CS218847B1 - Involvement to measure the length of swags on pilgrimage stands cold - Google Patents

Abstract

Connection for measuring the lengths of the slats on the pilgrim stand during cold rolling, especially of pipes, regardless of the wall thickness and clearance, implemented on a device consisting of two counters, limit switches, a charger position sensor and a frequency divider, whose mutual connection is characterized by the fact that the programming counter is connected to a controller, to which the frequency divider together with the generator are further connected, further limit switches, relays, a zero button and a display, the outputs from the controller are connected firstly back to the programming counter and then to the second, from which there is also an output to the indication switch, which is connected to the display, to which the pusher position signal is further introduced via the gearbox from the pusher position sensor and finally the charger position signal.

Description

The invention relates to a circuitry for measuring the length of dandruff on pilgrim stands during cold rolling, irrespective of the wall clearance and thickness.

Currently, electronic counters are used in rolling mill piles to optimize operation. These counters add pulses from sensors that are placed on pilgrims. Two counters are used for these counters, one on the charger gearbox and the other on the syringe gearbox.

The disadvantage of this arrangement is that the counters cannot be used to measure the length of the input magnifiers. Another major disadvantage of this arrangement is that the counters do not have a memory in which the measured data would be stored.

The disadvantages of the present invention are eliminated by two counter counters for measuring the dandruff lengths of the pilger's mill during cold rolling, the circuitry being essentially such that at the initial position of the charger the programming counter is set to a constant length equal to the end distance switches, reduced by the length of the charger. The controller receives pulses from both limit switches and from the direction of travel of the charger. The controller is connected to a programmable counter and a magnifier length counter, from which signals are discharged on the display to read the actual length of the input magnifiers. In addition, pulses and frequency dividers and pulses from the generators, which are also routed through the divider, are sent to the controller. Finally, pulses are supplied to the controller from the charger position sensor located on the charger gearbox.

The advantage of this wiring arrangement is that the measured value can be read on a four-digit indicator after the indication switch has been switched. After reading the value in the counter can be cleared by the reset button.

The circuit according to the invention operates in such a way that when the charger is in the initial position, the limit switch is closed and the programming counter is set to a constant length. This length is equal to the distance of the limit switches reduced by the length of the charger. After passing the limit switch (which is the position of the charger), the programming counter is released and starts counting downwards. The counter receives pulses from the charger position sensor. If the charger travel is changed, the counting direction of the program counter will also change. When the magnifier approaches the limit switch, pulses from the charger position sensor located on the charger gearbox are blocked. The value remaining on the program counter is equal to the magnifying glass length. At the same time, the pulses are unlocked from the generator and are routed to a computer which is added to the length of the measured magnifiers. The frequency from the generator is adjusted via the frequency divider. This adjustment results in its length being converted to 1 mra. The thus adjusted pulses are fed to the program counter, which counts down again. If a downlink signal comes from the program counter, the generator and the frequency divider and other inputs to the counters are blocked. In other positions of the charger, the counters are locked up to the last position that corresponds to the first position. In this position, the program counter is set to a constant length and the whole procedure is repeated again, the measured value being read on the four-digit display after switching the indication and after reading it is cleared by the reset button.

In the drawings, one possible embodiment of the invention is illustrated, wherein FIG. 1 illustrates the connection between the prior art parts numbered 1 to 10 and the magnifying glass part numbered 100-140. FIG. 2 shows seven positions magnifying glass and charger.

The pilgrim mill is equipped with two counters 101, 102. At the initial position of the charger 10, the programming counter 101 is set to a constant length equal to the distance of the limit switches 110, 120 reduced by the length of the charger 10. 120 and from the travel direction relay 130 of the charger

10. The controller 100 is coupled to a programmable counter 101 and a lup length counter 102, from which signals are output to the display 1 to subtract the actual length of the input lupes.

11, the pulses from the frequency divider 103 and the pulses from the generators 104, which are also routed through the divider 103, are further discharged to the controller 100. The controller 100 also receives pulses from the charger position sensor 3 located on the charger gearbox 8.

The wiring operates such that when the charger 10 is in the initial position, the limit switch 120 is closed and the programming counter 101 is set to a constant length. This length is equal to the distance of the limit switches 110, 120 reduced by the length of the charger 10. Upon passing the limit switch 120 (which is the position 2 of the charger 10), the programming counter 101 is released and starts counting downwards. The pulses 10 arrive at the counter 101, the counting direction of the program counter 101 is also changed. If the magnifier moves to the limit switch 110 in position 3 of the charger 10, the pulses from the charger position sensor 3 located on the charger gearbox 8 are blocked. It remains on the program counter, equal to the length of the magnifying glass 11. At the same time, the pulses from the generator 104 are unlocked and passed to the counter 102, which adds the length of the measured magnifying glass. The frequency from the generator is adjusted via the frequency divider 103. With this adjustment, one pulse, which in the specific case is 18 mm, is now equal to 1 mm. The thus adjusted pulses are fed to the program counter 101, which again counts downwards. When a downlink signal comes from the program counter 101, the generator 104 and the frequency divider 103 and other inputs to the counters 101, 102 are blocked. In other positions of the charger 10, i.e. 4, 5, 6, the counters 101, 102 are blocked until In this position, the program counter 101 is set to a constant length and the procedure is repeated again.

The measured value can be read on a four-digit numeric display by switching the display switch 105. After reading, the counter value can be cleared by the reset button 140.

Subject

Circuitry for measuring the length of dandruff on cold piles, in particular tubes, irrespective of the wall clearance and thickness, implemented on a device consisting of two counters, limit switches, a charger position sensor and a frequency divider, characterized in that the programming counter (101) it is connected to a controller (100), in which the frequency divider (103) together with the generator (104), the limit switches (110 and 120), the relay (130), the zero button (140) and the display are connected

Claims (1)

OF THE INVENTION (1), the terminals of the controller (101) are connected back to the programming counter (101) and to the other (102), from which the terminal is connected to the display switch (105), which is connected to the display (1), into which a signal of the position of the syringe (5) via the transmission (4) from the position sensor (2) of the thrust position (5) and finally the signal of the position of the charger (7) via the transmission (6) from the sensor (3) ).