles, intermittently released by a feeder device, which is able to satisfactorily solve the above-mentioned drawbacks, peculiar to the known solutions; so it is intended to provide a newly designed device, which is reliable, precise, functional, compact and which can be easily integrated inside feeder devices of known type as well, and whose costs are relatively reduced with respect to the advantages, which it is intended to pursue.
- Another object of the present invention is to provide a method for detecting and counting sheet articles, intermittently released by a feeder device which is able to satisfactorily solve the above-mentioned drawbacks, peculiar to the known solutions; so it is intended to provide a newly designed method, distinguished by an essential number of operating steps, which allows to precisely and reliably detect and count the sheet articles released by a feeder device and whose implementation costs are relatively reduced with respect to the advantages, which it is intended to pursue.
- the device for detecting and counting sheet articles released by a feeder device is characterized in that it comprises: an electromagnetic resonator fed by a first signal supplied by a signal generator, to generate an electromagnetic field in a passage region of said sheet articles; a sensor connected to the output of said electromagnetic resonator for detecting a second signal which identifies the induced disturbances in said electromagnetic field following the passage of said one sheet article or the passage of a plurality of said superimposed sheet articles; and a control unit connected to said sensor for calculating the number of said sheet articles, which pass from time to time across said passage region.
- the electromagnetic resonator is a resonator of recess type, in which it is made an aperture which makes this recess communicating with the outside and that said electromagnetic resonator is arranged such that said aperture is disposed at said passage region of said sheet articles.
- the method for detecting and counting articles released by a feeder device is characterized in that it comprises the following operating steps: intermittently releasing sheet articles by said feeder device; conveying said sheet articles, thus released, across a passage region in which a predetermined electromagnetic field acts; detecting the disturbances induced in said electromagnetic field after the passage of said one sheet article or after the passage of a plurality of said superimposed sheet articles; calculating the number of said sheet articles, which pass from time to time across said passage region according to the measurements carried out in the preceding step.
- FIG. 1 shows a side schematic view of a feeder device of known type, in which the inventive device for detecting and counting sheet articles is integrated;
- FIG. 2 shows a functional scheme of the device for detecting and counting of FIG. 1 ;
- FIG. 3A shows the recess electromagnetic resonator shown in FIG. 1
- FIG. 3B shows a variant thereof
- FIG. 4A shows an illustrative graph of the amplitude according to the frequency of a signal emitted by the electromagnetic resonator, the graph representing three curves, relative to as many functioning configurations indicated by # 0 , # 1 , # 2 (no sheet article passing, one sheet article passing, two superimposed sheet articles passing; respectively);
- FIG. 4B shows an illustrative graph of the phase displacement according to the frequency of a signal emitted by the electromagnetic resonator, the graph representing three curves, relative to as many significant functioning configurations indicated by # 0 , # 1 , # 2 (no sheet article passing, one sheet article passing, two superimposed sheet articles passing; respectively).
- FIG. 1 by the reference number 10 is indicated in its entirety a feeder device of known type, substantially of the above-described type, in which the inventive device 100 for detecting and counting sheet articles is integrated.
- the shown feeder device 10 comprises two endless belt conveyors 1 , 2 , mutually arranged to provide as many active counter-faced branches, a lower one 21 and an upper one 22 , intended to drag gripped sheet articles 3 towards an output section U communicating with said conveyor member (not shown) of the packaging machine (also not shown as not relevant to the invention); in particular, the upper conveyor 1 has the driven gear, defined by a much greater dimensioned drum 4 than that of the remaining driving gears, driven gears and snub pulleys and is provided for example with gripping means (not shown) intended to take an article 3 at the time from the base of a thereon arranged pile 5 , which is integral to the frame 6 of the feeder 10 , according to known ways, and to drag the article until the two counter-faced branches 21 , 22 , which extend partially around a section of the lower profile of the same drum 4 , grip it.
- the upper conveyor 1 has the driven gear, defined by a much greater dimensioned drum 4 than that of the remaining driving gears, driven gears
- the inventive detecting and counting device 100 is functionally disposed at a section of the path, which is run by each sheet article 3 released from the pile 5 and moved towards the output section U, according to ways, which will be better described in the following; in the example shown in FIG. 1 , the device 100 is fixed at the frame 6 and arranged upstream of the counter-faced branches 21 , 22 of the two belt conveyor 1 , 2 .
- the detecting and counting device 100 comprises an electromagnetic resonator 11 of recess type, in which it is made an aperture 7 , which makes the same recess 8 communicating with the outside; the electromagnetic resonator 11 is so positioned that the aperture 7 is arranged at a region 9 which is provided immediately upstream of the counter-faced branches 21 , 22 and in which the sheet articles 3 , conveyed towards the output section U of the feeder 10 are destined to pass.
- the electromagnetic resonator 11 can be arranged in any section of the path run by the sheet articles 3 released from the pile 5 and conveyed towards the output section U of the feeder 10 ; as a particular case, the resonator 11 can be functionally interposed between the output section U and the conveyor member of the packaging machine, that is to say, outside the feeder 10 .
