WO1981002938A1

WO1981002938A1 - Step checking device for a miniature read-only sequence controller

Info

Publication number: WO1981002938A1
Application number: PCT/JP1980/000062
Authority: WO
Inventors: Y Kuze
Original assignee: Y Kuze
Priority date: 1980-04-05
Filing date: 1980-04-05
Publication date: 1981-10-15
Also published as: AU5984580A

Abstract

A step checking device for a sequence controller is supplied with data outputs to be applied to controlled elements, and with outputs of sensors in the controlled elements. Outputs of a read-only memory in a sequence controller are applied to gates (O1) (O8) for generating one-shot differentiated pulses through a connector (5), the output of each of which gates is applied to a first input of a NOR gate (10). The outputs of sensors, each of which detects the correctness of operation in a controlled element corresponding to a data output, are entered through connectors (C1) (C8) and then applied to second inputs of NOR gates (10), respectively. In case of abnormal operation, a NOR gate (10) delivers an output to set a flip-flop (14) to actuate one of light-emitting diodes (P1)(P8) and supply a data-output eliminating signal to the sequence controller through terminals (7).

Description

Details Small read-only sequence ''

The present invention relates to a stroke confirmation device for a sequence controller, and more particularly to a small sequence controller for a stroke controller.

Background technology

The sequence controller is complicated to cope with diversifying control targets, and it is extremely complicated and expensive, especially if an operation confirmation function is added. Therefore, in many cases, small-scale sequencer / knowledge clerks omit this process confirmation function. However, without the process confirmation function, real labor saving and unmanned operation cannot be expected.

Disclosure of the invention

Accordingly, it is an object of the present invention to provide a simple process confirmation device adapted to a small sequence / con- troller.

Another object of the present invention is to obtain a highly reliable, high-performance and inexpensive process confirmation device.

The sequence controller is a step in the sequence. After confirming whether or not the controlled element has been correctly operated in accordance with a predetermined set of data, the process proceeds to the next operation. If there is an abnormality in the operation of the controlled element, the output of data is stopped. '

Control element to check for abnormalities

OMPI It is best to check with the same data and one output that controls the child without time delay. Therefore, the process checking device of the present invention introduces and uses the data and output of the sequence “read only” memory and “read only” memory. For each step of the sequence, each pair of the data output and the output of the sensor that detects whether the operation of the corresponding controlled element is correct or not is determined. Abnormality check 2 Sensor applied with one-shot differential pulse at the falling edge of the data output pulse applied to the input gate and at the end of one operation. Check for detection signal.

If an error is detected, an error signal is output, the data is stopped by the sequence controller, and the data output is stopped. Turn OFF all to protect equipment from abnormal operation. The width of the one shot-differential pulse is about 10 s, which is extremely high performance because anomalies are detected in this short time.

-The process checking device of the present invention can be applied to the field of any small sequence controller with a simple structure and a weight of 220 f and its performance and reliability. And contribute to labor saving and unmanned operation.

Brief explanation of drawings

Fig. 1 shows a plan view of the sequence-con- troller of the present invention.

FIG. 2 shows a perspective view of the present invention.

FIG. 3 shows a circuit diagram of the present invention.

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WIPO i Fig. 4 shows the abnormal check circuit diagram of the present invention, and Figs. 5 and 6 show the timing diagram of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

5 FIG. 1 is a plan view of the sequence checker of the present invention. The case is constructed by combining left and right panel boards 1 and 2 and two upper and lower metal plates 3 and 4 (Fig. 2). Reference numeral 5 denotes a connector. Ribbon • Lead of external sequence controller via cable 6 • 10-only memory Connect to the data output line of

2 Figure). C i and C 2 C s are connectors connected to the outputs of the corresponding abnormality detection sensors, respectively. ^ The normal detection sensor is a sequence control port. The controlled element controlled by the line is operating faithfully according to the data output: ^

15 is detected. P i, P 2, and P 8 are light emitting diodes for abnormal display, 7 is an abnormal signal output terminal, 8 is a reset-switch, and 9 is an external DC power source. The connector that connects to

FIG. 2 is a perspective view of the process checking device of the present invention, and FIG. 3 is a circuit diagram of the process checking device of the present invention.

The data output of the memory is connected to the connector 5 via the connector 15. It is input to the shot differential pulse generation gating device Oi, 02, 08, and its output is applied to the first input 5 of the 2-input NOR gate 10, respectively. The output of the sensor is the corresponding connector V IPO ^ The collectors Cl, C2,..., C8 are applied to the second input of the two-input NOR gate 10 via the shunt circuit 11.

Abnormality is detected by a 2-input N0R gate 10 which has a pair of a data output that passes through a one-shot differential pulse generation gate device and a sensor output. The check circuit is configured.

