DE1146665B - Circuit arrangement for measuring devices with deflection elements for monitoring one or more limit values - Google Patents

Description

Circuit arrangement for measuring devices with deflection elements for monitoring Measuring instruments indicating one or more limit values is used in many cases an additional task is posed, which is that the pointer when passing one or more scale points or one if the tolerance range is exceeded Triggers a reporting, control or regulating process. The usefulness of such devices depends on the extent to which the demands for simultaneity and negligible Retroactive effect can be observed. In arrangements in which the pointer on Signal point of the scale simply actuated a contact device is simultaneity achieved. However, an effect on the pointer cannot be avoided. at In another realized design, a control relay is connected in parallel to the measuring device. The simultaneity is not guaranteed here, while the retroactive effect is not matters. To solve the task in compliance with these two requirements Limit value detectors are available after the inductive, capacitive or photoelectric Principle. In many cases, there is another requirement: the signaling should be dependent on the direction of movement of the pointer. As soon as the pointer reaches the reporting point exceeds, the signal should therefore be triggered and persist as long as until the pointer wandered into the normal range of the scale with a downward trend is. The scale ranges of the instrument, signal range and normal range, must be assigned unique relay positions. There are versions of this Kind of become known, one on the inductive, another on the photoelectric Principle is based. A bistable multivibrator is provided for both devices, which tilts when the pointer enters the signal range of the scale and when it exits comes back to the normal tilt position.

In the case of bistable multivibrators, one can tip over from one to the different operating status can be achieved through various measures. The control of the bistable element can come from two sides by positive or negative impulses happen. On the other hand, pulses of opposite polarity of only fed to one side. In a known device of this type, which after the working inductive principle, the flip-flop is activated from two sides by impulses driven with the same polarity. A high-frequency oscillator is used on each side to generate impulses used with inductive feedback. So every pulse generator is two inductive associated coupled coils, which face each other in such a way that one on the pointer arranged shielding plate when a scale limit is exceeded area between them passes through. At the output of the oscillators arises in normal operating condition through Use of a rectifier a DC voltage value, which when shielded the feedback disappears. The size, which is more fundamental in these devices What is important is kept small by using transistors as a component. A boundary mark consists of two pairs of coils, which are arranged next to each other. The shielding plate wanders through both pairs of coils in chronological order. Is moving the pointer from the normal range to the signal range, for example, normally effects the second pair of coils flip the circuit. When the pointer returns to the In the normal range, it is again the last pair of coils passed through which the circuit lets tip over. When the device is put into operation it can happen that the tilted state the circuit is not clearly defined, e.g. it is conceivable that the tilt position in the normal range of the scale is such as it corresponds to the signal range would. In this case, it is sufficient to pass the limit mark once to find the correct one Establish tilted state.

Both pairs of coils cause a double tilt. Through this it is achieved that the switching state of the bistable element corresponds to the areas of the Scale is clearly assigned.

This embodiment has several disadvantages: Adjustment the limit mark on the scale circumference is due to the installation size of the two next to each other arranged coil pairs limited. A tolerance range cannot be arbitrary set small will. The two boundary marks can be mutually exclusive can only be brought so close that the coil assemblies touch. The overturning The signal position also takes place at another point on the scale, such as tilting back the circuit. Another disadvantageous property is the considerable one Additional effort. For example, if one tolerance range is to be recorded, there are two Limit marks with a total of four oscillators required.

