DE2623158C3 - Device for recording and displaying several measured values - Google Patents

Description

The invention relates to a device for recording and reproduction of a plurality of measured values, with one transducer measuring the measured values of a plurality of measuring devices gives a light beam oscilloscope via a measuring amplifier, which records the measured values.

In this known device, the measured values are recorded directly by the light beam oscilloscope. It is there, for example, when measurements are taken on tunneling machines for driving the road or tunnel are to be carried out, disadvantageous that in these recordings the individual measured value traces partially overlay each other, which makes the evaluation of the measurement diagrams very difficult.

The invention has the task of developing this device so that a clearer one Recording and thus a more reliable and faster evaluation of the measurement diagrams is achieved will.

The invention solves this problem in that the measurement amplifier also has a multi-channel tape recorder is connected downstream, which is an XY recorder and a synchronous time device, which has a pulse generator and a Pulse selector and starter with indicator light includes, is assigned. By including the Multi-channel tape recorder, the measurement results can be repeated as often as required, with the synchronous timer ensures that the recorded measurement signals from the multi-channel tape recorder with each other can be drawn synchronously by the XY recorder. These records can be multicolored, represent time stretched or gathered as well as amplitude reduced or enlarged, what the evaluation of the Measurement results significantly simplified. In addition, these records can be used unchanged z. B. present more clearly in reports. For comparison purposes, the recordings of the light beam oscilloscope can also be used.

The device according to the invention is explained in more detail with reference to the drawing in an example. It shows

Fig. 1 is a schematic representation of the device for recording and displaying several measured values,

Fig. 2 examples of original measuring diagrams,

Fig. 3 time-expanded excerpts from the measurement records according to Fig. 2,

4 shows details of the pulse generator in a circuit diagram,

5 shows, in a circuit diagram, details of a pulse selector and starter, and

6 shows the circuit diagram of a power supply unit for the power supply.

1 shows a tunneling machine 100 on which a number of measuring devices, for example a dynamometer SO, a displacement meter 91, a pressure meter 92 and a speedometer 93, are arranged, the control room of which is analogous to a light beam oscilloscope via a measuring transducer 9 and a measuring amplifier 8 80 are supplied, which displays the measurement results and records them if necessary. In addition, the pulses transmitted by the transducer 9 are fed into a multi-channel tape recorder 3, which is followed by an XY recorder 5 and to which a synchronous timer 2, which comprises a pulse generator 1 and a pulse selector and starter 6 with an illuminated display 7, is assigned . The device according to the invention works as follows:

During an experiment, the measured values determined by the measuring devices 90, 91, 92, 93 are the transmitter 9 at the same time as the normal time, which comes from the pulse generator 1 is fed to the multi-channel tape recorder 3. In order to be evaluated these measuring pulses successively from the individual channels of the multiple tape recorder 3 to the X-Y recorder 5 given. So that the measuring pulses are recorded synchronously by the X-Y recorder 5 a start impulse is given at the beginning of the respective measurement record, which is given by the tape recorder 3 comes and is fed to the X-Y writer 5 via the pulse selector and starter 6, which triggers the start. The start pulse is a trigger pulse that is generated by the pulse generator 1 continuously during an attempt on one of the channels of the tape recorder 3 simultaneously with the measured values is recorded in the remaining channels. Any impulse can be used as a Start pulse for the X-Y recorder 5 can be selected at any point in the measurement record.

In FIG. 2, the curves α and b shown represent recorded measured values, while curve c reproduces the course of the selected trigger signal, which is used as a time normal. With the help of the time standard, it is possible to record any measurement record from the tape recorder 3 to the XY recorder S at any point and at the same time record the measurement record, e.g. B. by time expansion, to reproduce more clearly so that, if necessary, individual details of the test results can be checked more precisely.

An example of this is shown in FIG. The curve / with the time normal shown in a time-stretched manner enables certain associated points to be found more easily on the measurement records d and e, which are also correspondingly stretched.

In Fig. 4 details of the pulse generator 1 are shown, which represents a trigger machine, which is operated in the example with 50 Hz pulses from the lighting network, Fig. 6 shows the power supply, which takes place via a transformer 10, which is a power supply 14 feeds, which feeds the pulse generator 1 via a DC voltage connection 12 (5 V). The voltage connection 12 is followed by a voltage divider 11 which comprises the resistors Rl (10 K) and Rl (11 K). In a pulse shaper 15, a Schmitt trigger, the mains voltage is converted into square-wave pulses. In two connected via a switch 25, from integrated switch

2 (1

Frequency dividers 16, 17 formed by the frequency divider, the 50 Hz pulses are divided into two steps in a ratio of 1:50, namely 1: 5 and 1:10, so that after the frequency divider 17 pulses of exactly 1 second duration are available . These 1 Hz pulses are fed to a decade counter which is formed from the integrated circuits 18, 19. The 10 outputs of the decade counter 18, 19, which supply negative pulses, are applied to a voltage divider 20 via negators 21, 22. The voltage divider 20 consists of a resistor R3 (10 K), followed by 10 voltage divider resistors 51 ... 510, of which the resistors 51 to 5710 K, 58 20 K and 59 and 510 250 K in the example. In each case between two resistors one of the outputs of decade counter 18-19 is connected via diodes Dll D20 ..., is reached so that every second at the output of the voltage divider 20, a potential difference of ₁₀ V in order to obtain distinct code signals. These signals look like this:

The first potential level is exactly V _{10 of} the total level (compare also FIGS. 2 and 3) and lasts one second. After one second has elapsed, the decade counter 18, 19 is incremented so that ² / _{] 0 of} the total potential level are now present at the output of the voltage divider 20 for another second. This process continues until a new cycle begins after the 10th jump. Using a seven-segment display 27 with a Sicben-segment decoder 26, it is shown which potential level is present on the device in each case. The trigger signal obtained is sent to the multi-channel tape recorder 3 via an operational amplifier 23. The operational amplifier 23 is connected to the power supply unit 14 (+ 15 V / -15 V) via the connections 13 »■>. Two resistors R4 and RS (10 K) and a voltage divider resistor 24 (100 K), with the help of which the trigger signal can be adapted to different tape devices 3, and a capacitor Cl w (0.22 μΡ) complete the operational amplifier 23.