- the inventive device 100 comprises also: a signal generator 12 which supplies the electromagnetic resonator 11 with a signal S 1 to define an electromagnetic field in the recess 8 and in the aperture 7 coinciding with the passage region 9 ; a sensor 13 connected to the output of said electromagnetic resonator 11 to detect a signal S 2 which identifies the induced disturbances in the electromagnetic field following the passage in the passage region 9 of a sheet article 3 or of a plurality of superimposed sheet articles 3 ; an analogue-to-digital converter 15 for converting in digital format the analogue signal supplied by the sensor 13 ; and a control unit 14 connected to the signal generator 12 and to the analogue-to-digital converter 15 , which controls the functioning of the detecting and counting device 100 in its entirety and which is connected to other not shown outer units, for example a control panel for the operator and/or electromechanical apparatuses of the packaging machine.
- a signal generator 12 which supplies the electromagnetic resonator 11 with a signal S 1 to define an electromagnetic field in the recess 8
- the signal generator 12 comprises for example oscillating electronic circuits and/or numerical control circuits DDS (Direct Digital Synthesizer) and supplies the high frequency signal 51 having a frequency between 1 MHz and 100 GHz, at the input of the electromagnetic resonator 11 .
- DDS Direct Digital Synthesizer
- the senor 13 is instead a detector device, which converts the high frequency signal S 2 received by the electromagnetic resonator 11 in two signals in direct current (DC), whose values vary according to the amplitude (power) and to the phase of the same signal S 2 .
- DC direct current
- FIGS. 1 , 3 B various illustrative embodiments of the recess electromagnetic resonator 11 are shown; in FIGS. 1 , 3 B the electromagnetic resonator 11 extends in longitudinal direction, has a rectangular transversal section, and the aperture 7 is made according to the relative longitudinal development dividing the same resonator 11 in two distinct and counter-faced portions 16 , 17 ;
- FIG. 3A shows another example of the electromagnetic resonator 11 , with a cylindrical configuration, also distinguished by the aperture 7 made according to the longitudinal development dividing the same resonator 11 in two distinct and counter-faced portions 16 , 17 ; in the schematic representation of FIG. 2 , the electromagnetic resonator 11 in instead similar to the one represented in FIGS. 1 , 3 B but it is different in that it is an unique body with the aperture 7 of predetermined depth.
- the recess 8 of the electromagnetic resonator 11 can be for example interested by air or Teflon.
- the functioning of the inventive detecting and counting device 100 is based on detecting the disturbance of the electromagnetic field acting in the aperture 7 , which as said, thanks to the suitable arrangement of the recess electromagnetic resonator 11 , coincides with the passage region 9 of the sheet articles 3 .
- Such disturbance of the electromagnetic field is caused by the passage of a sheet article 3 across the passage region 9 or of more superimposed sheet articles 3 which, by mistake, have been drawn from the base of the pile 5 of the feeder 10 .
- the aperture 7 is so shaped and dimensioned to allow the passage of one or more superimposed sheet articles 3 and to define a predetermined electromagnetic field in order to detect the passage of said sheet articles 3 .
- inventive detecting and counting device 100 results generally from the following description of the method for detecting and counting sheet articles 3 , intermittently released by the feeder device 10 , also object of the invention, the method comprising the following operating steps:
- FIG. 4A shows an illustrative graph of the amplitude variation of the signal S 2 according to the frequency, when at the input of the electromagnetic resonator 11 is applied a signal S 1 of prefixed amplitude and phase: the graph shows three curves indicated by # 0 , # 1 , # 2 , which represent the different behaviour of the electromagnetic resonator 11 in case in the passage region 9 no sheet article 3 passes (curve # 0 ), only one sheet article 3 passes (curve # 1 ) or two superimposed sheet articles 3 pass (curve # 2 ).
- these curves run in a “bell-like” way, which is peculiar to an electromagnetic resonator, which “resounds” at the frequency (resonance frequency), centred with respect to the corresponding reference curve.
- FIG. 4B shows similar considerations. It shows an illustrative graph of the phase variation of the signal S 2 according to the frequency when at the input of the electromagnetic resonator 11 is applied a signal S 1 of prefixed amplitude and phase; in fact, the graph shows three curves indicated by # 0 , # 1 , # 2 , which represent the different behaviour of the electromagnetic resonator 11 in case in the passage region 9 no sheet article 3 passes (curve # 0 ), only one sheet article 3 passes (curve # 1 ) or two superimposed sheet articles 3 pass (curve # 2 ).
- F 0 indicates the resonance frequency of the “loadless” electromagnetic resonator (no sheet article 3 , curve # 0 ); the praxis suggests to choose the frequency F S of the signal S 1 preferably between F 0 ⁇ 5*F 0 /Q 0 and F 0 +5*F 0 /Q 0 , where Q 0 is the merit factor of the electromagnetic resonator 11 when in the passage region 9 there is no sheet article 3 passing.
- the graphs shown in FIGS. 4A , 4 B define: A 0 (F S ), P 0 (F S ) respectively as amplitude and phase of the signal S 2 when there are no sheet articles 3 in the passage region 9 ; A 1 (F S ), P 1 (F S ) as amplitude and phase of the signal S 2 when there is only one sheet article 3 in the passage region 9 ; A 2 (F S ), P 2 (F S ) as amplitude and phase of the signal S 2 when there are two sheet articles 3 in the passage region 9 .
- the attenuation and the phase displacement undergone by the signal S 2 can be instead defined as:
- a L (F S ), P L (F S ) are respectively the amplitude and the phase of the signal S 2 detected at the frequency F S after the passage of zero, one, two or more superimposed sheet articles 3 in the passage region 9 .
