Claims, 3 Drawing Figs.

[52]U.S.C1......................................................…………………235/151.32,

73/490 [51]

[51]Int. CL............……………….......................................... G06g7/78

[50] Field of Search........................…………………….............-.-235/151.32;

324/68; 73/490, 491; 33/142

[56]References Cited

UNITED STATES PATENTS

2,340,403 2/1944 Morley et al...………………………….............. 73/490 X

3,028,550 4/1962 Naydan et al.…………………….............. 235/151.32 X

3,145,294 8/1964 Jackson......................……………………235/151.32

Primary Examiner—Malcolm A. Morrison

Assistant Exammer - Edward J, Wise

Attorneys—F.H. Henson, R. G. Brodahl and J. J. Wood

ABSTRACT: This disclosure relates to a computer for determining the length of material required in order to arrest a moving strip of material in a preselected deceleration time, the material being payed out from a reel in a mill operated at a predetermined mill speed. An analog signal, which is a func­tion of the mill speed and deceleration time, is applied to a voltage comparator. Another input to the voltage comparator is a ramp signal. A train of pulses, synchronized with the ramp signal, is generated as a function of the payed out length of the strip material, the pulses being counted by a stop length counter. When the voltage comparator has inputs which are equal in magnitude, an inhibit signal is developed which is applied to inactivate the stop length counter, the cumulative counts of which will then be a function of the length of material required to stop the mill for the mill speed and deceleration time selected by the mill operator.

COMPUTER SYSTEM FOR DETERMINING THE STOP

LENGTH REQUIRED TO ARREST A MOVING STRIP OF

MATERIAL

CROSS REFERENCE TO RELATED APPLICATIONS

See the copending application for Digital To Analog Con­verter, Ser. No. 886,696, filed on Dec. 19, 1969, in the name of Paul W. Wagener and assigned to the same assignee as the instant invention.

Background of the Invention

1. Field of the Invention

This invention relates to a stopping length computer system for determining the length of payoff strip required to stop a rolling mill for the given mill speed and deceleration time selected by the operator.

2. Description of The Prior Art

In modern steel rolling mills, it is frequently necessary to determine the length of material required to stop a mill in a preselected deceleration time while running at a known speed. Before the arrival of automation, the mill operator made this determination empirically. Various solutions have been proposed in order to automate the decision-making process, most of these solutions making use of strictly analog techniques.

SUMMARY OFTHE INVENTION

The invention relates to a computer system for determining the stop length required in order to arrest a moving strip of material in a predetermined deceleration time, the material being payed out from a reel in a mill operating at a selectable mill speed. Briefly, means provide an analog signal which is a function of both the mill speed and the deceleration time. Means are also provided to develop a ramp signal. Means, synchronized with the ramp signal means, generate a train of pulse signals which are a function of the payed out length of strip material. Means are further provided to compare the analog and ramp signals and to develop an inhibit signal when they are equal in magnitude. Finally, means are provided for counting the train of pulses and for receiving the inhibit signal, the receipt of the inhibit signal inactivating the counter means. the cumulative count up to the time of receipt of the inhibit signal being a function of the required stop length.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the invention, reference may be had to the exemplary embodiment shown in the accompanying drawings, in which:

FIG. 1 is an electromechanical schematic diagram showing the computer system in accordance with the invention;

FIG. 2 is a voltage vs. time waveform showing the ramp , signal output of the digital to analog converter; and

FIG. 3 is a tabular arrangement of typical system parame­ters and is used in explaining the operation of the invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENT

The stopping length computer system of the instant inven­tion is intended for utilization in connection with a payoff reel in a rolling mill. In view of the fact that the rolling mill art is fairly well-known, the description to follow will be directed in particular to those elements forming part of or cooperating more directly with the instant invention. Information concerning elements and mill functions not shown or described will be understood to be readily obtainable from commercially available sources or selectable from techniques well known to those practicing in the rolling mill art.

Referring now to FIGURE 1, a strip of material 10 is being payed off from a coil positioned on a mandrel 12. A suitable sensor such as a billy roll 14 is arranged in contiguous relation­ship with the strip 10, the roll 14 having a known circumference so that one revolution of the roll 14, means that a payed out length of strip 10 equal to the circumference of the roll has passed a datum position. The revolutions of the roller 14 are coupled to a pulse generator 16, which generates a number of pulses, perhaps 500 pulses for each revolution of the roll 14. The generated pulses are then applied to pulse shaper circuitry 18 which as the name implies, reshapes the generated pulses; the reshaped pulses result in a train of clock pulses which are applied through a gate means 20 to a

stopping length counter 22.

An analog mill signal input, which is a function of the mill speed selected, (i.e. 5 volts" 1560 inches/sec.) is applied successively to an isolation amplifier 24, and to a filter circuit 26. Beyond the filter circuit 26, the signal is fed to an attenuation network, indicated generally at 28, which enables selection of the deceleration time. The attenuation network 28 is here simplified and is depicted as a number of rheostats: 30, 32, 34, 36 and 38, having wipers: 40,42, 44, 46 and 48 respectively, with normally open cooperating contact pairs at 50, 52, 54, 56 and 58, respectively. As will be observed from a study of F10. 1, the open contact pairs are arranged with one contact of the pair being connected to the associated wiper, and the other contact of the pair being connected to the common input line identified at 60. The closing of the contact pairs produces the following deceleration times:

50-90 secs.

52-60 secs.

54-45 secs.

56-30 secs.

58-20 secs.

The input line 60 also includes a serially arrayed, normally open contact pair at 62. A test signal generator source indicated at 64, includes normally open contact pair 66 connected to the input line 60 as indicated. The input line 60 is applied to a voltage comparator means indicated generally at 68.

A free running oscillator is identified at 70. A train of pulses from the oscillator 70 are applied to gate means 72, and through the gate means 72 the pulses are applied to a counter means indicated generally at 74. The digital output of the counter 74 is applied to a digital to analog converter means identified generally at 76. The gate means 72 includes an enable signal input 78 and an inhibit signal input at 80. The counter 74 includes a clear (reset) line at 82. One type of suitable digital to analog converter 76 is identified in the copending application for Digital To Analog Converter, Serial No. 886,696 filed on Dec. 19, 1969 in the name of Paul W. Wagener and assigned to the same assignee as the instant invention. Although the digital to analog converter is described and claimed in a separate application, the use of the digital to analog converter described in the copending application cited supra is not mandatory, and therefore for purposes of this disclosure any other digital to analog converter could also be used.

The output of the digital to analog converter 76 is applied to the voltage comparator 68 at 84. The output of the voltage comparator 68 is applied to an inverter indicated at 86. and the output of the inverter is applied as inhibiting signals to the gate means 20 at an inhibit signal input 88. and to the gate means 72 at inhibit signal input 80 as previously identified. A display device for the stopping length counter 22 is identified at 90.

Date: 2015-12-18; view: 628