DE1623279A1 - DEVICE FOR CAPACITI - Google Patents

Description

"Device for the capacitive measurement of wire diameter fluctuations The invention relates to a device for the capacitive measurement of diameter fluctuations very thin tungsten wires with the help of an oscillator, a phase shifter and a measuring capacitor, which shows the fluctuations in the wire diameter as changes in capacitance measures and in the form of current or voltage signals via an amplifier of a detection device, e.g. a phase bridge.

A known device uses a measuring capacitor, which consists of a about 200 mm long U-shaped electrode - through which the wire to be measured is made runs continuously through it. To guide the wire are at the beginning and end of the U-shaped electrode guide wheel attached, which also serves as the second capacitor electrode supply the voltage to the wire used for this purpose. The U-shaped electrode is through a earthed jacket and the measuring frequency in this device is 10 kHz used.

With the known measuring capacitor, over its total length of 200 mm integrates the diameter fluctuations. A substantial downsizing of the Measuring length is in view of the low frequency and because of the due to the inadequate shielding and the unstable transition resistance from the guide wheel to the wire even with the relatively large measuring length significant disturbance variables occurring from 200 mm are not possible. Another difficulty constitute the changes in phase shift that occur as a result of temperature fluctuations occur in the phase shifter, amplifier and in the phase bridge and those in the are of the same order of magnitude as those to be expected for very small measuring distances Changes in the phase shift, which result from changes in capacitance of the measuring capacitor is delivered. With the measuring capacitors used up to now, all of them were missing evaluate the device elements mentioned as temperature-acid-stabilized. Because of the very small changes in capacity furthermore, much higher frequencies, around 1 MKz, have to be used for which the previous shields of the measuring capacitor are no longer sufficient.

A measuring capacitor, which consists of partial capacitances, is also known and also a differential capacitor, which consists of a measurement and a comparison capacitor exists and feeds the difference values to a recording device via amplifiers.

The aim of the invention is to create a device for capacitive Measurement of fluctuations in wire diameter = and fluctuations in very thin metal wires (Diameter about 20 μm, fluctuations 0.16 °) with high sensitivity and constancy without expensive temperature stabilization in a particularly short measuring distance of 2 mm in length or less at very high frequencies on the order of 1 MHz.

A device for capacitive measurement of diameter fluctuations very thin metal wires with the help of an oscillator, a phase shifter and a differential capacitor, which consists of a multiple partial capacitance Messkondensbr, through which the serving as a capacitor electrode to be measured Wire is continuously passed through and from a reference wire containing, otherwise The same comparison capacitor consists and the fluctuations in the wire diameter measured as changes in capacitance and transferred in the form of current or voltage signals an amplifier to a detection device, Zl. a phase bridge, and for the shields are provided, is characterized in that the measuring capacitor has an elongated outer shield electrode, in the longitudinal direction of which The channel used to accommodate the measuring wire runs in its center between the ends of the shielding electrode to form a hollow rattm, the extent of which in the longitudinal direction of the shielding electrode is small compared to its length, that in this cavity a measuring electrode at least partially surrounding the measuring wire is provided and that between the outer shielding electrode and the measuring electrode an inner shield is provided within the cavity, which together with the supply line to the measuring electrode as its shielding from the outer shielding electrode is brought out.

The invention is explained with reference to the figures.

FIG. 1 shows the block diagram of the measuring device.

Figure 2 shows the structure of the measurement and comparison capacitor in longitudinal section.

Figure 3 shows the cross section through the measuring capacitor.

FIG. 4 shows the circuit between the phase shifter output and the amplifier input.

The vibrations generated in the oscillator with a frequency of about 1 MHz is fed to the measurement and comparison capacitor via a phase shifter, which together in a differential circuit are arranged. the Output voltage corresponds to the diameter fluctuations and is increased after amplification fed to a phase bridge. The measured values can be used to monitor the quality of wire production be registered or they can be used to control an electrolysis bath, in which the points with too large a wire diameter are removed.