- Every above-described calculating operation can be carried out by the control unit 14 according to the data supplied by the detector device 13 by means of the analogue-to-digital converter 15 (which can be alternately integrated in the same control unit 14 ).
- the detector device 13 can be alternately chosen to supply only a signal emitted in direct current (DC), whose values vary according to the amplitude or the phase of the signal S 2 .
- control unit 14 can carry out an amplitude and phase measurement of the signal S 2 at the pre-chosen frequency F S only one time, with no sheet articles 3 passing in the passage region 9 , storing the values A 0 (F S ), P 0 (F S ); in the event of a format change of the sheet articles 3 , it is for example sufficient that by means of a control panel (not shown) the operator controls at the control unit 14 the running of an acquisition preliminary phase during which a sheet article 3 according to the new format is released from the pile 5 , so that the control unit 14 itself can store the new values A 1 (F S ), P 1 (F S ).
- the values A 1 (F S ), P 1 (F S ) associated to every type of sheet articles 3 can result pre-loaded in the storage of the control unit 14 or can be stored from time to time in the event of a format change, by carrying out the starting acquisition phase; in such case, from the control panel the operator can select the new pre-chosen format by a list of available formats or can control said acquisition phase.
- the values A 2 (F S ), P 2 (F S ) can be determined: by means of a further acquisition phase, in which two superimposed sheet articles 3 according to the new format pass; or by means of a calculus algorithm based on the yet acquired values A 1 (F S ), P 1 (F S ). However, it is to be adoptedd that these values A 2 (F S ), P 2 (F S ) are not indispensable to determine the thresholds of amplitude TA L , TA H and frequency TP L , TP H .
- control unit 14 can also provide different functioning ways of the device 100 in order to detect and count the sheet articles 3 , and so to carry out more complex calculus algorithms, based for example on detecting a plurality of amplitude and/or phase values of the signal S 2 for corresponding value of frequency between F 0 ⁇ 5*F 0 /Q 0 and F 0 +5*F 0 /Q 0 .
- the present invention is advantageous in that it defines a device for detecting and counting sheet articles, intermittently released by a feeder device which satisfies the prefixed objects, brilliantly solving every drawback lamented in the introduction, peculiar to the known devices; therefore, it has been defined a reliable, precise, compact, versatile device which can be easily integrated inside feeder devices of known type as well and whose costs are relatively reduced with respect to the achieved advantages.
- the thus defined detecting and counting device has therefore the function of constantly monitoring the correct functioning of the sheet feeder 10 ; in case of wrong releasing of more superimposed sheet articles 3 from the pile 5 of the feeder 10 , such device 100 detects a wrong condition.
- a wrong condition processed by the control unit 14 , a corresponding error signalling to the central processing unit of the packaging machine, an error signalling on the control panel and/or the emission of an acoustic signal can follow.
- the present invention is further advantageous in that it defines a method for detecting and counting sheet articles, intermittently released by a feeder device which satisfies the prefixed objects, brilliantly solving every drawback lamented in the introduction, peculiar to the known devices; therefore it has been defined a newly designed method distinguished by an essential number of operating steps, which allows to precisely and reliably detect and count the sheet articles released by a feeder device and whose implementation costs are relatively reduced with respect to the achieved advantages.
Abstract
A method and device for detecting and counting articles released by a feeder device, in particular sheet articles released by a sheet feeder are described.
The device comprises: an electromagnetic resonator (11) fed by a signal generator (12), to generate an electromagnetic field in a passage region (9) of said sheet articles (3); a sensor (13) connected to the electromagnetic resonator (11) for detecting the induced disturbances in the electromagnetic field following the passage of one or more superimposed sheet articles (3); and a control unit (14) connected to the sensor (13) for calculating the number of sheet articles (3), which pass from time to time across the passage region (9). In particular, the electromagnetic resonator (11) is of recess type and in it an aperture (7) is made which makes said recess (8) communicating with the outside; whereby the resonator (11) is arranged so that the aperture (7) is disposed at the passage region (9).
The method comprises the steps of: intermittently releasing sheet articles by the feeder (10); conveying the sheet articles (3) across the passage region (9); detecting the disturbances induced in the electromagnetic field after the passage of one or more superimposed sheet articles (3); calculating the number of sheet articles (3) which pass from time to time across the passage region (9) according to the measurements carried out in the preceding step.
Description
- The present invention relates to the technical field of packaging machines of piles of sheet articles, for example of paper documents, inserts or the like, which piles, when packaged, are intended to be sent by post; in particular, the invention relates to devices for detecting and counting the sheet articles released by feeder devices, included in the same packaging machines.
- A known packaging machine of the above-described type comprises: a conveyor member, which, by means of shaped strikers, spaced at a predetermined distance, moves corresponding article piles forming in an advancement direction; a first feeder device arranged upstream of the conveyor member, which above the latter, intermittently releases a sheet article at the time (that is a magazine, a bundle or the like) intended to be intercepted by a corresponding shaped striker; a plurality of feeder devices arranged in cascade along the development of the conveyor member to release, in suitable phase relation and above the latter, respective sheet articles (sheet articles, as for example paper inserts or the like) in order to progressively form piles in advancement; and a station, arranged downstream of the conveyor member, for packaging the thus formed piles, for example for their introduction in envelopes or their winding by means of a film or sheet, of plastic or paper respectively.
