DE3613982C2 - - Google Patents

Description

The invention relates to a thickness measuring device for Foils that are fed over a roll with a first beeper, which is one of the thickness of the one on the reel provides a signal that is dependent on the running film tape, with a second beeper, one of the speed of the Role-dependent reference signal supplies and with a Evaluation device, which consists of the difference between the Signal generators supplied signals an indication for the Thickness of the film forms.

Such a thickness measuring device is from DE-PS 34 35 860 known. In this known thickness measuring device that is Reference signal by means of the second signal generator thereby won that a sliding roller assigned to it on the part the surface of the roll is arranged by the film not covered. Thus, the reference signal is at the known thickness measuring device of the peripheral speed Role proportional. However, it is known with this one Thickness measuring device has the disadvantage that when measuring relatively thin foils the peripheral speed at the location of the first Signal transmitter is approximately the same as the peripheral speed at the location of the second signal generator, so that the Evaluation device a difference between the two Signals can no longer detect. In addition, that known thickness measuring device in the range of its resolution limit, d. H. if the film thickness can just be measured, Has measurement inaccuracies caused by dust deposits or wear and tear, in particular of the reference signal Detecting second signal transducer are conditional.

The magazine "Feinwerktechnik", 1966, issue 11, p. 518 through 522 shows an apparatus for measuring the circumference of Workpieces with a large diameter. It includes a Friction roller directly from the circumference of one to be measured Workpiece is driven. When moving the friction roller becomes an impulse disc through gear transmission taken with the movement by photoelectric means transformed into electrical impulses, which then become a Evaluation device are fed.

A second one corresponding to the peripheral speed Signal is in the known measuring device by a Start-stop casing generated which after a whole Rotation of the workpiece table illuminates the Photocell interrupted by the lamp. To the exact It comes from the reference position of this signal to the measured signal in this known measuring device, however, not crucial, as there is a deviation due to the large workpiece diameter only has a minimal effect.

In contrast, the invention is based on the object of a Thickness measuring device of the type mentioned at the beginning further develop that there is a sufficient Resolving power for measuring foils with extremely small thicknesses achieved.

This object is achieved in that the The first signal transmitter is driven via a speed-increasing one Gear is coupled to the roller and that the second Signal transmitter directly from the drive roller of the roller is driven.

The increase in resolving power according to the invention is on the one hand through the use of a speed-increasing Transmission achieved, whereby one of the second signal generator detected number of pulses in a purely mechanical manner and is multiplied with relatively simple means. To the another is determined by the arrangement of the second signal transmitter on the drive shaft of the roller, its angular speed used as a reference signal. This reference signal possesses compared to that from the peripheral speed of the roller obtained signal the decisive advantage that it is from Impurities or abrasion of the roller no longer depends. Even films with a thickness of 10 µm can be used with a corresponding translation with a Measure accuracy better than 1%.

Such a reference signal that is as constant as possible is particularly desirable in combination with the speed-increasing gear. Through the processing performed by the evaluation difference between the measurement signal of the first signal transmitter (pulse train I 4 in Fig. 7) and the reference signal (pulse train I 1 in Fig. 7) in fact occurs by a distorted reference signal (change of the time T _m) is also to a falsified measurement of the number of pulses from I 4 . If the circumference of the roll is known exactly, ie if it has been precisely measured, then absolute measurements can also be carried out on very thin foils with the aid of the measuring device according to the invention. In this case, the number of pulses (I 4 ) measured by the evaluation unit can be set in precise relation to the film thickness.

In the following the invention is explained in more detail with reference to a drawing explained. In detail shows

Fig. 1 shows a known thickness gauge for films with two signal transmitters in a side view,

Fig. 2 shows the thickness measuring device according to Fig. 1 with evaluation device in a plan view,

Fig. 3 shows an inventive thickness gauge with two signal transmitters, and a speed-increasing gear in a side view,

Fig. 4 shows the thickness measuring device according to Fig. 3 with evaluation device,

FIG. 5 shows a thickness measuring device corresponding to FIG. 3 with a calibration roller in side view and FIG

Fig. 6 is a timing diagram of the signal generator.

In the known thickness measuring device according to FIGS. 1 and 2, a film strip 2 , for example a folded film tube, is guided over a driven roller 1. A disk 4 is seated in a rotationally fixed manner on the drive shaft 3 of the roller 1 with slot-shaped marks arranged on the outer circumference and arranged at equal intervals. This disk 4 is assigned a sensor 5 , which can be designed as a light barrier.

A friction wheel 6 runs on the surface of the film strip 2 running on the roll 1 and drives a disk 7 with slot-shaped marks arranged at equal intervals on the outer circumference. The pane 7 is assigned a sensor 8 , for example a light barrier.

The marks detected by the two sensors 5, 8 when the disks 4, 7 rotate are received as periodic pulses by an evaluation device 11 and evaluated. In Fig. 6 the pulse sequence for the two signal generators 4, 5 and 7, 8 is shown. At a constant angular speed of the roll 1 , the signal generator 4, 5 delivers the pulse sequence I 1 and the pulse generator 7, 8 either the pulse sequence I 2 or I 3 depending on the thickness of the film strip 2 . Since the circumferential speed of the film strip on the friction roller 6 is lower with a thin film strip than with a thick film strip, a certain number of pulses I 1 of the signal generator 4, 5 are a small number of pulses I 3 for a thin film strip and a large number for a thick strip Number of pulses assigned to I 2. The difference between the pulses I 2 , I 3 corresponds to the difference in thickness between the two bands. In the case of a small number of pulses I 2 , I 3 , however, this difference cannot be detected by measurement.

The thickness gauge in the inventive embodiment of Fig. 3 and 4 of Fig. 1 and 2 differs from the conventional thickness gauge in that, 8, a speed-increasing gear 12 is disposed between the signal generator 7 with its friction roller 6, a friction roller 13 rests against the film strip 2. By using such a gear 12 , the signal generator 7, 8 delivers pulses I 4 with a much higher pulse repetition frequency. The high resolution achieved in this way makes it possible to measure a certain number of pulses Ix , which correspond to the change in thickness, to be recorded.

For very precise measurements or very thin tapes, it is advisable to calibrate the thickness measuring device. Such a calibration allows tolerances of the friction rollers and the speed-increasing gear to be taken into account. The calibration can be carried out in such a way that, as shown in FIG. 5, a reference roller 10 , the circumference of which is precisely known, is used instead of the roller 1 . When using such a roller 10 , the number of pulses I 4 can be assigned to the scope of the reference roller 10 .

Claims (2)

1. Thickness measuring device for foils that are guided over a roll, with a first signal transmitter, which supplies a signal dependent on the thickness of the film strip running on the roll, with a second signal transmitter, which supplies a reference signal dependent on the speed of the roll and with an evaluation device which uses the difference between the signals provided by the signal transmitters to display the thickness of the film, characterized in that the first signal transmitter (7, 8 ) is drive-coupled to the roller ( 1 ) via a speed-increasing gear ( 12) and that the second signal transmitter ( 4, 5 ) is driven directly by the drive shaft ( 3 ) of the roller ( 1 ). 2. Thickness measuring device according to claim 1, characterized in that a reference roller ( 10 ) with a precisely known scope is used as a roller, which has a plurality of marks arranged at its edge at equal intervals.