DE2102986C3 - Measuring device for periodically operated signature collecting devices for checking the signature groups determining a book for completeness - Google Patents

Description

Book with a reference value triggers an error signal. It is avoided that the binding device, such as it is the case with mechanical measuring instruments, initially continue working for a certain time before the system is switched off for the purpose of correcting the input,

The invention is based on exemplary embodiments explained with reference to the drawing

F i g. 1 of the drawing is a perspective view of a Signature collection device known embodiment, within which the measuring device according to the Invention is applied;

F i g. 2 is a detailed view of a signature or a group of signatures on a saddle of a conveyor system the signature collector;

Fig. 3 is a schematic view of a measuring device according to an embodiment of the invention;

F i g. Fig. 4 is a view of two disks used to timed interruption of the beams;

F i g. 5-7 are graphical representations of profiles of different output signals corresponding to one error-free book, corresponding to a book that is too thick and corresponding to a book that is too thin; and

Figs. 8-10 are views of other embodiments the measuring device according to the invention.

The signature collecting device shown in Fig. 1 of the drawings has a pair of storage containers Hl and H2 for signatures on its right-hand side in the viewing direction. The storage containers are partially covered by a pair of upwardly extending cover plates Ci and C2 . In the lowered position, the cover plates Ci and C2 cover a device through which the signatures or sheets are individually removed from the associated storage containers. The signatures 5-1 and 5-2 (FIG. 2) are removed from the storage containers and can be aligned in a spread position on the guide SD of a saddle conveyor at the front end of the signature collecting device and below the storage container.

A signature SI is withdrawn from the storage container Hl and initially placed on the saddle conveyor. This signature is then transported with the aid of a driver 20 along the saddle in the direction of the storage container H2 . The driver 20 is at the in F i g. 1 of the drawings attached conveyor chain 25 shown. The second signature 5-2 falls from the storage container H 2 onto the top of the first signature 5-1. As FIG. 2 illustrates, the signatures on the saddle conveyor are in a spread position such that the folded back of the lowest signature comes to rest on the top of the saddle or the saddle conveyor.

If a group of signatures is formed, then this group is determined according to FIG. 1 directed to the left in the direction of a binding * or stapling device. There the signature groups are aligned in a stationary position below a pair of stapling heads SH or similar binding devices. At this point, clips or other fastening elements are driven through the spine of the signatures of each group of signatures in order to complete the book corresponding to a group of signatures. In order to be able to check the signature groups determining a book, in such a way that incomplete signature groups are separated out, each of the signature groups is passed through a measurement area in the manner described below and sensed in this the position represented by the reference letters CS.

The strength in F, the measuring device shown 3 and 4 according to an embodiment of the invention is in the range CSdes signature collection device (Fig. 1), F ί g, 3 of the drawing is shown an unbound book B, which is within the measurement range in one to Check the ready position is The book B was previously moved into the measuring area by the conveyor consisting of the conveyor chain 25 and the driver 20. The measuring device 50 is equipped with a reference device 51 which triggers an effect analogous to the correct thickness of an unbound book Reference device from a flawlessly assembled, unbound book B 1, which is used as so-called standard sizes and which is held by a suitable device, such as gates 52 and 53. The plate 53 is provided with an opening 54 which is aligned with a reference radiation source 55 Reference radiation source is on a with a plate 56 equipped with an opening. In the embodiment shown in FIG. 3, the reference radiation source 55 consists of a radioactive material which emits a bundle of beta particles radioactive chlorin 36, preferably at a low radiation level (for example, 2-lOMillicurie) used the reference beams 57 extend from the reference radiation source 55 through the book B 1. the energy of the reference beam 57 as they exit from the book B 1, is a Function of the book thickness.

The measuring device 50 is further provided with a sensor device 61 in order to guide a further high-energy beam through each unbound book to be measured, so through the book B assembled by the signal collecting device. The sensor device 61 is equipped with a measuring radiation source 62 which is matched to the reference radiation source 55 and is fastened to a plate 63 forming part of the saddle SD. The plate 63 is provided with an opening 64 through which the measuring beams 65 are directed. The bundle of rays from beta particles passes through each unbound book B when the respective book passes the measurement area CS.

