CS215701B1 - An electronic device for indicating a exceedance of a set value of a physical quantity, such as an electrical capacity - Google Patents

Abstract

The invention relates in particular to the field of sheet-fed printing machines. The invention solves the problem of indicating the exceeding of the set value of a physical quantity, such as e.g. electric capacitance, inductance, electric resistance, which changes by a small value depending on the occurrence of the monitored substance in the sensor area. The electronic device according to the invention comprises a first pulse generator (1), controlled by the value of the indicated physical quantity, its output is connected to the input of the first pulse counter (2), the output of the first pulse counter (2) is connected to the reset input of the first pulse counter (2) and to the reset input of the second pulse counter (5) and the output of the second pulse generator (4) is connected to the input of the second pulse counter (5), the output of the second pulse counter (5) is connected to the input of the shaping circuit (3), or the first pulse generator (1) controlled by the value of the indicated physical quantity and the second pulse generator (4) are mutually connected. The first pulse generator (1) may be formed by an RC or LC oscillator, at least one of its elements influencing its time constant with its electrical value is formed by a sensor (6).

Description

BACKGROUND OF THE INVENTION The present invention relates to an electronic device for indicating an overshoot of a set value of a physical quantity, for example an electrical capacity.

In some cases it is necessary to check and possibly indicate that the set value of the physical quantity is exceeded. This physical quantity is usually electrical capacity, resp. the dielectric constant of the environment between the capacitor plates, or the electrical resistance of the environment. This control and possible indication is often used to control the quality or quantity of material occurring in the controlled load area.

The device for checking the setpoint overrun is often set up for the presence of a certain amount of material which, by its presence in the controlled area, causes a change in a physical quantity of the controlled area environment, e.g. a dielectric constant of the environment. changing the resistance of the environment, for example, as the concentration of a substance in the solution increases. Changes in physical quantities, the exceeding of whose value is controlled by these devices, are relatively small relative to their initial values, resulting in considerable complexity and complexity of the devices.

These devices are often used, for example, in printing technology, where they are used to check the correct supply of paper to the working parts of printing machines, where two suitable electrodes are placed at the appropriate paper transport point, between which transported paper forms the scanning capacitor plates. the circuitry of the apparatus for controlling the setpoint of the physical value, in this case the electrical capacity of said capacitor, the apparatus being generally set to signal the capacity of the capacitor corresponding to the presence of two or more papers on top of each other.

The principle of known devices of this type is that the sensing capacitor is generally part of the RC or LC circuit of the k & Ltu generator, the frequency of which is evaluated by a suitable evaluation circuit. By changing the electrical capacitance of the sensing capacitor due to the presence of paper between its electrodes, the frequency of the generator output voltage is changed, and if it is impermissibly changed due to the presence of two or more paper between the sensing capacitor plates, the evaluation circuit signals exceeding the set value.

A disadvantage of these devices is the requirement of very high stability over time for the device circuitry, especially its generator and evaluation circuit. This requirement increases the complexity of the device, its cost and, due to the need for temperature compensation of its circuits, leads to a relatively high assembly effort.

These disadvantages are largely eliminated by the electronic device to indicate that the physical value of the setpoint has been exceeded, in which the output of the first pulse generator is connected to the input of the first pulse counter, the output of the first pulse counter is connected to the zero input of the first pulse counter. the input of the second pulse counter and the output of the second pulse generator are connected to the input of the second pulse counter, wherein the output of the second pulse counter is connected to the input of the forming circuit, or the first pulse generator and the second pulse generator are interchanged.

The advantage of the electrical equipment for indicating the exceeding of the set physical quantity is its simplicity and manufacturing demands and if both generators are designed in the same way, the device according to the invention shows high stability even without dusty temperature compensation.

Exemplary embodiments of the electronic device of the invention are in the drawings where Figs. 1 and 6 show a block diagram of the device of the invention; Figs. 2 to 5 an exemplary embodiment of the device of Fig. 1.