In the embodiment, it is possible to increase the number of steps corresponding to the force sequence-controller, which uses the step confirmation of eight steps as a reference. -Fig. 4 is a detail drawing of one step of the abnormal check circuit.

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Diode is the shunt circuit 12, the known integration of the data of the memory controller. This is applied to the first input of the 2-input NOR gate 10 via the differential pulse generation circuit Oi due to the delay of the circuit. The output of the sensor corresponding to Di is connected to the two-input NOR gate through a connector Ci, a noise absorption circuit, a gate protection resistor, and a shunt circuit 11. Added to 10 second inputs.

One shot pulse generator circuit The capacitor 13 connected to the input side of the Oi is connected to the lead-only memory. It is held in one by the transient instability ¾ period co-down de capacitors one of Ho霄between data one to output the data one岀Ka to ^W H "level

Now, while the data output is at the "1" level, the two inputs N0R The first input of the gate 10 is "1", but the data is

Ο.ΜΡΙ wi? O-、、 At the moment it changes to "0", a differential pulse of "0" is generated. At this time, if the operation of the controlled element is correct, the output level of the sensor is determined in advance so that the output of the sensor is "1".

The timing diagram in Figure 5 is the relationship between the differential differential pulse Oi of the data output Di and the output Ci of the sensor at that time. Is shown. Pulse width of ^w 1 "of Ci is a differential Pulse width (about 10 s) good Ri Let 's Ru Oh margin back and forth with a focus on wide rather and differential Pulse Ni Se emissions of Sir Oi Determine the mounting position.

As long as the controlled element is operating correctly for data output, two inputs at any point of I, Π, I, W, and V

The output of the N0R gate 10 is "0" and the flip-flop 14 in the N0R gate configuration is set. However, if the controlled element does not operate properly, the output of the 2-input NOR gate 10 will be "1" as shown in Fig. 6. ), Flip-flop 14 is set and its output Q is set to "1" (flip-flop)

14 outputs have built-in inverters).

Light emitting diode when Q reads "1": Pi emits light and indicates an error. "1" of the output Q of the flip-flop 14 is a multi-input NOR gate 15, an inverter 16 and a transistor.

The signal is amplified by 17 and fed back to the sequencer's controller via terminal 7 and backed off to stop data output. . The resistor 18 is for noise absorption.

When the reset switch 8 is pressed after checking and repairing the abnormal part, the noise absorption circuit, the gate protection resistor, and the shunt

O PI

, ^? Via path 19, flip 'flop 14 is reset. Accordingly, the output of the sequencer's controller data is restarted. ·.

As described above, the process confirmation device of the present invention is based on a sequence of eight steps, but is adapted to the sequence controller to which it is applied. It goes without saying that the number of steps is increased. In addition, the embodiment is configured as a compact as an independent unit, but the circuit configuration can be used by being built in the sequence controller α. Of course. INDUSTRIAL APPLICABILITY 'The process confirmation device of the present invention has a weight of 220 ^ and is extremely compact and high performance. In particular, it can be easily adapted to small-scale sequence commands with no process confirmation function, so it can be easily adapted to small and large-sized enterprises from small enterprises to large enterprises. It can be used for automation, and its benefits are large.

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Claims

(7)

Sought

Sequence • Inlet-Ladder's lead only

• Introduce the memory data output and send it to each

Three-input differential pulse is applied to the first input of the sales gate via the differential pulse generation gate, and the lead, gain, and memory are applied to the first input of the sales gate. The output of the sensor for detecting the correctness of the operation of the controlled element driven by the input is applied to the second input of the two-input gate, and the data output is determined. The presence / absence of a failure detection signal of the self-sensor at that time is checked by the differential differential panoresis generated at the point of time, and when an abnormality is detected, m An abnormal signal is output from the controller, and the signal is fed to the sequence controller via a flip-flop, a multi-input circuit, and an amplifier circuit. A sequence to back up and stop the output of data. Rr

2. Sequence Cont.-Introduces the data output of the lite, memory, and memory, and transfers it to the circuits, circuits, and switches. Abnormal check 2 input — ヽ^: 0 R Applied to the first input of the gate through the shot differential panel generation circuit and the read-only one The output of the sensor, which detects the correctness of the operation of the controlled element driven by the memory, is supplied to the two-input N via a noise absorption circuit and a shunt circuit. 0 R The printing force α is applied to the second input of the gate, and the output is generated at a predetermined point in the output pulse. According to the noise, the presence or absence of the abnormal signal of the sensor at the lifespan is checked. When an error is detected, an error signal is output from the two-input NOR gate, and the sequence signal is output through the flip-flop, multi-input gate, and amplification circuit. Feed back to the controller to stop the output of data, and reset the switch to set the above-mentioned flip-flop. Resetting the sequence and restarting the output of the sequence 'controller' read 'only' memory ' A stroke checking device for one case.

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