HU202776B - Method and connection arrangement for determining the lateral contraction originating in the course of wire drawing - Google Patents

Abstract

according to the invention, the travel speed of the inlet wire (la) and the running speed of the run-off wire (lb) are measured and the ratio of the cross-sectional reduction is determined as the ratio of the velocity values. The switching arrangement includes measuring transducers, signal processing and evaluation units. According to the invention, the transducers include angular position transmitters (4.5) and signal processing and evaluation units (6), counter (8.9), display stage and synchronization stage (11). (Figure 1)> rv Figure 1 Scope of the description: 4 pages, Figure 1 EN 202 776 B -1-

Description

FIELD OF THE INVENTION The present invention relates to a method for determining a cross-sectional reduction in the drawing of a wire, measuring at least one parameter of the incoming wire and / or the outgoing wire and determining from the measured parameters A circuit arrangement for determining cross-sectional reduction, comprising measuring transducers associated with an inlet and outlet wire and a signal processing and evaluation unit connected to the transducers.

In the prior art tensioning machines, the diameter reduction of the wire is accomplished by using a calibrated pulling tool, a drawing stone. Technological specifications generally provide values for physical properties to be observed during tension, in particular wire temperature, tension tool temperature, initial wire diameter, and cross-section reduction. The continuous, 20 direct measurement of the listed parameters under operating conditions is still unresolved to our knowledge. The cross-sectional reduction value can be derived from two parameters of the wire: The diameter of the inlet wire and the diameter of the caliper section of the puller. 25 Both values can be measured with high accuracy, the second can be set according to the required degree of deformation before the drag operation. In the absence of any other useful parameter during drawing, the cross-sectional reduction value is considered constant, although it has been demonstrated in practice 30 that a change in the named parameters and two basic dimensions, i.e., wire diameter and / or stroke diameter, can substantially and adversely affect the drawn wire. 35

A change in the value of the cross-sectional reduction results in a change in the physical characteristics of the wire produced and in the quality of the wire. The wire becomes brittle, its tensile strength and specific electrical resistance change. The instability of the cross-sectional reduction can be caused by a change in the diameter of the incoming wire, by bouncing, abrasion of the caliper portion of the pulling tool, and by variations in the wire temperature and the pulling stone temperature.

Together, these phenomena can exert their effects by superposing each other, resulting in increased tensile strength, reduced tool life, and longitudinal inhomogeneity of the drop wire parameters, outweighing the quality degradation noted above. The disadvantages listed above are particularly pronounced for expensive wire materials such as tungsten or molybdenum wires. In practice, in order to economically utilize the wastes formed, wires that are unsuitable for their quality or their parameters are lowered to a smaller size range, using new energy and resources.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and circuit arrangement that enables the continuous and automatic determination, measurement and control of the drawn wire cross section through any pulling machine in a fast and simple manner.

The present invention is based on the discovery that there is no material separation in the drawing tool, except for graphite 65 as lubricant, and therefore the specific volume of the inlet and outlet wire can be considered to be the same. However, with the same specific volume, the speed of the smaller cross-sectional runoff wire is higher, and proportionally higher than the runoff wire, so that continuous and accurate information on cross-section reduction value is obtained by measuring and comparing the runoff wire and runoff wire speed.

SUMMARY OF THE INVENTION The object is solved by a method for determining cross-sectional reduction during pulling of a wire, wherein at least one parameter of the inlet and / or outlet wire is measured and the value of the cross-sectional reduction is derived. In the further development, the incoming wire travel velocity and the outgoing wire travel velocity are measured and the value of the cross section reduction is calculated as the ratio of the two velocity values.

In a further embodiment, the present invention is based on a circuit arrangement for determining cross-sectional reduction in wire drawing, comprising a measuring transducer associated with an inlet wire and a bypass wire and a signal processing and evaluation unit connected to the transducers. According to the invention, the transducers of the present invention have angular position transducers having the same parameters, which are mechanically connected to the non-slip contact rollers and to a signal forming and amplifying stage connected to an angular position transmitter output, Contains a comparator stage connected to a storage stage, a synchronization stage connected to the outgoing wire counter stage, and a digital display stage to the output of the incoming wire counter stage.