- According to a diffused structural configuration, a feeder device comprises two endless belt conveyors, mutually arranged to provide as many active counter-faced branches, a lower and an upper one, intended to drag gripped sheet articles towards an output section communicating with said conveyor member; in particular the upper conveyor has the driven gear, defined by a much greater dimensioned drum than that of the remaining driving gears, driven gears and snub pulleys and is provided with suction means intended to take an article at the time from the base of a thereon arranged pile, which is integral to the frame of the feeder, according to known ways, and to drag the article until the two counter-faced branches, which extend partially around a section of the lower profile of the same drum, grip it.
- Such feeder device is associated with means, which interact with a determined lower portion of such counter-faced branches, which is in contact with the drum, these means being intended to detect the passage of none, one or more superimposed sheet articles; their control function being aimed at the generation of an error signal in case instead of a single sheet article, no sheet article passes or two or more superimposed sheet articles pass. Usually, these control means comprise: a mechanic amplifier, which interacts with said belt portion of the lower conveyor, intended to induce a rotation of one detecting arm of its own, proportionally to the shifting undergone by the same belt portion, after the passage of one or more sheet articles; a proximity sensor, sighting a direction perpendicular to the area interested by the same arm and interfering with the latter. The mechanic amplifier can be for example a shaft, rotatably carried on the frame of the feeder device, constrained on one side at a transversal detecting arm and on the other one at a little arm, which on the opposing end, comprises an idle roller (so-called “feeler”), which rolls on said belt portion of the lower conveyor and is in contact thereon by means of elastic means, interposed between the same little arm and the frame. Therefore, following the passage of a sheet article above the belt portion intercepted by the roller, the detecting arm carries out a temporary rotation from a stable rest position to a first angular position, carrying out an excursion as much marked as greater the thickness of the passing article is; when the passage is ended, the detecting arm comes back to its original, stable balancing position.
- The sensor is disposed such that its optic beam sights the detecting arm when the latter is stable in the first angular position, in order to break the light beam, for a minimum predetermined time, only when a sheet article passes. A local computer unit, for example associated to the feeder device, receives the signals supplied by the proximity sensor; by way of example it can define an error state, to which the production stop might follow, if, when a sheet article is required to the output of the feeder, the relative signal generated by the proximity sensor, indicating the passage of a single sheet article in a determined time, does not correspond. A similar solution is very diffused in this field, even if it implies many drawbacks: sheet articles of relevant thickness (therefore, for example more than sixty micrometers), in fact, determine remarkable mechanic stresses on the mechanic amplifier, defining an upper limit of the operative speed of the feeder and therefore of the productivity of the packaging machine in which the latter is integrated; moreover, such limit, has to be further reduced to allow the same amplifier to withstand stress “peaks”, which are induced by the undesired passage of two or more superimposed sheet articles between the counter-faced branches. The position of the sensor emitted light beam has also to be adjusted every time a format change of the loaded articles in the feeder device is required, as a thickness variation of the passing article between the counter-faced branches corresponds to a different angular excursion of the detecting arm; clearly, this operation requires expert personnel, a great number of technical tests, suitable devices and a remarkable time in comparison to the pressing requirements of a productivity, which is higher and higher. Moreover, the required adjusting times increase according to the total number of feeder devices associated to the conveyor member (being not possible the usage of an operator and the required equipment for every conveyor, for obvious cost reasons), and become therefore unsustainable as the packaging machine becomes more complex.
- Generally, it can be said that the devices for detecting and counting sheet articles released by feeder devices are disadvantageous because they are subjected to detecting errors and because they define, in order to properly function, a significant limit to the productivity of the packaging machine.
- Therefore, an object of the present invention is to provide a device for detecting and counting sheet articles, intermittently released by a feeder device, which is able to satisfactorily solve the above-mentioned drawbacks, peculiar to the known solutions; so it is intended to provide a newly designed device, which is reliable, precise, functional, compact and which can be easily integrated inside feeder devices of known type as well, and whose costs are relatively reduced with respect to the advantages, which it is intended to pursue.
- Another object of the present invention is to provide a method for detecting and counting sheet articles, intermittently released by a feeder device which is able to satisfactorily solve the above-mentioned drawbacks, peculiar to the known solutions; so it is intended to provide a newly designed method, distinguished by an essential number of operating steps, which allows to precisely and reliably detect and count the sheet articles released by a feeder device and whose implementation costs are relatively reduced with respect to the advantages, which it is intended to pursue.
- Said above-mentioned objects are accomplished by a device and a method according to
claims - The device for detecting and counting sheet articles released by a feeder device, in particular sheet articles released by a sheet feeder, is characterized in that it comprises: an electromagnetic resonator fed by a first signal supplied by a signal generator, to generate an electromagnetic field in a passage region of said sheet articles; a sensor connected to the output of said electromagnetic resonator for detecting a second signal which identifies the induced disturbances in said electromagnetic field following the passage of said one sheet article or the passage of a plurality of said superimposed sheet articles; and a control unit connected to said sensor for calculating the number of said sheet articles, which pass from time to time across said passage region.
- In a dependent claim, it is précised that the electromagnetic resonator is a resonator of recess type, in which it is made an aperture which makes this recess communicating with the outside and that said electromagnetic resonator is arranged such that said aperture is disposed at said passage region of said sheet articles.
