DE3300320A1 - Monitoring and evaluation device for fault and multiple-sheet monitoring and measurement of thickness - Google Patents

Abstract

The invention relates to a monitoring and evaluation device for fault and multiple-sheet monitoring and measurement of the thickness of sheet-like or web-like materials in processing and manufacturing machines. The object of the invention is to produce a vibration-compensating device which requires fairly small sensors and carries out evaluation in such a way that only comparative values for one side of the transporting line are required. The object is achieved by having at least three sensors on the basic body, arranging the latter to the side of the material transporting line, having the object of the measurement which is to be monitored in one of the two outside sensors at the time of measurement and having downstream of this arrangement an evaluation device, serving for the evaluation and determination of the measured values with regard to changes in measured values due to mechanical vibration and changes due to the presence of the object of the measurement in the sensor. As a result of the invention, the outlay or material and assembly time are reduced and the dimensions of such devices are reduced. Sensitivity can also be increased by the possible use of inductive sensors. <IMAGE>

Description

Control and evaluation device for single and multiple sheet

control and thickness measurement The invention relates to a control and evaluation device for Pehl and multiple sheet control as well as thickness measurement of sheet or web-shaped materials in machining and processing machines.

According to DD-PS 149.053, a capacitive control and evaluation device is known on bookbinding and printing machines where the one capacitor plate of the capacitive Transducer is separated in two places and both capacitor plates each located on a base body. The main body is on both sides elastically mounted.

During the measurement process, the substrate is between the middle part of the separated capacitor plate and the second capacitor plate.

The disadvantage here is that the base body extends over the entire width of the printing material and beyond that extend mouth, because due to the evaluation method the two comparison capacitors are located on both sides of the printing material have to. In addition to the complex structure, this arrangement requires additional technical equipment Measures to prevent mechanical vibrations along the body with stronger oil, shaking tulgen.

The aim of the invention is a control and evaluation device to create, which requires less effort, has smaller dimensions and the assembly effort is reduced, the technical object of the invention is therein, the measurement encoder arrangement in the machine and the associated evaluation circuit to be designed so that the base body with the associated transducers is kept small and the evaluation by the evaluation circuit takes place in such a way that only comparison values one side of the transport path are required.

The object is achieved in that there are at least three transducers are on the base body and this is on the side of the transport path of the materials is arranged, as well as -sich the test object to be checked at the time of the measurement is located in one of the two outer transducers and this arrangement is one for Evaluation and determination of the measured values for changes in measured values due to mechanical vibrations and changes due to the presence of the device under test in the transmitter Evaluation circuit is downstream.

For the implementation of a non-contact measurement, it is advantageous to that capacitive transducers are arranged on the base body.

An increase in the sensitivity of the device is achieved by that inductive transducers are arranged on the base body.

imine increased sensitivity achieved with a non-contact measurement one in that capacitive and inductive transducers are arranged on the base body are.

The transducer arrangement is effective in that the Base body arranged inductive transducers with these opposite Sensors are inductively coupled.

It is advantageous to use dynamic pickup systems as inductive transducers to use. The control and evaluation device is preferably designed in such a way that that in the evaluation circuit the signals coming from capacitive transducers Y12 Y 2 'Y3 and Y4 comparative, capacitance measuring bridges each an amplifier and each of these is followed by a rectifier and the rectifier outputs are connected to a computing circuit. The arithmetic circuit will be useful so chosen that in the arithmetic circuit the outputs C1 and C2 of the first and second A first subtraction circuit is connected downstream of the rectifier and this is a coefficient potentiometer, a multiplier following this, the output of which is sent to a division circuit is connected, a further second connected to the output of the division circuit 3ubtrahierschaltung is arranged downstream as well as that with the coefficient potentiometer connected input of the Multikplika sector together with the output C1 of the first Rectifier via a summation circuit to a second input of the division circuit is connected, and that the output of the third rectifier C3 to the second Input of the subtracting circuit following the division circuit is connected.