The measuring capacitor consists of an elongated outer shielding electrode 1, in the longitudinal direction of which a channel 2 runs through which the measuring wire 3 is continuous is passed through. Channel 2 is in the middle of the outer shield electrode 1 expanded to a l cavity 4, through the center of which the wire 3 runs approximately and that extends from channel 2 in all directions perpendicular to the movement of the wire extends.

The dimensions of this cavity 4 in the direction of wire movement, d. H. in the direction of the longitudinal dimension of the outer shield electrode is small compared to of the length of the electrode and also smaller than the dimensions of the cavity in Direction perpendicular to the wire. In the exemplary embodiment, the cross section of the cavity is both perpendicular to the wire and in planes in which the wire lies, rectangular. But it is also possible that the cavity cross-section perpendicular to the wire is circular and is elliptical in planes in which the wire lies, with the minor axis coincides with the wire. In the cavity 4 is the measuring electrode 5, which the Surrounds wire in whole or in part. In the example this electrode has a U-shape, with legs and bilgel lie in a plane perpendicular to the wire. The distance between the two legs corresponds approximately to the width of the channel 2 and is aligned with it. Between The measuring electrode 5 and the outer shielding electrode 1 have an inner shielding electrode 6, which is essentially box-shaped and one with the channel 2 coinciding Owns breakthrough. The inner shield 6 is together with the lead 7 of the Measuring electrode 5 in the form of a this surrounding coaxial shield led out of the outer shielding. The comparison capacitor has the same Structure like the measuring capacitor and contains instead of the continuously fed through Measuring wire a piece of wire 9 of the nominal diameter. The remaining electrodes are labeled 1 ', 5' and 6.

The aim of the invention is thereby achieved with the aid of a measuring capacitor achieves that the capacitor consists of several partial capacities through which interference capacitances lying parallel to the measuring capacitance are eliminated and thereby, that the wire to be measured or the reference wire is also one of the capacitor electrodes and the voltage is not fed galvanically but capacitively. It This results in the following partial capacities: C35 capacitance between measuring electrode 5 and wire 3 (or wire 9).

C13 capacitance between outer shielding electrode 1 and wire 3.

C16 capacitance between the two shielding electrodes 1 and 6.

C56 capacitance between measuring electrode 5 and inner shielding electrode 6th

The measuring capacitor and the comparison capacitor are located together with the relatively large capacities C1 and C in one through 1 2 the capacitor C3 balanced bridge circuit. This bridge circuit is through the transformer 10 with the phase shifter and through the transformer 11 with the following Amplifier connected. The outer shield electrode 1 lies together with the one The end of the primary side of the transformer 11 is connected to ground and shields the measuring capacitance C35 counteracting external interference fields.

At the same time, the electrode 1 serves to supply the voltage to the as Capacitor electrode-acting wire 3 (lead capacitance C13).

The primary side of 11 is due to a relatively large capacity C4 bridged. The change in diameter of the wire 3 is called the change in capacitance of the measuring capacitor C35 formed by the electrode 5 and the wire 3 opposite the comparison capacitor 5, 9 determined. A maximum of amplitude change at the input of the amplifier, i.e. at the transformer 11, is achieved when the measuring capacitance C35 no capacitance is in parallel. Such a parallel capacity is provided by the inner shield 6 avoided. their introduction does result in capacities C16 and C56, which are harmless because they run parallel to the much larger capacities C4 or C1 and C 3 lie.

The middle shielding electrode is not grounded to the second End of the primary winding of the transformer 11 and each with a plate of the two capacitors C and C, connected1 while the other two plates use these capacitors each one end of the secondary winding of the transformer 10 are connected.

