DE1648587A1 - Calibration device for electronic textile fiber monitoring system - Google Patents

Description

Calibration device for electronic textile fiber monitoring system The invention relates to an electrical calibration device by means of which pulses Defined frequency, width, height and plank steepness can be generated to as pulse train standards for calibration and testing in an automatic dextile fiber monitoring system to serve, as described for example in patent application L 41 625 IXc / 47k will.

In the cited patent application, the calibration arrangement is automatic activated when the Zettler is switched off and indicates via control lamps whether the electronic Part of the facility also really works with the set sensitivity.

This task, electronic signal processing units in textile fiber monitoring systems to calibrate and / or to monitor is carried out by the calibration device according to the invention solved by the fact that the pulses, which the photocell of the test head to the electronic Signal processing system emits, simulated and entered into this be, so that this system by assigning its output signals to the such defined input signals can be calibrated. This calibration device is constructed so that a circuit device is provided which in relation on the amplitude, the distance and the width can deliver defined pulses that the signals generated in the monitoring device by the detected faults simulate and that the output pulses of this circuit device through transmission means are connected to the electronic monitoring device, so that the monitoring device is checked and calibrated by means of the impulses which the monitoring device generated signals are simulated if corresponding errors are displayed.

In the standard version ten different error sizes are mapped as impulses, for example --1, 2%, 3%, 4%, 5%, 8%, 10%, 12 *, 15% and 20%.

There are 1% - (measuring) resistors, Zener diodes for generation constant voltages and extremely stabilized trigger stages are used. When considering of all possible interfering influences, the error variables with a tolerance of less simulated as 10%. For example, a simulated 1% error can in reality 0.946.

The following is a structure and operation of an embodiment the calibration device explained on the basis of a figure.

With the two-pole switch 706, a stabilized via a Zener diode can be used AC voltage to the two parallel-connected primary windings, which are wound in the same direction of the isolation transformer 707 can be switched. The feed is symmetrical to the ground via the two equally large capacities at the entrance of the network transformer. A control lamp 710 indicates whether the device is on. The secondary side is to the transmitter a Graetz bridge 709 connected for full wave rectification. The connection point of those valves of the rectifier circuit 709 which are destroyed by one of the two Half-waves of the current flow through is grounded. On the DC side is the Bridge connected to a filter element, which is called F (-Vierpol with the capacitors 711, 712 and a resistor 713 is constructed. At the in series with this resistance 713 connected Zener diode 715 is therefore a defined, constant DC voltage, that of the further calibration device as the supply voltage is fed.

The actual calibration circuit has a stable flip-flop 717, which is formed by a pair of transistors 718,719.

The transistors of the corresponding positive feedback flip-flop vibrate at an idle frequency, which is caused by the interaction of the capacities 720 to 723 determined with the resistors 725 to 728 and is chosen such that a predetermined pulse width of, for example, 0.2 seconds and a sweep frequency of, for example, 2 Hertz is achieved. The output voltage of the astable multivibrator feeds a differential circuit 730, which consists of a resistor 732 and a capacitor 733 consists, through this circle are the planks of the pulse of the output voltage of the flip-flop made steeper, so that with this Voltage can be triggered by a monostable multivibrator. The astable flip-flop thus only supplies the trigger pulse of the monostable multivibrator, without its output voltage otherwise influencing, In the arrangement of the monostable multivibrator is a Pair of transistors 737, 738 connected together. The one that steepened on its flank negative pulse at the output of the differentiation circuit 730 opens the input transistor 737 the downstream flip-flop completely, creating a pulse of a given size and width is generated, which only depends on the time constants of the monostable multivibrator depends. These are due to the interaction of the resistors 740, 741 with the capacitor 742 determined. It has been shown that to simulate actual operating conditions a slightly rounded pulse, for example with a pulse width of 0.001 seconds and a pulse rate of 2 Hertz is most suitable.

The output voltage of the monostable multivibrator becomes the impulses Forming network 750 supplied, which consists of a diode 751, a resistor 752 and a capacitor 753 consists. Using this network, the desired Form of the impulses generated. The pulse of the forming network becomes the base of a transistor 757 in emitter follower formwork, at the output of which a Zener diode 760 connected. This gives a constant output voltage, if only the base voltage of transistor 757 above a certain minimum value, for example 3.9 volts. The calibration circuit is with a precision switch arrangement provided, to which a potentiometer 762 and a rotary switch 763 belong to a Number of series resistors 765, each of which has a predetermined value, optionally to turn on the circuit, so that any of the thread monitoring device The size of the defect to be detected can be mapped by a corresponding pulse can. The resistor 768 can be short-circuited via a switch 767, whereby a greater setting accuracy is achieved.

This calibration device can in a known manner via an anti-coincidence circuit be connected to one of the control units of the thread monitoring device, so that only one of the two, either the calibration circuit or the relevant one Electronic control unit to be calibrated and monitored in relation to each other is switched on is. A calibration relay 769 and a five-pin socket 789 are provided for this purpose. In addition, a connection socket 780 is short-circuited when the Zettler is running and open when the Zettler stands still, so that the predetermined output signal of the calibration device can get into the control unit in order to calibrate or monitor them. Plug connections 788, 789 are used to connect the calibration device to various embodiments the control units. In this way, depending on the position of the switch 763 automatically emits a predetermined pulse to the thread monitoring device, a flashing of the fuse lamp on the Control unit front panel causes. When it flashes, the control unit amplifier is working properly; if the If, on the other hand, the lamp does not light up, the output voltage of the amplifier has dropped and some correction needed. If the calibration device remains plugged in permanently, so it can be used to calibrate the thread monitoring device and continuously monitor their sensitivity.

Claims (3)

Claims 1. Calibration device for testing and calibrating an electronic t} monitoring device, which photoelectrically diameter and length errors of Shows yarn and fabric, characterized in that a switching device is provided, which defined the distance and the width with respect to the amplitude Can emit pulses that are detected in the monitoring device by the Errors generated simulate signals and that the output pulses of this circuit device connected by transmission means to the electronic surveillance device so that the monitoring device is checked and calibrated by means of the pulses which simulates the signals generated in the monitoring device, if corresponding errors are displayed. 2. Calibration device according to claim 1, characterized by a device to generate a pulse that determines the beat, one of the planks of this pulse steepening differentiation circuit, a monostable multivibrator, which by the steepened Pulse is triggered, a downstream of this flip-flop, The shaping network determining the shape of the triggered impulses and a Controllable device for adjusting the amplitude level. 3. calibration device according to claim 2, characterized in that the Device for generating a pulse that determines the clock from a negative one There is an astable multivibrator generating pulses.