A control and evaluation device also proves to be useful, in the, the coming from the inductive transducers signals Y1, T2 and Y3 Y comparative, inductivity measuring bridges each have an amplifier and this each a rectifier is arranged downstream as well as the outputs of the rectifier judge are connected to a computing circuit. To do this, you design the arithmetic circuit Favorably so that the outputs of the first and second rectifier one first subtraction circuit connected downstream and this via a coefficient circuit is connected to the first input of a summation circuit that the second input the summation circuit with the output of the first rectifier and the output the summing circuit to the first input of a following second subtracting circuit and the output of the third rectifier to the second input of the second Subtracting circuit are connected.

The computing circuit is also effective in that the outputs the rectifier is assigned an analog / digital converter and this are connected to a digital computer. It is beneficial if at least one of the base bodies is stored in elastic filler and with this in one Housing is housed.

The WIeßwertgeberanordnung can be designed so that the number the transducer on the base body, over three transducers, with the number the format of the materials to be checked is identical. It is also beneficial the housing with the base body mounted in the elastic filler at right angles to the direction of transport adjustable to attach to a fastening element.

The invention is intended below with the aid of some examples are explained in more detail: In the accompanying drawings show: Wig. 1: the schematic Arrangement of capacitive transducers, lilly. 2: the schematic Arrangement of the inductive transducers, Fig. 3: the evaluation circuit for the capacitive Measuring transducer, Fig. 4: the evaluation circuit for the inductive measuring transducer.

The arrangement of the capacitive transducers shown in FIG is attached to the side of the machine. The serve as capacitive transducers Capacitor plates 1, 2 and 3. They are attached together on the base body 4 and stored in the housing 5 by the elastic filler 6 located therein. Foam, for example, could be used as filler 6. Through this, that the storage of the base body 4 is equally present at all surface points is, vibrations along the longitudinal axis of the base body 4 cannot occur.

The counter electrode to the capacitor plates 1, 2 and 3 is used Capacitor plate 7. Are caused by vibrations of the machine vibrations along the longitudinal axis of the capacitor plate 7 to be expected, then this can be through a elastic mounting of the capacitor plate 7 in the feed table can be prevented. Of the Transport of the test object 8 takes place in the representation of Figures 1 and 2 in the Drawing plane into it. The capacitive transducers 1, 2 with the common counter electrode 7 provide the comparison values Y1 and Y2. The measured value Y3 of the test object 8 supplies the capacitive transducer 3, which is also the capacitor plate as a counter electrode 7 owns. Separate counter electrodes, which are shared on a further base body 4 are applied, were also possible. All values (Y1,, y2, y3, y4).

are fed to an evaluation device 10.

The Pigur 2 shows an arrangement of inductive transducers. In this embodiment of the invention, there are three on the base body 4 Inductors. The first coil 13 and the second coil 14 supply the comparison values Yl and Y2. The measured value Y3 is obtained by the third coil 15.

The change in inductance of the coils according to the location of the Coil to the feed table 9 is carried out by the scanning elements 16, 17, 18, each are connected to the housing 5 by a spring 12. The base body 4 with the Spools 13, 14, 15 are stored in the fuel 6. The sensing elements are inside the bobbin movably attached, at the top of the scanning elements 16, 17, 18 measuring wheels can also be located. The values yl, to Y2 Y3 become an evaluation device 11 supplied.

When measuring objects 8 that have a different width or which have different formats, it is advantageous to have so many more transducers to be arranged transversely to the transport direction so that all formats can be measured. The control of the transducers then takes place in such a way that three adjacent Measuring transducers deliver values and the test object 8 is in an outer one of the three measuring transducers is located. It is also possible that the housing can be adjusted using a fastening element to attach.

The evaluation circuit for the capacitive transducer arrangement is shown in FIG. It has the task of using the measured comparative values Y1 and Y2 when the position of the base body 4 is changed as a result of oscillations Capacitor plate 7 the current position of the third capacitor plate 3 in relation to the capacitor plate 7 and thus the capacity to be determined without the DUT 8 in the dielectric would exist. In addition, it must match the measured value Y3 with that of the comparison values Compare the values determined by Y1 and Y2.