In another known device, a relay toggle circuit is provided, which consists of two separate switching branches. The impetus for tipping is through here two photo resistors are given, which means one after the other at the limit mark of the scale a cover plate can be shielded from a light source. This cover plate is arranged on the pointer of the device and follows its movements. A branch is constructed so that the base of a transistor has a contact on the tap of a voltage divider. The voltage divider consists of a photo resistor, which is at negative potential, and another resistor which is at positive Potential is connected. The emitter of the transistor is at zero potential. One terminal of a relay is connected to the collector of the transistor while the other terminal is at negative potential. The relay in this branch actuates a normally closed contact, which is in the collector circuit of the otherwise analogue structure other branch. The two relays each switch in the other switching branch a normally closed contact, one of which is at the base, the other at the collector of the Transistors. If the circuit is tilted to one side, there is a break contact, For example, the contact arranged in the collector circuit, dropped into a branch, because the relay in the other branch has picked up. Will the photo resistor of this branch covered, nothing changes in the tilted position. During the subsequent covering the photo resistor in the other branch increases its resistance value. The on the normally closed contact on the base is closed here. The transistor in the second branch blocks because the base potential is shifted into the positive. The relay drops out. In the first branch, the photo resistor is now illuminated again. The base of the transistor is at negative potential as soon as the relay in the second branch has dropped out and in connection with it the normally closed contact in the last branch has closed.

With this device, the effort and size are insignificant, however, it is inherently unreliable and short-lived. The base of the transistor in one branch there is a sudden switch to negative potential, which is a Significant overuse means. At high measuring speed it can be at This circuit can also cause the relays not to respond.

Photoelectric control devices have also become known, in which switching processes can be initiated by the display means. The Switching states of a breakover voltage circuit caused by covered phototransistors used for control as follows: A widened measuring instrument indicator protects in the event of a signal, a phototransistor placed behind him before exposure, in which In the rest of the measuring range, the light-sensitive component is exposed to the incidence of light. The phototransistor either conducts or blocks depending on its exposure state of him downstream normal transistor, in its collector line a relay is arranged. The relay contacts carry out the actual switching process.

The circuit thus has a monostable effect, i.e. in that by exposure of the phototransistor marked idle state, the relay has dropped out.

In a similar known arrangement, instead of the phototransistors a photo resistor and a thyratron to switch the relay.

The photo resistor has a low resistance during exposure.

The grid potential of the thyratron therefore moves at applied alternating voltage supply in phase with the anode potential. That conductive thyratron pulls the relay in this case. The unexposed photo resistor due to its high atomicity, it causes an out-of-phase potential curve at the grid and the anode of the thyratron, which has been extinguished and the relay has dropped out State left. The character of this circuit is also monostable.

In both circuits it can prove to be disadvantageous that the subdivision »work area - rest areaa by the spatial extent of the light-covering body depends. The cover over the photosensitive control would have to sweep the same angle as the pointer on the idle state Scale division; it becomes the scale arc for a device with an adjustable limit value correspond.

Another known circuit uses two light-controlled, bistable Multivibrators that emit impulses when they are interconnected, their frequency is a measure of the speed of a shaft and its polarity depends on the direction of rotation depends on this wave. The control of the phototransistors used in the multivibrators takes place through a light beam influenced by a perforated disk.

The latter differs from the other institutions mentioned in that with each light pulse caused by a hole there is one in his Sign of the direction of movement dependent electrical impulse is emitted.

The invention relates to a circuit arrangement for measuring devices with Deflection organs for monitoring one or more limit values in connection with a bistable toggle switch, which occurs when a flag arranged on the deflection element passes through is controlled by successively influenced control elements. The invention exists in that in a known manner an electronically operating bistable trigger circuit is arranged in the form of a bistable multivibrator and that also in itself As is known, photoresistors each serve individually as control elements in the circuit lie in the feedback branches of the flip-flop.

The mode of operation of the invention is based on an exemplary embodiment, which is shown in the drawing, explained in more detail. Switching elements with the same Index, which is used to identify their arrangement in the circuit with a dash are provided are of the same size. In Fig. 1 is the schematic structure of the bistable multivibrator shown; in Fig. 2 are all switching parts of the Arrangement reproduced.

In Fig. 1, only those switching elements are a bistable Multivibrators are taken into account, which are important for explaining the mode of operation are.