- The method for detecting and counting articles released by a feeder device, in particular sheet articles released by a sheet feeder, is characterized in that it comprises the following operating steps: intermittently releasing sheet articles by said feeder device; conveying said sheet articles, thus released, across a passage region in which a predetermined electromagnetic field acts; detecting the disturbances induced in said electromagnetic field after the passage of said one sheet article or after the passage of a plurality of said superimposed sheet articles; calculating the number of said sheet articles, which pass from time to time across said passage region according to the measurements carried out in the preceding step.
- The features of the invention, not emerging from the preceding description, will be better highlighted in the following, according to the claims and by means of the appended drawings, in which:
-
FIG. 1 shows a side schematic view of a feeder device of known type, in which the inventive device for detecting and counting sheet articles is integrated; -
FIG. 2 shows a functional scheme of the device for detecting and counting ofFIG. 1 ; -
FIG. 3A shows the recess electromagnetic resonator shown inFIG. 1 , whileFIG. 3B shows a variant thereof; -
FIG. 4A shows an illustrative graph of the amplitude according to the frequency of a signal emitted by the electromagnetic resonator, the graph representing three curves, relative to as many functioning configurations indicated by #0, #1, #2 (no sheet article passing, one sheet article passing, two superimposed sheet articles passing; respectively); -
FIG. 4B shows an illustrative graph of the phase displacement according to the frequency of a signal emitted by the electromagnetic resonator, the graph representing three curves, relative to as many significant functioning configurations indicated by #0, #1, #2 (no sheet article passing, one sheet article passing, two superimposed sheet articles passing; respectively). - In
FIG. 1 , by thereference number 10 is indicated in its entirety a feeder device of known type, substantially of the above-described type, in which theinventive device 100 for detecting and counting sheet articles is integrated. - The shown
feeder device 10 comprises twoendless belt conveyors sheet articles 3 towards an output section U communicating with said conveyor member (not shown) of the packaging machine (also not shown as not relevant to the invention); in particular, theupper conveyor 1 has the driven gear, defined by a much greaterdimensioned drum 4 than that of the remaining driving gears, driven gears and snub pulleys and is provided for example with gripping means (not shown) intended to take anarticle 3 at the time from the base of a thereon arrangedpile 5, which is integral to theframe 6 of thefeeder 10, according to known ways, and to drag the article until the twocounter-faced branches same drum 4, grip it. - The inventive detecting and counting
device 100 is functionally disposed at a section of the path, which is run by eachsheet article 3 released from thepile 5 and moved towards the output section U, according to ways, which will be better described in the following; in the example shown inFIG. 1 , thedevice 100 is fixed at theframe 6 and arranged upstream of thecounter-faced branches belt conveyor - The detecting and counting
device 100 comprises anelectromagnetic resonator 11 of recess type, in which it is made anaperture 7, which makes thesame recess 8 communicating with the outside; theelectromagnetic resonator 11 is so positioned that theaperture 7 is arranged at aregion 9 which is provided immediately upstream of thecounter-faced branches sheet articles 3, conveyed towards the output section U of thefeeder 10 are destined to pass. In general, however, theelectromagnetic resonator 11 can be arranged in any section of the path run by thesheet articles 3 released from thepile 5 and conveyed towards the output section U of thefeeder 10; as a particular case, theresonator 11 can be functionally interposed between the output section U and the conveyor member of the packaging machine, that is to say, outside thefeeder 10. - The
inventive device 100 comprises also: asignal generator 12 which supplies theelectromagnetic resonator 11 with a signal S1 to define an electromagnetic field in therecess 8 and in theaperture 7 coinciding with thepassage region 9; asensor 13 connected to the output of saidelectromagnetic resonator 11 to detect a signal S2 which identifies the induced disturbances in the electromagnetic field following the passage in thepassage region 9 of asheet article 3 or of a plurality of superimposedsheet articles 3; an analogue-to-digital converter 15 for converting in digital format the analogue signal supplied by thesensor 13; and acontrol unit 14 connected to thesignal generator 12 and to the analogue-to-digital converter 15, which controls the functioning of the detecting and countingdevice 100 in its entirety and which is connected to other not shown outer units, for example a control panel for the operator and/or electromechanical apparatuses of the packaging machine. - The
signal generator 12 comprises for example oscillating electronic circuits and/or numerical control circuits DDS (Direct Digital Synthesizer) and supplies the high frequency signal 51 having a frequency between 1 MHz and 100 GHz, at the input of theelectromagnetic resonator 11. - By way of example, the
sensor 13 is instead a detector device, which converts the high frequency signal S2 received by theelectromagnetic resonator 11 in two signals in direct current (DC), whose values vary according to the amplitude (power) and to the phase of the same signal S2. - In the appended drawings, various illustrative embodiments of the recess
electromagnetic resonator 11 are shown; inFIGS. 1 , 3B theelectromagnetic resonator 11 extends in longitudinal direction, has a rectangular transversal section, and theaperture 7 is made according to the relative longitudinal development dividing thesame resonator 11 in two distinct and counter-facedportions FIG. 3A shows another example of theelectromagnetic resonator 11, with a cylindrical configuration, also distinguished by theaperture 7 made according to the longitudinal development dividing thesame resonator 11 in two distinct andcounter-faced portions FIG. 2 , theelectromagnetic resonator 11 in instead similar to the one represented inFIGS. 1 , 3B but it is different in that it is an unique body with theaperture 7 of predetermined depth. Therecess 8 of theelectromagnetic resonator 11 can be for example interested by air or Teflon. - The functioning of the inventive detecting and counting
device 100 is based on detecting the disturbance of the electromagnetic field acting in theaperture 7, which as said, thanks to the suitable arrangement of the recesselectromagnetic resonator 11, coincides with thepassage region 9 of thesheet articles 3. Such disturbance of the electromagnetic field is caused by the passage of asheet article 3 across thepassage region 9 or of moresuperimposed sheet articles 3 which, by mistake, have been drawn from the base of thepile 5 of thefeeder 10. - Therefore, the
aperture 7 is so shaped and dimensioned to allow the passage of one or moresuperimposed sheet articles 3 and to define a predetermined electromagnetic field in order to detect the passage of saidsheet articles 3. - The functioning of the inventive detecting and counting
device 100 results generally from the following description of the method for detecting and countingsheet articles 3, intermittently released by thefeeder device 10, also object of the invention, the method comprising the following operating steps: -
- a. intermittently releasing
sheet articles 3 from thepile 5 of thefeeder device 10; - b. conveying the
sheet articles 3 across thepassage region 9 in which a predetermined electromagnetic field defined by thesignal generator 12 acts; - c. detecting the disturbances induced in this electromagnetic field after the passage of said one
sheet article 3 or after the passage of a plurality of superimposedsheet articles 3; - d. calculating the number of
sheet articles 3, which pass from time to time across thepassage region 9 according to the measurements carried out in the preceding step.