In the evaluation circuit 10, the value to be determined is determined on the basis of the following relationship: It is assumed that the inert to be determined is to be compared with a sloping position of the base body 4 with a series connection of C1 and the respective adjacent differential capacitances of the three transducers.

After the capacitive transducer in the from a high frequency generator 33 fed capacitance measuring bridges with the nominal capacities 19 contained therein, 20, 21 were compared, the signals of the unbalanced measuring bridges pass over Amplifiers 22, 23, 24, rectifiers 25, 26, 27 assigned to them in each case. The signals Ci, C2 and are now at the outputs of the rectifiers 25, 26, 27 C3, which is determined by the following arithmetic circuit according to the above relationship from C3 and the comparison with C3.

First, the difference between C2 and Ci is determined by the subtracting circuit 28 formed. The coefficient potentiometer 29 multiplies the output signal with 0.5. After that, the signal goes to a multiplier 30. This is where the signal multiplied by the Ci signal. The C1 signal is sent in parallel to this in the summation circuit 31 is added to the output signal of the coefficient potentiometer. Both signals, the output of the multiplier 30 and the output of the summation circuit 31 are passed to a division circuit 34 and divided there. That generated Signal now corresponds to C3 and is in a subtracting circuit 32 with C3 signal compared. The output signal A of the Subtrahiersohaltung 32 corresponds to the change in capacitance through the test object 8 in the third Keßwertgeber.

In Figure 4, the evaluation circuit 11 is for the inductive Mef3wertgeber shown, According to the fact that L3 is out of a ranks circuit composed of L1 and the two differential inductances, results the relationship L3 = L1 + F (L2 - L1) The factor F reflects the relationship between the very concrete change in inductance and the anchoring of L3 again.

It must be determined experimentally.

After the inductive transducers in the inductivity measuring bridges with the nominal inductances 35, 36, 37 were compared, the output signals the unbalanced measuring bridges through the amplifier 22 following each measuring bridge, 23, 24 amplified and rectified by the rectifiers 25, 26, 27. In the The following arithmetic circuit is the output signals of the first rectifier 25 and of the second rectifier 26 in the subsequent subtracting circuit 38 subtracted and the difference signal is through a subsequent coefficient circuit 39 multiplied by the factor F. If the factor F is less than one, then contains the coefficient circuit is a coefficient potentiometer 29 and is the factor If P is greater than one, then, for example, a DC voltage amplifier can be used will.

The difference signal changed by the factor F then reaches a Summing circuit 40, in which this signal with the output signal of the first rectifier 25 is added, the summed signal is then in a subtracting circuit 41 with the output signal of the third rectifier 27 by forming the difference compared. The desired output signal is now at the output of the subtraction circuit A at.

with the output signal A the thickness can be measured with a display device of the MeBobåect are displayed. Using downstream Schmitt triggers a missing and multiple sheet control is to be implemented. The measurement takes place in the machine cycle.

Very high for measurements under the influence of mechanical vibrations Is the frequency at which the signal propagation times can influence the measurement result it is necessary to switch on delay elements in the shorter signal paths.

Designation 1 capacitor plate 2 capacitor plate 3 capacitor plate 4 Base body 5 Housing 6 Filler 7 Capacitor plate 8 Measurement object 9 Feed table 10 evaluation circuit 11 evaluation circuit 12 peder 13 first coil 14 second coil 15 third coil 16 sensing element 17 sensing element 18 sensing element 19 first nominal capacitance 20 second nominal capacitance 21 third nominal capacitance 22 first amplifier 23 second Amplifier 24 third amplifier 25 first rectifier 26 second rectifier 27 third rectifier 28 subtraction circuit 29 coefficient potentiometer 30 Multiplier 31 summing circuit 32 subtracting circuit 33 high frequency generator 34 division circuit 35 first nominal inductance 36 second nominal inductance 37 third nominal inductance 38 subtracting circuit 39 coefficient circuit 40 summing circuit 41 Subtraction circuit

