DE2250388A1 - DISPLAY DEVICE FOR A CHANGING SIGNAL OVER TIME - Google Patents

Description

Display device for a signal that changes over time

The invention relates to a display or readout device for displaying the output signal of a measuring circuit and in particular on a display device for displaying the roll separation force on a metal roll train.

So far, display instruments or strip chart recorders have been used to display changing currents, voltages, Forces or similar signals used as a function of time. For rolling mills, especially sheet metal or Plate rolling mills, an ingot is reduced to a plate of the desired width and thickness by pulling it several times is sent through the rolling mill. Since the

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Reduction in strength per roller path through training the rolling train and the available drives are limited, the rolling train should be set in such a way that that a maximum reduction per roll pass is achieved without, however, the one that is still permissible with certainty Roll separating force is exceeded. The operator must therefore apply the roll separating force during each roll pass know so that they can increase or decrease the respective force as desired. Becomes an indicator is used, the force is only displayed momentarily and one of this display instrument is not Constantly observing operator does not know how great the force is or was. Even if the operator the display instrument is constantly observed - but the greatest force is only displayed for a moment, so that he cannot read it exactly. In addition, he cannot easily adjust the press pressure during a pass Compare with the press pressure of the subsequent pass. A strip chart recorder enables Although such a comparison, it has other disadvantages. Since it works mechanically, it cannot instantly show high compressive forces. The registration strips and the ink supply must be replaced from time to time, the ink can also dry out. It is therefore necessary to arrange the recording strips there where it can be easily serviced, but which is often not the best place for operator observation is. If the stripline or ink runs out, the operator must call a meter technician request for maintenance of the measuring arrangement. In the meantime, however, he has no reference values according to which he could operate the rolling mill with optimal efficiency.

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Task of the invention characterized in claim 1 it is »to create a display device that is more reliable than the previously used devices and with which the roller force can be displayed as a function of time over a series of roller passes.

By displaying the desired size on a storage electron beam oscilloscope is a clearly visible, very precise one that shows almost no time inertia It is also possible to display signals or measured variables occurring during successive processes, after which the The display appearing on the oscilloscope is only deleted when the displayed values are no longer required, or a new measuring process is initiated

The invention is illustrated by means of one in the drawing Embodiment explained in more detail. Show in detail:

Fig. 1 is a schematic view of the invention Display device in connection with a roller train and

2 shows a representation showing a typical force-time diagram as it appears on the screen of the oscilloscope appears.

A roller housing 2 has rollers 4 which are rotatable in this are stored, with a spindle 6 the roller distance and thus the roller pressure when a workpiece W through this passes through, can adjust. A strain gauge bridge 8 is arranged on one leg of the housing 2. One

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• · 1 · t

The baffle 26 is via a line 33 with a
Tap 34- A of a potentiometer 34, which is also part of the control logic 32. The tension increases
of the baffle 22, the electron tidal moves
20 along the X-axis to the baffle 24, while at a
As the voltage on the deflection plate 26 increases, the electron beam travels along the X-axis to the deflection plate 28.
One side of the potentiometer 30 is connected to ground potential and
the other side is connected to the output of an amplifier 36 generating a sawtooth voltage. The outcome of the
Amplifier 36 is also connected to an input of a comparator 38. The output of the comparator 38 is
connected to ground potential via a relay winding 40.
The accessory 40 has contacts 40C, 40C1, 40C2, 4003, 40C4
and 40C5. Contacts 4OC and 40C3 are boom contacts,
while the other contacts are working contacts. Of the

- 4 -

Voltage source 10 feeds bridge 8. A bridge bridge \

12 is provided across the voltage source 10. |

The supply of the bridge 8 is with a switch 14; '

switched on. The output of the bridge circuit is marked with j

a circuit 16 that compensates for the drift. J

These parts described so far do not in themselves constitute a j

Part of the invention. (

'' ■■■■ ■ '■.' ■! ■

The display device according to the invention has a | conventional storage electron beam oscilloscope 18 i, which can be, for example, a Tektronix model 611 or model 4501 1. The oscilloscope 18 has an electron beam 20, the position and movement of which are controlled by deflection plates 22, 24, 26 and 28. The deflection] plates 24 and 28 are connected to ground potential. The ■. ■■ Deflector 22 is with the tap 30 A of a potentiometer; meters 30, which is part of a control logic 32. '