The two bundles of rays, ie the reference rays 57 and the measuring rays 65, both impinge on a single filter device with a sensor element 66. The sensor device can consist of a crystal of anthracene, sodium or other material which luminesces when irradiated by beta particles and which generates light, the intensity of the light being a function of the energy of the incident rays. The sensor element 66 is arranged in the immediate vicinity of an amplifier 67, which can have the form of a photo-electron amplifier. The amplifier 67 generates an electrical signal which corresponds to the light output of the sensor element 66. This electrical signal is fed to a comparator circuit 68 in such a way that the reference beams 57 are compared with the measuring beams 65. In this way a comparison can be made between the book B 1 used as a reference and the

Book B to be measured can be achieved. The output signal of the comparator acoustic signal 68 is fed to the control circuit 71 of the signature transmitter. An electromagnet 40 serving to control the binding device is located within this circuit.

The measuring device SO is also provided with a device 11 by means of which the two beams, ie the reference beams St and the measuring signals a1, are cyclically interrupted. The phase of the cyclically operating interrupter elements is preferably offset by 180 ". The device 72 is provided with an electric motor or with another drive 73 which has a rotating shaft 74. Two disks 75 and 76 are attached to the shaft. The shaft 74 is essentially parallel to the paths of the radiation bundles 57, 65. The disk 75 extends in the path of the bezels 57, while the disk 76 extends in the path of the measuring beams 65.

The disrupting or chopping disks 75 and 76 are shown in Figure 4 of the drawings. the Disk 75 consists of four quadrants 81, 82, 83 and 84. Quadrants 81 and 83 are opposite one Beta particle beam permeable, while the segments or quadrants 82 and 84 face one corresponding bundles of rays are opaque. The other disk 76 is of a comparable structure and has two pervious segments or quadrants 85 and 87 as well as two opaque quadrants 86 and 88 on. The relative positions of the two disks on the shaft 74 are shown in FIG. 4 of the drawing can be seen. the Reference rays 57 are interrupted by disk 75 during those time intervals during which which the measuring beams 65 pass through the disk 76 without hindrance and vice versa.

The operation of the in F i g. 3 can be seen with reference to the output pulse waveforms shown in FIGS. 5-7. In Fig. 5 of the drawing shows the output impulses 91 corresponding to the output signal of the amplifier 67, which are generated by the excitation of the sensor element 66 by the reference beams 57. The output signals 91 form a series of electrical pulses of constant amplitude, the amplitude of these pulses being a measure of the thickness of the book B 1 used as a reference.

In Fig. 5 of the drawing, which shows the conditions for a measured book of perfect thickness, the electrical output signal of the amplifier 67, generated by energizing the sensing element 66 with the aid of the measuring beams 65, is represented by the output pulses 92 which were assumed that the book B was correct Thickness, which is why the two radiation sources, ie the reference radiation source 55 and the measuring radiation source 62, generate adapted outputs, the output pulses 92 are the output pulses 91 corresponding. By using the interrupting disks 75 and 76, however, the phase of the two output pulses is offset by 180 °. As a result, the overall output signal of the amplifier 67 has the form of the output pulses 93. These have an average value which is reproduced by the output signal 94.

F i g. 6 of the drawing is F i g. 5, however, represents the output signal of the amplifier 67 for a book which is thicker than the book B 1 used for the reference. While the output pulses 91 remain unchanged, the amplitudes of the output pulses 95 are considerably reduced for the search to be measured . As a result, the output of the amplifier 67 is a pulsating and changing signal

s amplitude in the form of the output signal 96. The Output signal $ 6 has the form of output signal 97 after averaging.

In Fig. 7 shows an output signal of the amplifier 67 when measuring a book B which is in the

To comparison to book B t is too thin According to the illustration , the normal output pulses 91 and the excessive output pulses 98 result in a pulsating output signal 99 which, after adjustment, has the form of the output signal 100 for displaying a book that is too thin. With the help of the measuring device 50, it is possible to show a difference in thickness between the book B 1 and the book B to be measured, where the pin sheet corresponds to paper used for the production of normal books is enabled on the operating speed of the conveyor of the signature collection device. So there can be books with essentially any

2 = · working speed can be measured in passing. Switching to a book of varying thickness kn ^s n be effected within a very short time simply by the book used as a reference element B 1 by one another

to thickness replaced. The measuring device 50 can therefore be adapted very quickly.

A measuring device 110 according to a further embodiment is shown in FIG. 8 of the drawing. In this measuring device, some of the components of the measuring device 50 explained in connection with the embodiment according to FIGS. 3-7 are used. The measuring device 110 is also shown in the measuring area CS and is used to sense each book B. The conveyor is represented by the saddle SD, the conveyor chain 25 and the driver 20. The measuring radiation source 62, which is preferably designed as a beta particle radiation source, is aligned with respect to the opening 64 in the plate 63 of the saddle. The sensor device 61 for sensing the measuring beams 65 in turn consists of a crystal or a sensor element 66 which has a luminescent effect due to the impact of a beam of beta particles. A photosensitive device in the form of the amplifier 67 is located near the sensor element 66 and generates an output which corresponds to the energy of the measuring beams 65 when these beams take the path through the book B.