Claims (14)

Claims (1.4 control and evaluation device for Xehl and multiple sheet control as well as thickness measurement of sheet or web-shaped materials with transducers attached to a common, elastically mounted base body, characterized in that there are at least three transducers on the base body (4) are located and this is arranged on the side of the transport path of the materials is, as well as the object to be checked (8) at the time of measurement in one of the two outer transducers is located and this arrangement is one for evaluation and determination of the measured values for changes in measured values due to mechanical vibrations and changes due to the presence of the test object (8) in the transducer Evaluation circuit (10, 11) is arranged downstream. 2. Control and evaluation device according to claim 1, marked in that capacitive cwertgeber are arranged on the base body (4). 3. Control and Ausverteeinrichtung according to claim 1, characterized in that inductive ewertgeber are arranged on the base body (4). 4. Control and evaluation device according to claim 1, characterized in that capacitive and inductive transducers are arranged on the base body (4) are. 5. Control and evaluation device according to claim 1, 3 and 4, characterized in that the inductive transducers arranged on the base body (4) also have these opposite transducers are inductively coupled. 6. control and evaluation device according to claim 1, 3, and 4, characterized in that dynamic pickup systems are used as inductive transducers will. 7. control and evaluation device according to claim 1 and 2, characterized in that in the evaluation circuit (10) that of capacitive transducers Coming signals Y1, tL2, Y3 and Y4 comparing, capacitance measuring devices, respectively an amplifier (22, 23, 24) followed by a rectifier (25, 26, 27) is, as well as the outputs of the rectifiers (25, 26, 27) with. a computing circuit are connected. 8. Control and evaluation device according to claim 1, 2 and 7, gekennseichnet in that in the computing circuit the outputs C1 and C2 of the first and second Rectifier (25, 26) is followed by a first subtracting circuit (28) ttlid this one coefficient potentiometer (29), one following this multiplier (30), which is connected with its output to a division circuit (34), another to the output of the division circuit (34) connected to the second subtraction circuit (32) and that connected to the coefficient potentiometer (29) Input of the t: "multiplier (30) together with the output C1 of the first rectifier (25) via a summation circuit (31) to a second input of the division circuit (34) is connected and that the output of the third rectifier (27) C3 to the second input of the second subtraction circuit following the division circuit (34) (32) is switched. 9. control and evaluation device according to claim 1 and 3, characterized characterized in that in the evaluation circuit (11) that of the inductive transducers Coming signals Y1, J2s Y3} and Y4 comparing inductivity measuring bridges, respectively an amplifier (22, 23, 24) followed by a rectifier (25, 26, 27) is, as well as the outputs of the rectifiers (25, 26, 27) with a computing circuit are connected. 10. Control and evaluation device according to claim 1, 3 and 9, characterized in that the outputs of the first and second rectifiers are in the llechensohaltung (25; 26) followed by a first subtracting circuit (38) and this via a Coefficient circuit (39) with the first input of a summation circuit (40) is connected that the second input of the summation circuit (40) with the output of the first rectifier (25) and the output of the summation circuit (40) at the first input of a following second subtracting circuit (41) and the output of the third rectifier (27) to the second input of the second subtraction circuit (41) are connected, 11. Control and evaluation device according to claim 1, 7 and 9, characterized in that the outputs of the rectifier in the computing circuit (25; 26; 27) are each assigned an analog / digital converter and this with a digital computers are connected. 12. Control and evaluation device according to claim 1, characterized in that at least one of the base bodies (4) in elastic fillers (6) is stored and housed with this in a housing (5). 13. Control and evaluation device according to claim 1, characterized in that the number of transducers on the base body (4) has three transducers in addition, identical to the number of the itiaterials format to be checked is. 14. Control and evaluation device according to claim 1, characterized in that the housing (5) with the base body mounted in the elasticx filler (G) (4) Can be adjusted transversely to the direction of transit on a fastening element attached to it is.