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ι i · ·

Contact 4OC is in a -10 volt line L1 and is connected to the second input of the comparator 38, while contact 4001 is the second input of the Comparator 38 connects to ground potential. The contact 4-ÖC2 is in a +10 volt line L2 in Series with a potentiometer 42, the tap 4-2A of which is connected to the first input of the amplifier 36. the Line L1 is via tap 44-A of the potentiometer 4-4- connected to the second input of the amplifier 36. The .Kontakt 4003 is in the connection between the Baffle 26 and tap 34A. The line 33 is also via the contact 40C4- with the tap of the potentiometer 46 connected, which in turn is connected to the line L2. The potentiometer 34 is with the that signal to be displayed leading output 48 of the circuit connected.

Contact 40C5 is between ground potential and a terminal a capacitor 50 switched. The same connection of the capacitor 50 is connected to a line L3 carrying a positive voltage. A cancellation circuit 52 is switched via the capacitor 50. The other terminal of the Capacitor 50 is connected to ground potential. The capacitor 50, the line L3 and the cancellation circuit 52 constitute part of the oscilloscope 18.

A positive output signal 54 of the circuit 16 is fed to a transistor 58 of the control logic 32 via the resistor 56. The transistor 58 can be of the type 2N1304 and functions as a switch for controlling the flow of current to one terminal of a capacitor 60. The same terminal of the capacitor 60 is with the positive voltage

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leading line L3 connected. The other connection of the; Capacitor 60 is connected to ground potential. A 5 i * Reset circuit 62 for the display is via the Capacitor 60 switched. The capacitor 60, the line L3 and the reset circuit 62 form a part of the oscilloscope 18. The signal 54- indicates the presence of a workpiece in the roller train. This particular one Circuitry can be provided as an option and is used to increase the brightness of the display signal, when a Tektronix Model 611 is used, but not when a Tektronix Model 4501 is used.

The mode of operation of the display device according to the invention is as follows: the potentiometer 42 is set to the desired speed of the beam return and the potentiometer 44 to the desired speed of the display beam along the X-axis. The potentiometer 46 is set to the desired level for the jet return, which indicates the maximum permissible roller separation force. If a workpiece W gets between the rollers 4, it generates a signal via the line 5 ^ Bn to the transistor 58, which makes it conductive and short-circuits the capacitor 60. This causes the reset circuit 62 for the display to be actuated, whereby the image on the display surface of the oscilloscope 18 becomes brighter. At this time the relay 40 is switched off, whereby all of its contacts are in the rest position and the electron beam 20 can be assumed to be at point A (FIG. 2). The signal indicating the force is transmitted from the drift compensating circuit 16 to the deflection plate 26 via the line 48, the potentiometer 34 and the rest

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contact 4OC3 given, whereby the electron beam 20 is moved along the Y-axis to the respective Waisskraft to display. At the same time, a negative voltage is applied to amplifier 36 from line L1 applied via the potentiometer 44. The output signal of amplifier 36 is positive and increases at a fixed rate Speed gradually increases by adjusting the potentiometer 44 and the gain of the amplifier 36 is given. This output signal is connected to the deflector plate 22 via the potentiometer 30 given, whereby a uniform movement of the electron beam 20 from left to right along the X axis of the display surface 18 of the oscilloscope is moved as shown in FIG is also given to the comparator 38 and, when its value reaches +10 volts, the combined voltage of the Amplifier 36 and that of line L1 via contact 400 equals O. The display device is set so that the electron beam 20 is at this point in time B is located and this current from the comparator 38 through the Relay 40 flows, opening contacts 4OC and 4003 and closing the remaining contacts. That opening of the contact 400 and the closing of the contact 40C1 connects the second input of the comparator 38 with Earth potential. Closing contact 4002 connects a positive voltage to amplifier 36 * This positive Voltage causes the output of amplifier 36 to drop from 10 volts to 0 at a rate which is determined by the potentiometer 42, causing the electron beam x 20 along the X-axis from the right returns to its original position to the left. The opening of the contact 4OC3 and the closing of the contact

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40C4- switches the signal indicating the force to a Value that indicates the maximum permissible force. In this way the electron beam 20 writes on the oscilloscope 18 a return line from point B to point C. and then to point D at a level indicating this maximum allowable force. This line is a substantial one Piece above the actual rolling force, the operator knows that he is reinforcing the rolling process the rolling force can accelerate. If the output signal of the amplifier 36 reaches zero, the comparator switches 38 the relay 40 off, so that this is its contacts switches back to its original position of rest, the electron beam 20 likewise returning to its original position Location at point A. The relay 40 is switched off when the electron beam reaches point B.