The measuring device 110 is not provided with a

mechanical breakers or equipped with breaker disks of the type which are referred to were explained on Fig.3 of the drawing. Of the Measuring device 110 is assigned an alternating current source 111, which is connected to the primary winding 112 of a Transformer 113 is connected The secondary winding 114 of the transformer has a tap on, which preferably leads to the ground of the system. An end connection of the secondary winding 114 is with the Amplifier 67 is connected and forms the current source for this, so that the output signal of the amplifier Represents alternating current signal

The reference device 120 of the measuring device 110 differs essentially from the arrangement which with reference to the measuring device 50

was explained. It consists of a resistor 121. which with a number of taps 122, 123 and 124 is provided. Resistance 121 gin endaflsehluß is connected to one end of the secondary winding 114, while the other end of the s Resistance is returned to the mass of the system. The resistor 121 is thus through the same Excited input signal, which is fed to the amplifier 67. However, this happens with a Phase shift of 180 °.

leather of the taps 122-124 of the resistor 121 is connected to the input terminal of a selector switch 125 which has a movable contact 126 . The movable contact 126 of the selector switch is in turn connected to an input of the comparator circuit 68. The second input of the comparator circuit 68 is connected to the output of the amplifier 67. As in the case of the previously described embodiment of the present invention, the Vergieicherschaitung ATS is connected to a control circuit 7i for the signature collection device.

The measuring device 1 10 according to F i g. 8 of the drawing requires calibration. Assuming that the signal collector. in which the measuring device is used, is used to join books of three different thicknesses within a given run, then a faultlessly assembled book B of a certain thickness is introduced into the measuring area in such a way that it assumes the position shown in FIG . The selector switch 125 is brought to a first position so that its movable contact comes to rest against one of the taps 122-124. This tap is then adjusted until the comparator circuit 68 does not generate an effective output signal for the control circuit 71. A book of the next desired thickness is then introduced into the measuring area, after which the selector switch 125 is again set in order to produce a connection from a further tap on the resistor 121 to the comparator circuit 68. The calibration is now repeated. Also with respect to a third book with a dritlpn DirlcpmaR is made dip ^"1 Firhiintr. In this way, the reference device 120 of the measuring device 110 is set for each of the three books of different thicknesses.

If, during operation of the device, it should be necessary to change from one book thickness to another, then the measuring device can easily be adjusted by simply operating the selector switch 125 . The measuring device 110 according to FIG. 8 of the drawing consequently works in a manner which is essentially comparable to the method of operation of the device shown in FIG its taps is generated and not by a second bundle of rays, as is the case with the one shown in FIG. 3 device shown is used. Furthermore, the requirements for the comparator circuits of the two devices are essentially the same, except that the shapes of the output signals may be somewhat different since the AC power source 111 has a substantially sinusoidal output instead of that shown in Figures 5-7 limited momentum

In Fig. 10 of the drawing is a meter 170 shown; this measuring device is preferably on generated.

In the measuring device 110 shown in Figure 8 of the drawing, the synchronized, periodic interruption of both the comparison circuit 68 from the reference device 120 and the Sensing device fed signals through the alternating current source 111. It can be seen, however, that a comparable circuit in the output circuit of the amplifier 67 can be used. This applies equally to the embodiments according to the invention described below.

In Fig. 9 of the drawings, a measuring device 130 is shown in which some of the features of the systems of Figs. 3 and 8 are combined. The measuring range CS of the measuring device 130 essentially corresponds to that of the measuring device 110 and has a sensor device 61 with a measuring radiation source 62. This is attached to the saddle SD and directs a beam of rays, preferably of beta particles, through one half of each book B when it crosses the measurement area. The exiting measuring beams 65 strike a crystal or another sensor element 66 which becomes luminescent by the beam. The light output of the sensor element 66 is converted into an electrical signal by the amplifier 67 or another photosensitive device connected to the comparator circuit 68.

In the measuring device 130 , a reference device 140 is provided with a holding body 141 on which a book B 1 of faultless thickness serving as a reference is placed. The reference device is also provided with a reference radiation source 155 emitting, for example, beta particles, which directs a beam of rays through one half of the book B 1 in such a way that the beam of rays hits a crystal or some other luminescent sensor element 166 . The light output of the sensor element 166 is converted into an electrical signal by an amplifier 167. The electrical signal from the photosensitive amplifier 167 is fed to the comparator bracket BM

In the case of the in FIG. 9 of the drawing shown measuring device 130 , the two amplifiers 67 and 167 are fed by a alternating current source U1. The two amplifiers are preferably excited in mutually opposite phases in order to be able to bring about a simpler comparison in the comparator circuit 68. It should be noted that a mechanical interrupter of the type shown in FIG. Construction shown in Figure 3 can be brought in the model shown in Figure 9 the measuring system used.