According to a preferred embodiment of the circuit arrangement according to the invention, the angle transmitters are optoelectronic angle transmitters which are mounted on the axis of the ceramic rollers in contact with the wire.

It is also advantageous for the signal shaping and amplifying stages to be composed of Schmitt triggers.

It is further preferred according to the invention that the incoming and outgoing wire count stages are constructed with a four-decimeter decimal counter.

It is also advantageous according to the invention that the counting stages are connected to the output of the signal forming and amplifying stages through a quadruple frequency, since the proportionally increased frequency results in greater measuring accuracy. In a further preferred embodiment of the circuit arrangement, the synchronization stage is a restartable monostable tilt stage. It is also preferred that the storage stage containing the cross-sectional reduction limits is implemented by a flanged code switch.

-2EN 202776Β

According to the invention, it is advantageous for one output of the error stage to be connected to the output of the comparator stage and the other input of the error stage to be connected to the third output of the synchronization stage and its output to a further data input of the digital display stage. Finally, it is advantageous to have the adjusting input of the incoming wire counter connected to the output of the container having the offset error of the angular transmitter, and the second output of the synchronizing stage connected to the enable input of the container.

The method and circuit arrangement of the present invention are capable of continuously measuring and displaying cross-section reduction values in any size range, industrial environment and during machining. The wiring arrangement does not contain complicated electronic components that can be assembled from small parts in a small space. The digital display of the cross-sectional reduction value allows high-precision readings to the tenth of a percent, and the error rate also visually or acoustically informs the operator of the machine.

The invention will now be described in more detail with reference to the drawing, in which a block embodiment of a possible embodiment of a switching arrangement implementing the method is shown.

The drawing wire la and the drawing wire lb coming out of the drawing tool 2 are shown in the drawing only. Precision machined ceramic rollers 3 having the same geometric dimensions are provided with non-slip ceramic rollers 3 with a lead-in wire 1a and a run-off wire 1b.

The non-slip contact of the rollers 3 with the inlet wire la and the outgoing wire lb can be ensured in a manner known per se, for example by a spring force. Optoelectronic angle transducers 4.5 are mounted on the rollers 3, which, coupled to rollers 3 with a diameter of 100 mm, emit two hundred pulses per swing. The angle transmitters 4,5 are connected to the inputs of 6 signal generating and amplifying stages. The latter in this example contains a Scmitt-trlggerk providing a standard output signal level. The output of the signal generator and amplifier stage 6 is connected to a frequency quadruple stage 7 implemented by logic circuits, the outputs of which are connected to the inputs of the counting stage 8 of the inlet wire la and the counting stage 9 of the runoff wire lb. Each of the 8.9 counter stages is constructed of four serially decadent counters. The outputs of the counters of the counter stage 8 are connected to the data inputs of the digital display stage 10. The output of the counting stage 9 of the runoff wire lb is connected to the start input 11a of the synchronization stage 11b. Output of monostable tilt stage of all synchronization stage 11 output of monostable tilt stage of synchronization stage 11, the first output 11b of which is connected to the control input 10a of the digital display stage 10, the second output 11c is connected to the input terminal contains a 3x4 bit comparator chain. One of the inputs of the comparator chain comparators is connected to the outputs of the counting stage 8 and to the other inputs of the storage stage 13. The storage stage A13 includes a freely adjustable maximum and minimum value of cross-sectional reduction. In the simplest case, the storage stage 13 is comprised of three-decker rim-mounted code switches, but the storage stage 13 may also include other electronic semiconductor storage providing digital information at its output. The input of the comparator chains of the maximum value and the minimum value of the cross-section reduction are switched in parallel. The outputs of the two comparator circuits, which are connected to the control input 14a of the error stage 14, are also connected in parallel. The reset input 14b of the error stage 14 is connected to the fourth output lle of the synchronization stage 11, and the output 14c is connected to the further data input 10a of the display stage 10.

The angular position encoder pulse sequences 4.5, which are proportional to the movement velocities of the pulling tool 2, are fed to the counting stages 8, 9 after signal formation and possible amplification. The counters of the counters 8, 9 are set to a given value at the beginning of each measuring cycle. This value in this example is decimal 0000, and incoming pulses reduce this initial value. The higher wire velocity after the pulling tool 2 results in a higher frequency pulse sequence, this pulse sequence being introduced into the counting stage 9, which initiates the synchronization stage all.