The output of the first pulse generator 1 (Fig. 1), controlled by the value of the indicated physical value, is connected to the first pulse counter 2 output, the first pulse 2 pulse output is connected to the pulse counter 2 reset reset and second pulse counter reset input and second generator output. 4 pulses are connected to the input of the second pulse counter 2, wherein the output of the second pulse counter 2 is connected to the input of the shaping circuit J. The output of the shaping circuit J is connected to the input of signaling means not shown, or to the actuator of a device not shown. the device according to the invention cooperates.

The first pulse generator 1 generates at its output a voltage of a certain kilometer of rotation in the form of, for example, rectangular pulses, the frequency of the output voltage being controlled by the value of the indicated physical quantity. The output voltage from the first pulse generator 1 is applied to the input of the first pulse counter 2, which counts the pulses generated by the first pulse generator 1. The output of the first pulse counter 2, at which ae appears in the event of a full or full pulse. the overflow of the first pulse counter 2 is connected to the reset inputs of the first and second pulse counters 2, 2. The second pulse generator 4 generates pulses at a constant repetition rate approaching and at the frequency of the first pulse generator 1. The pulses from the output of the second pulse generator 4 are counted by a second pulse counter 2, preferably the same as the first pulse counter 2, the output of which the pulse appears when the pulse is full or full. An overflow of the pulse counter 2 > 3 ' power adjusts.

In the event that the indicated physical quantity does not exceed the set value, the frequency of the first pulse generator 1 is slightly higher than the frequency of the second pulse generator 4, and the first pulse counter 2 is filled, respectively. overflows before the second pulse counter. The pulse from the output of the first counter 2 resets the first and second counters 2, 6 and the cycle of counting the pulses by both counters 2, 5 ® * is repeated.

If the indicated physical quantity exceeds the set value, the frequency of the first generator 1 is somewhat lower than the frequency of the second pulse generator 4, and the second pulse counter 2 is filled or lowered. overflows before the first 2 pulse counter. At the output of the second counter ²⁸ a pulse is formed which is suitably shaped in the shaping circuit The output signal of the shaping circuit J activates signaling means (not shown) indicating that the set value of the physical quantity has been exceeded or actuator (not shown). cooperates, which switches off the device (not shown).

The control of the frequency of the first pulse generator 1 by the value of the indicated physical quantity is ensured such that at least one of the elements of the first pulse generator 1 affecting the time constant by its electrical value and thereby 1 the frequency of the first pulse generator 1 constitutes a sensor 6 The physical quantity affects its electrical value.

Giant. 2 shows an exemplary embodiment of the device of FIG. 1, in which the pulse generator X is an RC oscillator and the sensor 6 is a capacitor 2 of its RC member containing also a resistor 8. The capacitor 2 de β is preferably deactivated. which in this case is a dielectric substance is transported between its plates, whereby its dimensions and the dielectric constant affect the electrical capacity of the capacitor 2 ^and hence the frequency of the pulse generator 2.

Giant. 3 shows the exemplary embodiments of the device of FIG. 1, in which the pulse generator 1 is an RC oscillator and the sensor 6 is a resistor 8 of its RC member containing such a capacitor 2. The resistor 8 is formed by two electrodes between them. the value of the indicated physical quantity is changed by resistance, eg thermometer, photoresistor and the like.

Giant. 4 shows the exemplary embodiments of the device of FIG. 1, in which the Pulse Generator 1 is an LC oscillator and the sensor 6 is a capacitor 2 of its LC member containing such inductance 11, not shown. The capacitor 2 ^and other circuits are similar to those described The embodiment of FIG.

Giant. 5 shows an exemplary embodiment of the device according to the invention of FIG. 1, in which the pulse generator i is an LC oscillator and the sensor 6 is inductive 11 of its LC member including a capacitor 2 (not shown).