- a. intermittently releasing
- In the following, it will be described in further detail one among the possible functioning ways of the detecting and counting
device 100, object of the present invention. -
FIG. 4A shows an illustrative graph of the amplitude variation of the signal S2 according to the frequency, when at the input of theelectromagnetic resonator 11 is applied a signal S1 of prefixed amplitude and phase: the graph shows three curves indicated by #0, #1, #2, which represent the different behaviour of theelectromagnetic resonator 11 in case in thepassage region 9 nosheet article 3 passes (curve #0), only onesheet article 3 passes (curve #1) or two superimposedsheet articles 3 pass (curve #2). As it can be noted, these curves run in a “bell-like” way, which is peculiar to an electromagnetic resonator, which “resounds” at the frequency (resonance frequency), centred with respect to the corresponding reference curve. -
FIG. 4B allows similar considerations. It shows an illustrative graph of the phase variation of the signal S2 according to the frequency when at the input of theelectromagnetic resonator 11 is applied a signal S1 of prefixed amplitude and phase; in fact, the graph shows three curves indicated by #0, #1, #2, which represent the different behaviour of theelectromagnetic resonator 11 in case in thepassage region 9 nosheet article 3 passes (curve #0), only onesheet article 3 passes (curve #1) or two superimposedsheet articles 3 pass (curve #2). - F0 indicates the resonance frequency of the “loadless” electromagnetic resonator (no
sheet article 3, curve #0); the praxis suggests to choose the frequency FS of the signal S1 preferably between F0−5*F0/Q0 and F0+5*F0/Q0, where Q0 is the merit factor of theelectromagnetic resonator 11 when in thepassage region 9 there is nosheet article 3 passing. - The graphs shown in
FIGS. 4A , 4B define: A0(FS), P0(FS) respectively as amplitude and phase of the signal S2 when there are nosheet articles 3 in thepassage region 9; A1(FS), P1(FS) as amplitude and phase of the signal S2 when there is only onesheet article 3 in thepassage region 9; A2(FS), P2(FS) as amplitude and phase of the signal S2 when there are twosheet articles 3 in thepassage region 9. - It is possible to define the attenuation and the phase displacement undergone by the signal S2 when only a
single sheet article 3 passes in thepassage region 9, as: -
ΔA1(FS)=|A0(FS)−A1(FS)| -
ΔP1(FS)=|P0(FS)−P1(FS)| - and the attenuation and the phase displacement undergone by the signal S2 when two
superimposed sheet articles 3 pass in thepassage region 9, as: -
ΔA2(FS)=|A0(FS)−A2(FS)| -
ΔP2(FS)=|P0(FS)−P2(FS)| - In general terms, the attenuation and the phase displacement undergone by the signal S2 can be instead defined as:
-
ΔAL(FS)=|A0(FS)−AL(FS)| -
ΔPL(FS)=|P0(FS)−PL(FS)| - where AL(FS), PL(FS) are respectively the amplitude and the phase of the signal S2 detected at the frequency FS after the passage of zero, one, two or more
superimposed sheet articles 3 in thepassage region 9. - When the attenuation ΔA1(FS), ΔA2(FS) undergone by the signal S2, in case of passage of one
sheet article 3 or of twosuperimposed sheet articles 3 respectively in thepassage region 9, is known, it is possible to provide suitable threshold values TAL, TAH with TAL<TAH so that: -
- if ΔAL(FS) is greater than the lower threshold TAL and smaller than the upper threshold TAH, there is a
sheet article 3 in thepassage region 9; - if ΔAL(FS) is smaller than the lower threshold TAL there are no
sheet articles 3 in thepassage region 9; - if ΔAL(FS) is greater than the upper threshold TAH, there are at least two
superimposed sheet articles 3 in thepassage region 9, whereby a drawing error of thesheet articles 3 from the base of thepile 5 is detectable.