When all synchronization stages are started, it stops counting stage 8, on the one hand, enables rewriting stage 10, and, on the other hand, tilts counters 8 and 9 to its initial position. Thus, it can be seen that in the event of an overflow of the counting stage 9, which counts the higher frequency pulse sequence, the other counting stage 8 causes the synchronization to stop. By storing and displaying the current value of the counter stage 8, the percentage reduction of the desired cross-section is obtained, to the tenth of a percent, unless a separate display element in the counter stage 10 is assigned to the smallest local counter of the counter stage 8. A tenth percent display of the cross-section reduction value fully meets the technological requirements and further prevents the counting error due to gate errors from appearing on the display stage 10.

The previously mentioned 100mm roller diameter and two hundred pulse / revolution parameters ensure that every five meters of drawn wire a new measurement result is available regardless of the pulling speed. Given the machining times and wire lengths of the wire drawing equipment, the aforementioned sampling frequency provides a high degree of safety. Of course, by changing the diameter of the rollers 3 or the technical parameters of the angle position transmitters 4.5, the measuring period of the switching arrangement can be arbitrarily set.

If the result displayed at the output of the counter stage 8 is equal to the maximum value or the minimum value of the storage stage cross section reduction, the comparator stage 12 is

The output of the comparator circuit of the shooter 202776Β provides an impulse to the control input 14a of the diagnostic stage 14, and the diagnostic stage 14 provides an error signal through the data input 10a of the display stage 10, and

Claims (9)

CLAIMS 1. A method for determining cross-sectional reduction during pulling of a wire, wherein at least one parameter of the inlet and / or outlet wire is measured and the value of the cross-sectional reduction is derived from the measured parameters, characterized in that (lb) determine the percent reduction of the cross-section by plotting the velocity and the quotient of the two velocities. 2, Circuit arrangement for determining the reduction in cross section during wire drawing, measuring transducers associated with inlet and outlet wire, signal processing and evaluation unit connected to the transducers, characterized in that the transducers 4 having the same parameters, the inlet wire (la), the overhanging outlet wire (lb) being in non-slip contact with the non-slip rollers (3), and the signal processing and evaluation unit is an angular position transmitter (4, 5) a signal forming and amplifying stage (6) connected to its output, a counting stage (8, 9) connected thereto, a display stage (10) connected to the counting stage 35 (8) of the inlet wire (1a), synchronized to the counting stage (9) of the outgoing wire (lb) 11), wherein the outputs of the incoming wire (1a) counter stage (8) are connected to the data inputs of the display stage (10), the outputs of the outgoing wire (1b) counter 40 stage (9) are connected to the synchronization stage (11) output of synchronization (11) (1 lb - 1d) are connected to the adjustment inputs (8a, 9a) of the counter stages (8,9) and the control input (10v) of the display stage (10). Circuit arrangement according to claim 2, characterized in that the angular transducers (4,5) are optoelectronic angular transducers Circuit arrangement according to claim 2, characterized in that the signal forming and amplifying stages (6) are Schmitt triggers. The circuit arrangement according to claim 2, characterized in that the counting stages (8,9) of the inlet wire (Ia) and the outgoing wire (1b) consist of four decimal decimals. Circuit arrangement according to claim 2, characterized in that the counting stages (8, 9) are connected to the output of the signal forming and amplifying stages (6) via a frequency quadruple (7). A circuit arrangement according to claim 2, characterized in that the synchronization stage (11) is a restartable monostable tilting stage. Circuit arrangement according to claim 2, characterized in that one of the inputs of the comparator stage (12) is connected to the output of the counting stage (8) of the inlet wire (1a) in conjunction with the display stage (10) and the other input of the comparators is max. the output of the storage stage (13) having a value and a minimum value is connected, and the output of the comparator stage (12) is connected to the control input (14a) of the fault stage (14). The output of the display stage (10) is connected to the control input (10a). (11) is connected to the fourth output (1 off). 9. A circuit arrangement according to any one of claims 1 to 6, characterized in that the second output (11c) of the synchronization stage (11) is connected to an adjusting input (8a) of the incoming wire (1a) via an intermediate storage containing an offset error of the angular position transmitter (4, 5).