The first and second pulse generators 1, 4 are preferably of the same type as shown in Figures 2 to 5 and the elements of the second generator 6 corresponding to the elements of the first pulse generator 1 constituting the sensor 6 are adjustable in the electrical values. In case the sensors 6 are a capacitor 2 (FIG. 2) of the RC member of the first pulse generator 1, the electrical value of the capacitance 2 of the second pulse generator member 6 is adjustable. In case the sensor 6 is the resistance 8 (Fig. 3) of the RC member of the first pulse generator 1, the value of the electrical resistance reap is adjustable. The identity of the type of the first and second pulse generators 1, 4, largely ensures the temperature coincidence of the two pulse generators 1 and thus the temperature compensation of the device. The thermal overlap of both pulse generators 1, 6 also supports that the adjustable elements of the RC member of the second pulse generator 6 correspond to the RC elements of the first pulse generator 1 constituting the sensor 6 so that the other corresponding sl elements RC of the two pulse generators 1 are identical. practically the same parameters.

The electrical values of the adjustable elements of the RC member of the second pulse generator 6 together and the electrical values of the other elements of the RC member of the second pulse generator 6 determine the value of the physical quantity to be exceeded.

This is similarly the case when both pulse generators 1, 4 are LC oscillators.

In the case where the sensor 6 forms the capacitor 2 of the ^LC circuit of the first pulse generator 1, the electrical value of the capacitor 2 of the circuit of the second pulse generator 4 is adjustable and in case the sensor 6 forms the inductive number 11 of the LC circuit of the first pulse generator 1 .

If the set value exceeds the set physical value by increasing the frequency of the pulse generator 1, the shaping circuit J is supplemented by a circuit (not shown) whose pulse appears only when there are no pulses from the output of the second pulse counter 2 or the first generator 1. The pulse generator and the second pulse generator 6 are interchanged (FIG. 6) and the apparatus operates similarly to that described in FIGS. 1 to 5.

The apparatus according to the invention can be used, for example, on printing machines, using a capacitor sensor between which the paper passes to indicate that the paper has exceeded its thickness, i.e. to indicate an illicit state where two or more sheets of paper are transported on top of each other; in devices to indicate the set point exceeded * slightly changing temperatures, lighting, etc.

The device according to the invention can also be used to indicate that some of the contaminants are contaminated with water by using a sensor comprising two electrodes immersed in controlled water, changing their electrical resistance depending on their contamination.

Claims (5)

SUBJECT OF THE INVENTION An electronic device indicating the overrun of a set value of a physical quantity such as electrical capacity, characterized in that the output of the first pulse generator (1) is connected to the input of the first pulse counter (2), the output of the first pulse counter (2) is connected to the reset input of the first counter ( 2) the pulses and the resetting input of the second pulse counter (5) and the output of the second pulse generator (4) is connected to the input of the second pulse counter (S), the output of the second pulse counter (5) is connected to the shaping circuit (3) or the first pulse generator (1) β the second pulse generator (4) is interchangeable. Electronic device according to claim 1, characterized in that at least one of the elements of the first pulse generator (1) forms a physical value sensor (6). 3, 5. Electronic device according to claim 2, characterized in that the first RC oscillator generator and the sensor (6) are a capacitor (7) of its RC member. (1) pulses is Electronic device according to claim 2, characterized in that the first generator (1) of the RC oscillator and the sensor (6) is a resistor (8) of its RC member. pulses them Electronic devices according to claim 2, characterized in that the first LC oscillator generator and the sensor (6) are a capacitor (7) of its LC member. (1) pulses is 6. Electrical apparatus according to claim 2, characterized in that the first pulse generator (1) is an LC oscillator and the sensor (6) is an inductance (11) of its LC member. Electronic device according to claim 1, characterized in that the first pulse generator (1) and the second pulse generator (4) are of the same type and the elements of the second pulse generator (4) correspond to the elements of the first pulse generator (1) forming the sensor (6). adjustable electrical values.