The flip-flop circuit according to FIG. 1 is from tube technology known. As a new component, however, two photoresistors P1 and P2 are added, the serve as feedback resistors. With R1 and R1 'are two collector resistors which have the same characteristics in this symmetrical circuit. Two emitter-connected transistors are indicated by T1 and T2. The voltage applied to two terminals a and b is directed so that the emitter of the transistors are at positive potential, while the collector resistances are connected to negative potential. Interrupt two cover plates A1 and A2 the exposure falling from an incandescent lamp G onto the photoresistors in chronological order. These cover plates At and Ai are on a pointer, not shown, of the measuring instrument arranged.

To explain the mode of operation of the circuit arrangement, first assumed that both cover plates A1 and A2 are outside the range of both Photo resistors P1 and P2 are located and transistor T1 is conductive. The two Photoresistors P1 and P2 should be covered in the order P1, P2. the Increase the value of the photo resistor, which is first unexposed, does not change the state of the circuit. With the following coverage of the photo resistor P2, the base potential of the transistor T1 is shifted into the positive, so that this locks. Since there is no longer any voltage drop across the resistor Rt, it is the base of the transistor T2 biased negatively via the newly exposed photoresistor P1. He will conductive. The circuit flips. In reverse order it becomes P and then P P1 covered, the transistor T1 is accordingly again conductive.

In the overall circuit according to FIG. 2, the flip-flop is the Circuit characterizing voltage drop at R1 'amplified via a transistor T3.

A relay B is connected to the collector of the transistor T3, which controls a break contact b1.

The contact bt bridges a resistor R8. This resistance is limited the relay current when relay B is picked up to the holding current. Two resistors R5 and R5, the purpose of adapting the multivibrator to the amplifier stage. Two Resistors R6 and R7 together with the resistor R, 'form a combination for Temperature compensation of the residual collector current of the transistor T3. As overload protection two resistors R.n and R2, are used for the photoresistors. The temperature compensation of transistors T1 and T2 is replaced by resistors P1, P2, R2, R2, and three more Resistors R3, R3, and R4 reached.

The mode of operation of the multivibrator has been explained in detail above. The relay B responds when there is no voltage drop at R1, because then the Base of the transistor T3 is at negative potential.

However, in the other stable position of the multivibrator, the resistance is R1, when current flows through it, the relay drops out. The voltage across the resistor1, drops, therefore determines the position of relay B. To the signaling that through the relay B takes place via additional control contacts, not shown, vary too can, these control contacts are provided as changeover switches. The circuit is like this suitable for an upper or lower scale limit. Structural changes are not necessary.

The two photo resistors are opposite each other, so that on the scale the border mark only takes up a small width. The assignment of the signaling to the scale range is clearly determined with little effort. The installation size of the entire arrangement is insignificant.

Claims (4)

PATENT CLAIMS: 1. Circuit arrangement for measuring devices with deflection organs for monitoring one or more limit values in connection with a bistable Toggle switch that occurs when a flag arranged on the deflection element passes through sequentially influenced control elements are controlled, characterized in that that in a known manner an electronically operating bistable trigger circuit is arranged in the form of a bistable multivibrator and that also in itself It is known that photoresistors are used individually as control elements in the circuit lie in the feedback branches of the flip-flop. 2. Circuit arrangement according to claim 1, characterized in that a light source is arranged between the oppositely arranged photoresistors is that when the flag passes by means of two in the direction of deflection and transversely for this purpose, cover plates offset from one another only with regard to the one photoresistor and then covered with respect to the other. 3. Circuit arrangement according to claim 1, characterized in that an output variable taken from a collector resistor of the multivibrator a transistor amplifier circuit acts on a relay. 4. Circuit arrangement according to claim 3, characterized in that by using a normally closed contact (b) the response current and the holding current of the Relays are sized differently. Documents considered: German Auslegeschrift No. 1024 617; German utility model No. 1763 978; French patent specification no. 1 097501.