- if ΔAL(FS) is greater than the lower threshold TAL and smaller than the upper threshold TAH, there is a
- Similarly, when the phase displacement ΔP2(FS), ΔP1(FS) undergone by the signal S2, in case of passage of one
sheet article 3 or of twosuperimposed sheet articles 3 respectively in thepassage region 9, is known, it is possible to provide suitable threshold values TPL, TPH with TPL<TPH so that: -
- if ΔPL(FS) is greater than the lower threshold TPL and smaller than the upper threshold TPH, there is a
sheet article 3 in thepassage region 9; - if ΔPL(FS) is smaller than the lower threshold TPL there are no
sheet articles 3 in thepassage region 9; - if ΔPL(FS) is greater than the upper threshold TPH there are at least two
superimposed sheet articles 3 in thepassage region 9, whereby a drawing error of thesheet articles 3 from the base of thepile 5 is detectable.
- if ΔPL(FS) is greater than the lower threshold TPL and smaller than the upper threshold TPH, there is a
- Every above-described calculating operation can be carried out by the
control unit 14 according to the data supplied by thedetector device 13 by means of the analogue-to-digital converter 15 (which can be alternately integrated in the same control unit 14). - From the preceding description it results clear that for detecting and counting the
sheet articles 3 passing across thepassage region 9, it is sufficient to consider even only amplitude or phase detecting of the signal S2, from which then it is possible to go back respectively to the attenuation and the phase displacement of the same signal S2. In this way, thedetector device 13 can be alternately chosen to supply only a signal emitted in direct current (DC), whose values vary according to the amplitude or the phase of the signal S2. - In order to carry out the above-described operations, which allow to count the number of
sheet articles 3 passing across thepassage region 9, it is required to have preliminary measures of amplitude and/or phase of the signal S2 at the pre-chosen frequency FS at one's disposal, in case of no sheet articles passing (values A0(FS), P0(FS)), only onesheet article 3 passing (values A1(FS), P1(FS)) and twosuperimposed sheet articles 3 passing (values A2(FS), P2(FS)); the knowledge of these values allows then to define the above-mentioned thresholds of amplitude TAL, TAH and frequency TPL, TPH. - In practical terms, the
control unit 14 can carry out an amplitude and phase measurement of the signal S2 at the pre-chosen frequency FS only one time, with nosheet articles 3 passing in thepassage region 9, storing the values A0(FS), P0(FS); in the event of a format change of thesheet articles 3, it is for example sufficient that by means of a control panel (not shown) the operator controls at thecontrol unit 14 the running of an acquisition preliminary phase during which asheet article 3 according to the new format is released from thepile 5, so that thecontrol unit 14 itself can store the new values A1(FS), P1(FS). It has to be précised that in the event of a format change of thesheet articles 3, in which material and/or dimensions and/or thickness of thesame sheet articles 3 change, the curve indicated by #1 in the graphs ofFIGS. 4A , 4B can undergo even sensible variations, that have to be considered in order to count thesheet articles 3. - The values A1(FS), P1(FS) associated to every type of
sheet articles 3 can result pre-loaded in the storage of thecontrol unit 14 or can be stored from time to time in the event of a format change, by carrying out the starting acquisition phase; in such case, from the control panel the operator can select the new pre-chosen format by a list of available formats or can control said acquisition phase. - This is extremely advantageous because it makes very easy and fast the format change operation of the
sheet articles 3, which can be carried out by means of essential controls given by thecontrol unit 14 by means of a standard user-interface connected to the latter, as for example the above-mentioned control panel; skilled personnel manual interventions to adjust mechanical portions of the detecting andcounting device 100 are therefore not required. - The values A2(FS), P2(FS) can be determined: by means of a further acquisition phase, in which two
superimposed sheet articles 3 according to the new format pass; or by means of a calculus algorithm based on the yet acquired values A1(FS), P1(FS). However, it is to be précised that these values A2(FS), P2(FS) are not indispensable to determine the thresholds of amplitude TAL, TAH and frequency TPL, TPH. - In general terms, the
control unit 14 can also provide different functioning ways of thedevice 100 in order to detect and count thesheet articles 3, and so to carry out more complex calculus algorithms, based for example on detecting a plurality of amplitude and/or phase values of the signal S2 for corresponding value of frequency between F0−5*F0/Q0 and F0+5*F0/Q0. - According to the claims, it is eventually to be précised that in order to accomplish the present invention, in the
device 100, electromagnetic resonators different from those of “recess” type can be used, which are shown in the appended drawings. - The present invention is advantageous in that it defines a device for detecting and counting sheet articles, intermittently released by a feeder device which satisfies the prefixed objects, brilliantly solving every drawback lamented in the introduction, peculiar to the known devices; therefore, it has been defined a reliable, precise, compact, versatile device which can be easily integrated inside feeder devices of known type as well and whose costs are relatively reduced with respect to the achieved advantages.
- The thus defined detecting and counting device has therefore the function of constantly monitoring the correct functioning of the
sheet feeder 10; in case of wrong releasing of moresuperimposed sheet articles 3 from thepile 5 of thefeeder 10,such device 100 detects a wrong condition. By way of a not limiting example, after such a wrong condition, processed by thecontrol unit 14, a corresponding error signalling to the central processing unit of the packaging machine, an error signalling on the control panel and/or the emission of an acoustic signal can follow. - The present invention is further advantageous in that it defines a method for detecting and counting sheet articles, intermittently released by a feeder device which satisfies the prefixed objects, brilliantly solving every drawback lamented in the introduction, peculiar to the known devices; therefore it has been defined a newly designed method distinguished by an essential number of operating steps, which allows to precisely and reliably detect and count the sheet articles released by a feeder device and whose implementation costs are relatively reduced with respect to the achieved advantages.