The in F i g. The measuring device shown in FIG. 9 of the drawing works essentially in the same way as that in FIG. 3 of the drawing reproduced measuring device 50 with the exception that the two separate output signals of the amplifiers 67 and 167 are compared in the comparator circuit 68 instead of first being combined in the sensor device of the device. As in the case of the embodiment already described, a change in the book thickness can easily be carried out by simply replacing the book B \ serving as a reference with another book of different thickness.

a signature collecting device, which can be used for side-staple binding or for full binding instead

the saddle binding is used. A measuring area CS is in turn assigned to the gin device. Each book B of signature groups moves in a flat position along a support SS. The measuring device has a measuring radiation source 62 which, in the previously described way, measuring beams 65 through an opening ifi of the plate-shaped! Support 55 passes through. The measuring beams strike a crystal or a Fahler element 66 which, as in the case of the embodiment already mentioned, is equipped with a photoelectron multiplier or amplifier 67.

The measuring device 170 is equipped with two separate reference devices. Each of these reference devices is capable of generating an energy analogous to the flawless thickness of an unbound book. Two reference areas are provided in order to be able to carry out the rapid switchover from a signature group or a book of a certain thickness to a second book of a second predetermined thickness.

The first reference device of the measuring device 170 consists of a support plate 171 on which a first book B 1 is placed. A reference radiation source 155 is arranged on the platen 171 and directs reference rays 157, preferably of beta particles, through an opening in the platen and further through the book B 1 used as a reference, so that the beam hits a sensor element 166 . The sensing device for the first reference device is equipped with an amplifier 167.

The second reference device in the measuring device 170 is provided with a second support plate 172 on which a second book B 2 is located. The thickness of this book differs from the thickness of book B 1. A reference radiation source 255 directs reference rays 257 through an opening in the platen and finally through book B 2 used as a reference, so that the beam hits a sensor element 266 . The luminescence of the

cs 266 is through an amplifier 20? displayed or played back.

In the measuring device 170 , the amplifier 67 is excited by a current source 111. The power source is also connected to the movable contact 173 of a stage of a two-stage selector switch 174 . One of the fixed contacts, which can be brought into contact with the movable contact 173 , is connected to the amplifier 167 . The other fixed contact, which can be brought into abutment with the movable contact 173 , is connected to the amplifier 267. This can also be designed as a photoelectron amplifier in the present case.

The selector switch 174 is designed in two stages and has a second movable contact 175. The movable contact is connected to an input circuit for a Comparative loudspeaker 68 connected. One of s fixed or fixed contacts, which can be brought into connection with the movable contact 175, is connected to the output of amplifier 167. The other fixed contact of this stage of the Selector switch 174 is connected to the output of the amplifier

ίο 267 connected. As in the case of the already described embodiments of the present invention, the comparator circuit 68 is connected to the control circuit 71 having the electromagnet 40 in the binding area.

When the selector switch 174 is in the position shown in FIG. 10, the measuring radiation source 62 generates measuring beams 65 which are passed through book B crossing each Hpn measuring area CS . The energy level of the exiting Sirahlenbündis is measured by the sensor element 66 and is converted into an electrical signal via the amplifier 67. This electrical signal is fed to the comparator circuit 68. The energy corresponding to the error-free thickness of a book (the book ßl), which is generated by the reference radiation source 155 and by the sensor element 166 or the amplifier 167 , is also fed to the comparator circuit. The two electrical signals are compared within the comparator circuit and, if necessary, used to generate a control signal. This control signal operates the control circuit 71 to prevent the binding of defective books.
In order to convert the circuit according to FIG. 10 of the drawing to the measurement of books of different thicknesses, the selector switch 174 is actuated in such a way that the second reference device becomes effective. This consists of the reference radiation source 255, the sensor element 266 and the amplifier 267. The

■ »ο Actuation of the selector switch 174 is the only work step which is necessary for a change in the book thickness. If a third book of a further different thickness is to be joined together by the same binding device, then book B 1 of the first reference device can be replaced, while book B 2 serves as a standard or reference book. As a result, there is no downtime in the facility that requires changing or readjusting for books of different thicknesses.

If further steps of the selector switch 174 are used, further reference devices can of course also be assigned to the measuring device.

