DD152988B1 - METHOD FOR MEASURING THE MEASUREMENT OF LINEAR MOVED STRESS FORMING GOOD - Google Patents

Description

Field of application of the invention

The invention finds application in the manufacturing industry in particular for the diagnostic measurement of isolated wires

Characteristic of the known technical solutions

Measurement methods are known in which the body to be measured is imaged by a light source on a micrometer bar provided with HeII dark markings, and the unobstructed healing ocular markings are scanned by a photocell for mechanical reciprocation of a mirror and the generated imoulse is paid and displayed we ^r the

(DT-OS 2046513)

It has also been described as a light source parallel incident light, for example, a laser beam for Abildildung the measured body on a provided with light-dark markings matrix, which was scanned with a television camera (D ^T OS 2211 343) brings the laser device with its monochromatic light For optical scanning some advantages over the color mixture of the bulb

It is also known to use a television camera directly to pay the darkened image line and thus to determine the diameter In all cases, either incandescent lamps are used to illuminate aes Meßgutes, which have a limited life or a laser device, which is quite costly Furthermore, it is considered disadvantageous that by dusting of the optical system underexposure of the light receiver occurs, whereby Fenlmessungen arise

Object of the invention

It st goal of the invention to increase the accuracy of non-contact Druchmessermeßgerate without Verscnleißteile, such as incandescent or mechanically moving parts, use, oei simultaneous reduction in the cost of manufacture

Explanation of the essence of the invention

The invention has for its object to provide a method for beruhrungslosen diameter measurement available which works with a source parallel L chts and readjust itself in case of signs of contamination of the optics in its radiation intensity

According to the invention the object is achieved by the measured material with a true size is sharply displayed on a CCD Zeiie and evaluated by a control device and at the same time with this the guided on the CCD line light amount is kept constant

The method of diameter measurement further provides that from the video signal of the CCD line once the pulses for the actual measurement and the other a light quantity signal of the light source (designed as infrared radiator) is measured which a Gleichwertgleichnchtung and a P I controller with the setpoint specification controls the infrared radiator

exemplary

The invention will be explained with reference to the accompanying drawings

F g 1 measuring arrangement

2 shows a block diagram of the measuring arrangement

With a light source 1 (infrared radiator) and an optic 2 Meßqut3 back is illuminated with paiailelen infrared rays The sample 3 is imaged with a further optics 4 on an electronic grid 5 This grid 5 is now scanned electronically by means of control 13 and amplified proportionally in the amplifier 6 From the resulting signal, two pieces of information are now filtered out. The filter 11 is not repulsive and is not covered by the material to be measured

Light source out The trigger 12 converts the pulse train into clean rectangles with a unit amplitude In the dark pulse generation 13, the pulse sequence is now obtained together with the controller 15, which corresponds to the darkened sections on the electronic grid 5 and thus the diameter of the measured material 3 In the Zahler The second information from the amplifier б the radiation intensity, is filtered out with the filter 10, rectified with the peak rectifier 9 and compared with a predetermined setpoint 8 The difference between the setpoint 8 and The actual value from the rectifier 9 controls the intensity of the light source 1 via the controller 7. Due to the relatively long-wave radiation of the light source 1 and by regulating the intensity of the intensity with the electronic grid 5, it is clear that in the P'oportionaibereich the control in Versta ubung of the measuring space between optics 2 and optics 4 no measurement error arises. The control compensates for the radiation losses and thus ensures optimum irradiation of the electronic grid. The dark pulse generation consists of a generator 16 whose output pulse is divided in a divider 17 and 2 1. With the AND element 18 and with the NAND element 20, together with the generator 16 and the divider 17, two pulses of the same frequency but offset from each other and negated produced The signal coming from the trigger 12 is switched to a flip-flop, consisting of the NAND Links 21, 22, passed This flip-flop is set on the one hand by the trigger 12 and the other by the NAND gate 20 The NAND gate 21 and the AND gate 18 is brought together with the AND gate 19 Now from the electronic grid 5 just the material to be measured scanned, so get over the amplifier 6, the filter 11 and the trigger 12 no pulses to the NAND gate 22, but this hebt at the output of the AND gate 19 a pulse train, paid by the payer, memory and display 14 and displayed

Claims (2)

invention claim ¹ method for diameter measurement / on linearly moved extruded material, in which the material to be measured returns.g illuminated with a light source via an optical system jrd is imaged on an electronic grid, characterized in that the material to be measured (3) with its true size on a CCO- Zeiie 5; sharply imaged evaluated by a counter and simultaneously with a control device, which is kept constant on the CCD line (5) directed amount of light 2 Verfanren for measuring the diameter of linearly moved strandformigem property according to item 1, characterized in that from the video signal of the CCD line (5) once the 'mpuise for d'e actual measurement and on the other a Lchtmengensignal the light source (1) preferably as 'Infrared radiator running) which is about a Spitzenwertgleichnchtung' 9! and a ° -l controller 171 with the setpoint input (8!) controls the source (1) For this 2 pages drawings