In the exemplary embodiment, the effective area of the measuring electrode closes 2 with those of the electrodes 1 and 6. However, it can also be used against these surfaces be reset

Claims (14)

Claims 1. Device for capacitive measurement of the diameter fluctuations very thin metal wires with the help of an oscillator, a phase shifter and a differential capacitor, which consists of a multiple partial capacitance Measuring capacitor through which the one to be measured serving as a capacitor electrode Wire is passed through continuously, and from a reference wire Containing, otherwise identically constructed comparison capacitor and the Measures fluctuations in the wire diameter as capacitance changes and in the form of Current and voltage signals via an amplifier to a detection device, e.g. a Phase bridges, which are supplied and for which shields are provided, characterized in that that the measuring capacitor has an elongated outer shielding electrode (i), in their longitudinal direction a channel (2) for receiving the measuring wire (3) runs, which is in its middle between the ends of the outer shielding electrode expanded to a cavity (4), the extent of which in the longitudinal direction of the outer The shielding electrode is small compared to its length, that in this cavity a measuring wire at least partially surrounding measuring electrode (5) is provided and that between the outer shielding electrode and the measuring electrode within the cavity a inner shielding electrode () is provided, which together with the supply line (7) to the measuring electrode as the shielding of which is led out of the outer shielding electrode. 2. Apparatus according to claim 1-, characterized in that the dimensions of the cavity (4) from the channel (2) in all directions perpendicular extend to the wire. 3. Apparatus according to claim 1 and 2, characterized in that the dimensions of the cavity in the wire direction are smaller than in the perpendicular direction to the wire. 4. Apparatus according to claim 1 to 3, characterized in that the cross-section of the cavity in planes in which the wire lies and the corresponding perpendicular planes, is rectangular. 5. Apparatus according to claim 1 to 3, characterized in that the cross section of the cavity in planes perpendicular to the wire circular and in the planes in which the wire lies is elliptical, with the minor axis of the ellipse coincides with the wire. 6. Apparatus according to claim 1 to 5, characterized in that the measuring electrode has a U-shape and both its legs and the one connecting them Stirrups lie in a plane perpendicular to the wire. 7. Apparatus according to claim 1 to 6, characterized in that da4 the inner shielding electrode (6) is essentially box-shaped and one with the channel (2) Has coincident breakthrough. 8. Apparatus according to claim 1 to 7, characterized in that the effective area of the measuring electrode (5) bits the corresponding areas of the shielding electrodes tl) and (3) are flush. 9. Apparatus according to claim 1 to 7, characterized in that the effective area of the measuring electrode (5) compared to the corresponding areas of the Shielding electrodes (i) and (3) is set back. 10. Apparatus according to claim 1 to 9, characterized in that the measuring capacity C35, consisting of the measuring electrode (5) and the one to be measured Wire (3), together with the reference capacitance, consisting of the electrode (5 ') and the target wire (9), and the comparatively large capacitances C1 and C2 in one Bridge circuit is arranged. 11. The device according to claim 10, characterized in that # a Capacitor C3 is provided for balancing the bridge circuit. 12. Apparatus according to claim 10 and 11, characterized in that a transformer (10) between the phase shifter and the bridge circuit and a from this to the amplifier leading transformer (1i) is provided and that its Primary winding is bridged by a comparatively large capacitance Ck. 13. The apparatus according to claim 12, characterized in that the outer shielding electrode (1) is connected to ground and the measuring capacitance C35 between the measuring wire (3) and the measuring electrode (5) are shielded from external interference fields and that # is the capacitance between the inner shielding electrode (1) and the measuring electrode (5) and between the two shielding electrodes (1) and (6) parallel to the comparative large capacities C4 or C1 and C3 and are harmless in this way and that one for the measuring capacitance or the comparison capacitance between the electrode (5 ') and reference wire (9) parallel capacitance through the inner shield electrode (6) or (6 ') is largely avoided. 14. The apparatus according to claim 13, characterized in that the inner shield (6) with the second non-grounded end the primary winding of the transformer (11) leading to the amplifier and each with one Plate of the two capacitors C1 and C2 is connected while the other two Plates of these capacitors, each with one end of the secondary winding of the transformer (10) are connected between the phase shifter and the bridge circuit.