For this purpose 3 sheets of drawings

Claims (2)

Claims; J, measuring device for periodically operable signature devices for checking the signature groups determining a book for completeness, in which the signature groups in unbound form are conveyed one behind the other along a predetermined path through a measurement area to a binding device and are bound in this in their infeed sequence, with a control device for controlled actuation of the binding device as a function of control signals derived by measuring the thickness of the signature groups by means of radiation, characterized in that a sensor element (66) reacting to the beam (57, 65) is arranged in the beam path of two radiation sources, a reference radiation source (55) and a measuring radiation source (62) , wherein the beam path of BezugsstrahluDgsquelle (.. 5-1, 5-2.) an inserted between it and the Fühlereiement ^ (66), error-free assembled signature group of the book used as a reference (Bi) penetrates laundri while the beam path of the measuring radiation source (62) penetrates a signature group of the Ruches (B ) to be measured between it and the sensor element (66), so that the sensor element (66) generating an electrical signal is assigned an amplifier which is connected to a comparator circuit (68) for Comparison of the signals triggered by the reference beams (57) and the measuring beams (65 *) and that the Vergletcherscb.-Jtung (68) is connected to the control circuit (71) for the controlled actuation of the binding device. 2. Measuring device for periodically operable signature collecting devices for checking the signature groups determining a book for completeness, in which the signature groups in unbound form are conveyed one after the other along a predetermined path through a measuring area to a binding device and are bound in this in their infeed sequence, with a control device for controlled actuation of the binding device as a function of control signals derived by measuring the thickness of the signature groups by means of radiation, characterized in that a sensor element (66) reacting to a beam (65) is arranged in the beam path of a measuring radiation source (62), the measuring beams of which are between the sensor element (66 ) and the Meßstrahiungsquelle (62) insertable signature group (5-1, 5-2 ...) of the book to be measured (B) penetrate that the sensor element (66) generating an electrical signal is assigned an amplifier (67) that for Gener For electrical reference signals corresponding to an error-free signature group (5-1, 5-2 ...), a tap (122, 123, 124) is provided on a resistor (121) connected to a voltage source (111) which, like the amplifier (67 ) is individually switchable with a comparator circuit (68) for comparing the signals triggered by the measuring beams (65) and the reference signals, and that the comparator circuit is connected to the control circuit (71) for controlled actuation of the binding device. Pie invention relates to a measuring device according to the generic term of claims 1 and 2, A measuring system for measuring the thickness of a material made, for example, of paper, plastic, metal, etc. is known. existing material web, in which this in the Beam path of a radiation source is brought and this passes through the thickness changes of the web forming material trigger a change in the energy of the rays or the bundle of rays, because the particles passing through the material lose a certain amount of their energy. In systems of this type it is always necessary to enter new comparative values in the system if the paths are different Thickness to be measured. Accordingly, the system cannot continuously, for example in association with an assembly line manufacturing process. Measuring systems of the type described above can be found in general use to measure the thickness of the moving web of material such that a Drive device for changing the speed of the material web is controlled when changes consist of thickness. Such devices are suitable for periodically operated signature collecting devices of the type in question Measuring systems do not have new calibrations of the system when measuring different material webs must be made. When collecting signature groups in the form of books, it is desired, with the help of a single sponsor, one of those To process chain conveyors, buckers or brochures of different thicknesses in the assembly line process without that time-consuming adjustments have to be made between the individual book sizes or book thicknesses. The object of the invention is based on this therein, a measuring device of the type in question to be trained so that these the assembly line manufacturing process when collating and binding or stapling of books etc can be assigned, so that a thickness measurement is possible without between Changes to the measuring system are to be made for the individual book runs. The solution to this problem is characterized by the features according to the identification part of the Claim 1 as well as by the features according to ♦ 5 the characterizing part of claim 2. With the help of the measuring device it is possible to bind, staple etc. books, brochures or to control the same signature groups without a large expenditure of time for the conversion of the so measuring device on books of different thicknesses would be required. The measuring device works without the mechanical measuring devices own inertia, the Measurement accuracy can be adjusted to at least two sheet thicknesses according to a signature. The measuring device is responsible for the measuring accuracy with the aid of bundles of energy beams Quality. As a result of the simple structure of the reference device, the reference element either by a Reference book or by a previously adjustable one w reference value is given, the measuring device can im be driven substantially continuously when a passage of books of different thickness takes place. The measuring device can so the further Flow production processes for the entire plant be sorted. The accuracy of the measurement ensures that the actuation of the binding device is interrupted immediately if a comparison of the thickness of the to be measured