The closing of contact 4OC5 causes actuation the erase circuit 52 to cancel the storage on the display of the oscilloscope 18 after the electron stop 20 has reached point B and returns to its original position of rest. The way of working then becomes repeatedly regardless of whether a workpiece is in the rolling train or not. If desired, can a reset button may be provided to the electron beam 20 to be returned to point A at any time. It should be noted that the terms X-axis and Y-axis are broadest Senses were used here to indicate two mutually perpendicular axes. Of course you can the display device according to the invention also for display other types of signals that change over time can be used.

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Claims (3)

Patent claims 1. 1. J display device for a changing signal over time, characterized by a memory electron beam oscilloscope (18) with a beam deflection (22, 24) for the X-axis and a beam deflection (26, 28) for the Y-axis of the electron beam (20), through a 'deletion circuit (52), through a control logic (32)' for controlling the beam deflections and the deletion circuit, through a supply device (16) for the changing signal to the control logic, through a first circuit (36, 38, 40, 44) with which the electron beam can be moved along the X-axis in one direction at a speed indicative of time via the beam deflection for the X-axis, and by a second circuit which is responsive to the signal (34, 40C3, 40C4, 46), with which the beam can be moved along the Y-axis indicating the size of the signal via the beam deflection for the Y-axis. 2. Display device according to claim 1, characterized in that the first circuit (36, 38, 40, 44) has an amplifier (36), a positive input voltage (+10 volts) for the amplifier, a negative input voltage (-10 volts) ' for the amplifier, a working contact (4002) in one of the Eingangsleitiin "from a connection between the gene for the amplifier," 0 9 8 16/1110 output of the amplifier and the beam deflection (22, 24) for the X-axis, a comparator (38) with awei inputs, the first with the output of the amplifier and the second of which is connected to an input voltage whose polarity is that of its first input is opposite, a break contact (4OC) in the connection line between the input voltage and the comparator, a switch arrangement (4QC1) connecting the second comparator input to ground potential, a second normally open contact in this switch arrangement parallel to the first normally closed contact and one of the Comparator-operated first switching arrangement (40) for opening the normally closed contact and closing the working con clock when the electron beam (20) reaches its travel end point (B) in a direction along the X-axis has, whereby the electron beam travels along the X-axis into its reverse position, and has a second switching arrangement that can be actuated by the comparator, with which the contacts can be returned to their rest position when the electron beam is in its original position Position returns along the X-axis. 3. Display device according to claim 2, characterized by a potentiometer (42, 44) for each each of the input voltages of the amplifier (38) 4. Display device according to claim 2 or 3t characterized by one of the first switching arrangement (40) actuatable normally open contact (W !?), with de »the extinguishing circuit (52) for the deletion of the picture on the mirror «- Oscillograph (18) can be operated when the electrical 309816/1110 ray (20) has reached the end (B) of its movement in one direction « · Display device according to claim 1, characterized in that the changing signal the rolling separation force generated when a workpiece (W) is rolled is. 6. Display device according to claims 2, 3 and 5, characterized characterized in that the second circuit (34-, 4OC3, 4004, 46) has a connection (33) between the beam deflection (26, 28) for the T-axis and the feed device (16) for that of the roller separating force proportional signal to the control logic (32), which in turn has a third potentiometer (34), a second Buhekontakt (40C3) in series with the third potentiometer on the Y-beam deflection adjacent connection side, a fourth potentiometer (46) and a third connected in series with this Has normally open contact (40C4), the fourth potentiometer and the third normally open contact being the third potentiometer and the second normally closed contact are connected in parallel, and the third normally open contact and the second Normally closed contact can be actuated by the first switching arrangement (40) actuated by the comparator (38). 3 0 9 816/1110 Blank page