- It is intended that the preceding description is purely exemplary and not limiting, therefore possible practical-applicative variations are intended to fall into the protective scope of the invention, as defined by the following claims.
Claims (9)
1. Device for detecting and counting articles released by a feeder device, in particular sheet articles released by a sheet feeder, characterized in that it comprises: an electromagnetic resonator (11), fed by a signal (S1)supplied by a signal generator (12) to generate an electromagnetic field in a passage region (9) of said sheet articles (3); a sensor (13) connected to the output of said electromagnetic resonator (11)for detecting a signal (S2) which identifies the induced disturbances in said electromagnetic field following the passage of said one sheet article(3)or of a plurality of said superimposed sheet articles (3);and a control unit(14)connected to said sensor (13) for calculating the number of said sheet articles (3) passing from time to time across said passage region (9).
2. Device according to claim 1 , characterized in that said electromagnetic resonator (11) is a resonator of recess type, in which an aperture (7)is made, which makes said recess (8) communicating with the outside and in that said electromagnetic resonator (11) is arranged such that said aperture (7) is disposed at said passage region (9) of said sheet articles (3).
3. Device according to claim 2 , characterized in that said aperture (7) divides said recess resonator (11) in two distinct and counter-faced portions (16, 17).
4. Device according to claim 1 , characterized in that said sensor (13) is a detector for detecting the amplitude or power of said signal (S2) provided at the output of said electromagnetic resonator (11).
5. Device according to claim 1 , characterized in that said sensor (13) is a detector for detecting the phase of said signal (S2) provided at the output of said electromagnetic resonator (11).
6. Device according to claim 1 , characterized in that said signal generator supplies said one signal (S1), having a frequency between 1 MHz and 100 GHz at the input of said electromagnetic resonator (11).
7. Method for detecting and counting articles released by a feeder device, in particular sheet articles released by a sheet feeder, characterized in that it comprises the following operating steps:
a. releasing said sheet articles (3) by said feeder device (10);
b. conveying said sheet articles (3),thus released, across a passage region (9) in which a predetermined electromagnetic fieldacts;
c. detecting the disturbances induced in said electromagnetic field after the passage of said one sheet article(3) or the passage of a plurality of said superimposed sheet articles (3);
d. calculating the number of said sheet articles (3), which pass from time to time across said passage region (9) according to the measurements carried out in the preceding step.
8. Device according to claim 2 , characterized in that said sensor (13) is a detector for detecting the amplitude or power of said signal (S2) provided at the output of said electromagnetic resonator (11).
9. Device according to claim 2 , characterized in that said sensor (13) is a detector for detecting the phase of said signal (S2) provided at the output of said electromagnetic resonator (11).
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
ITPG2007A000034 | 2007-04-13 | ||
IT000034A ITPG20070034A1 (en) | 2007-04-13 | 2007-04-13 | APPARATUS AND METHOD FOR DETECTION AND COUNTING OF SHEETS AND LAMINATED PRODUCTS. |
PCT/IB2008/000895 WO2008125959A1 (en) | 2007-04-13 | 2008-04-14 | Device and method for detecting and counting articles, released by a feeder device, in particular sheet articles released by a sheet feeder |
Publications (1)
Publication Number | Publication Date |
---|---|
US20100066011A1 true US20100066011A1 (en) | 2010-03-18 |
Family
ID=39708321
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US12/595,535 Abandoned US20100066011A1 (en) | 2007-04-13 | 2008-04-14 | Device and method for detecting and counting articles, released by a feeder device, in particular sheet articles released by a sheet feeder |
Country Status (6)
Country | Link |
---|---|
US (1) | US20100066011A1 (en) |
EP (1) | EP2155562A1 (en) |
JP (1) | JP2010523440A (en) |
CA (1) | CA2683860A1 (en) |
IT (1) | ITPG20070034A1 (en) |
WO (1) | WO2008125959A1 (en) |
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US20120159899A1 (en) * | 2010-12-28 | 2012-06-28 | Riso Kagaku Corporation | Enclosing-sealing device and image formation system having the same |
CN104494973A (en) * | 2014-12-25 | 2015-04-08 | 重庆博钻太阳能灯具有限公司 | Statistic return-to-zero device for equipment for packing and transporting LED tubes |
US20150260688A1 (en) * | 2014-03-17 | 2015-09-17 | Hiroyuki Ono | Sheet conveying device, image forming apparatus, and method of determining whether multi-feed has occurred |
EP2848133B1 (en) | 2013-07-16 | 2018-05-30 | Hauni Maschinenbau GmbH | Assembly and method for checking rod-shaped articles from the tobacco processing industry |
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Also Published As
Publication number | Publication date |
---|---|
ITPG20070034A1 (en) | 2008-10-14 |
CA2683860A1 (en) | 2008-10-23 |
WO2008125959A1 (en) | 2008-10-23 |
EP2155562A1 (en) | 2010-02-24 |
JP2010523440A (en) | 2010-07-15 |
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