FIG. 5 shows an example of a circuit for the pulse selector and starter 6. The trigger signals played by the tape recorder 3 arrive at the input of an operational amplifier 30 and are amplified there. The resistors R6, Rl have a value of 10 K in the example, the voltage divider resistor 511 of 100 K. A group 31 of 10 voltage divider resistors 32, 320 ... 328 (each 10 K) connected in parallel is present at the output of the operational amplifier 23 Tap 33. These can be selected via a step switch 34 with 10 individual steps 341 ... 350 in the example. The voltage divider resistor 32 is set so that at its tap 33 V _{10 of} the total voltage of the operational amplifier 30 is applied. Correspondingly, the voltage divider resistor 320 is set to ² / _{m of} this total voltage, and the rest accordingly up to the voltage divider resistor 328, at which the Csaint voltage is then applied. From the step switch 34 the signal reaches the base 49 of a transistor 4, which switches a relay 40. The start pulse is given to the XY recorder 5 via a contact 41 of the relay 40 protected by a diode D21. A switch 42 also belongs to the relay 40. In order to start the XY recorder 5, for example with the 7th stage 347, the stages

■ r> switch 34 set to this level. Since the trigger signal ^{receives corresponding to 1} I _{10 of} the voltage value of the maximum voltage, the voltage at the base 49 of the transistor 4 is just large enough for the transistor 4 to open and thus the relay 40 to switch. The voltage at the base 49 of the transistor 4 is also taken off for the illuminated display 7, which is controlled via an integrated circuit 70. The integrated circuit 70 has matching resistors 71, the individual resistors R9 (10 K), KlQ (33 K), RU (0.1 M) and R12 (69 K) and voltage divider resistors 512 (100 K) and 513 (5 K ) contain. The integrated circuit 70 controls 10 light-emitting diodes D1 ... D10, which are each assigned to one of the 10 levels of the trigger signal. Power is supplied via DC voltage connections 13 (+15 V).

In Fig. 6 an example of a circuit of the power supply 14 is shown, which here consists of three bridge rectifiers 140,141,142 is built, which the required Supply DC voltage connections 12 (5 V) and 13 (one + 15 V, one - 15 V). To the Bridge rectifiers also include capacitors C2, C3, C4 (1000 μΡ each) and the capacitors C5 ... ClO (0.22 μΡ "each) and the voltage stabilizers 143, 144, 145.

1 pulse generator

10 transformer
100 tunneling machine

11 voltage divider

12 DC voltage connection (5 V)

13 DC voltage connection (+ 15V / - 15 V)

14 Power supply unit

15 pulse shaper

16 frequency dividers

17 frequency divider

18 decade counter

19 decade counter

2 synchronous time device

20 voltage dividers

21 negators

22 negators

23 operational amplifiers

24 voltage divider resistor (100 K)

25 switches

26 Seven-Segment Decoder

27 Seven-segment display

v) 3 multi-channel tape recorder

30 operational amplifiers

31 resistance group

32 voltage divider resistor (10 K)
320 voltage divider resistor (10 K)

r> - voltage divider resistor (10 K)

- voltage divider resistor (10 K)

- voltage divider resistor (10 K)
328 voltage divider resistor (10 K)

33 tap

Mi 34 ten-position switch

341 level 1

350 level 10

40 "relay

41 Contact

"-, 42 switches

49 base

70 integrated circuit

71 Adaptation resistors

Rl Rl R3 A4 RS R6 Rl R9 RlO RIl RIl

Cl Cl C3 C4 CS

Resistance Resistance Resistance Resistance Resistance Resistance Resistance Resistance resistance resistance resistance

(10 k) (Hk) (10 k) (10 k) (10 k) (10 k) (10 k) (10 k) (33 k) (91 M) (69 k)

Capacitor (0.22 capacitor (1000 Capacitor (1000 capacitor (1000 capacitor (0.22 μ

ClO capacitor (0.22 μΡ)

51 voltage divider resistor (10 k)

57 voltage divider resistor (10 k)

. 58 voltage divider resistor (20 k)

59 voltage divider resistor (250 k)

510 voltage divider resistor (250 k)

511 voltage divider resistor (100 k)

512 voltage divider resistor (100 k), 513 voltage divider resistor (5 k)

Dl diode (light emitting diode)

- Diode (light emitting diode)

- Diode (light emitting diode) DlQ diode

ι-, DU diode

D20 diode

DIl diode

In addition 5 sheets of drawings

Claims (1)

Claim: Device for recording and reproducing several measured values, with a measuring transducer the Sends measured values from several measuring devices to a light beam oscilloscope via a measuring amplifier, characterized in that the measurement amplifier (8) also has a multi-channel tape recorder (3) is connected downstream, which is an X-Y recorder (5) and a synchronous time device (2), the a pulse generator (1) and a pulse selector and starter (6) with illuminated display (7), assigned is.