SK39896A3 - Monitoring device for outdoor adjustable installations using three phase current drive - Google Patents

Abstract

The monitoring device has test signals supplied to the AC leads (A1,...A4)for the operating drive, with detection of corresponding signal parameters dependent on the position of the operated device, the operating drive, or the condition of the AC leads for evaluation via a microprocessor by comparison with expected values. The test signals are generated by a network containing the AC leads, the drive windings (W1,W2,W3) and a signal generator (SG), with detection of the measuring signal parameters via characteristic electromagnetic values.

Description

Connection for control of external mechanisms adjustable by three-phase drives

Technical field

The invention relates to a wiring for the control of external mechanisms, such as switches, bolts, lifting and turning bridges, lock gates and others, adjustable by three-phase drives in which they are connected to a three-phase line or three-phase lines or their cores leading to an external mechanism; by external mechanism and to the three-phase drive located in the external mechanism, they send electrical test signals and test signals influenced by the state and / or position of the external mechanism and / or three-phase drive and / or cores of the three-phase line. are sent to an evaluation unit, such as a computer, and here the signals are screened to determine whether they are in line with the expected value or are different from that expected value.

The invention relates to a wiring for controlling external mechanisms of any type in which three-phase drives are used for the purpose of adjusting the external mechanism between defined end positions which are secured by limit switches. The device according to the invention is usually located in a central unit, and between this central unit and the external mechanism there are three-phase conductors which serve to supply the three-phase drive, the current flow being controlled by the switching elements in the central unit or from the central unit leading to the switching elements such as relays, in three-phase conductors, by means of which it is possible to connect current to the external mechanism. The control circuit is thus connected at the central or at a point between the central and the external mechanism with a three-phase conductor supplying the three-phase drive of the external mechanism through which the position and / or condition of the external mechanism is checked. For the purpose of adjusting the external mechanism, in particular the turnout, a three-phase three-wire conductor (R, S, T, N) is fed to the three-phase drive, the three-phase drive being usually run asymmetrically through the switching means arranged in the three-phase drive. After the external mechanism, in particular the tongue of the switch, has left its end position, the three-phase drive continues to run three-phase symmetrically. When the next end position is reached, the three-phase drive is usually switched off asymmetrically.

BACKGROUND OF THE INVENTION

It is known that three-phase actuators are used to achieve large adjustment distances in the interlocking technique, and for the purpose of saving wiring, the three-phase lines required for adjusting external mechanisms are also used to control the external mechanism and the three-phase lines themselves. It is known from DE-AS 20 38 031 to incorporate expensive circuits in the design of a control current circuit. The semiconductor switches used need more protection to achieve the desired redundancy, which is associated with high costs. Any information is derived from the current direction of a conductor, so that only very little information about the state or position of the external mechanism is obtained. This known circuit creates, for inspection purposes, a wire loop from which an electrically measured quantity is detected for said inspection.

A circuit that is similar to that of the above type is described in DE-OS 37 15 478. This circuit, in which test voltages are permanently coupled between the cores of a three-phase line and thereby sequence sequentially evaluates the signals, requires an enormous computer range to obtained substantial measured quantities for different test conditions. For each individual measurement, the loop of the conductor to which the signal is transmitted is sensed, assessing the compliance of the signal with the expected value or the deviation of the signal from said expected value with respect to the condition and / or position of the external mechanism.

DE-OS 36 38 681 discloses a connection in which the three-phase drive and the cores of the three-phase line in the form of individual wire loops are supplied with signals and the line condition after the application of said signals is evaluated as a measured variable for the state and / or position of the three-phase line three-phase wiring. As in the case of DE-OS 37 15 478, a forced excitation relay is also provided for safety reasons in order to achieve a current cut-off during the measurement procedure.

Furthermore, an adjustment and control circuit is known from DL-PS 15 96 91, in which all information processing and information transmission channels are sequentially checked for their operation. Permanent connection of the measuring voltage and subsequent detection require an extremely high load on the control computer system in order to make a redundant safety-and-unambiguous decision. Thereby, the number of controllable external mechanisms is very limited. In addition, the mains voltage for the measurement is connected to a three-phase motor with low ohmic resistance, which is undesirable for safety reasons. In addition, the test signals are transmitted to the wires of the three-phase line which are connected to each other in the form of a wire loop, so that very little signal information or redundancy is achieved.

It is therefore an object of the present invention to provide a wiring for controlling external mechanisms adjustable by three-phase drives that meets the high demands placed on the reliability and safety of these devices. In addition, this wiring should be easy to make and usable for a large number of external mechanisms without imposing too high a computer capacity requirement. A specific purpose of the computer is to provide a wiring that would allow a four-wire motor connection and that would be functional without forced-wake-up safety relays.

SUMMARY OF THE INVENTION

This object is achieved by using the above-mentioned type according to the invention, for generating the test signals, the signal generator constituting the three-phase drive circuit or its windings and cores leading to the three-phase drive is connected to at least two of the four existing cores. the test signals introduced in the circuit produce a distribution of measured quantities depending on the state and / or position of the three-phase drive and / or the aforesaid conductors, in particular current and voltage distributions, the device comprising measuring elements for measuring electromagnetic quantities characteristic of the measured distribution such as , voltages, phases or electromagnetic quantities derived therefrom.

veins (voltage, phase redundant and sufficiently accurate)

According to the invention, a circuit is provided together with the signal generator used alone or optionally in conjunction with an associated auxiliary generator, with three-phase line cores supplied with test signals or with three-phase drive, in which the test signal produced produces a detectable measured variable in veins. current (or between shifts), so that diversified information can be provided to detect states or positions or defects of external mechanisms. Thus, for example, the end positions of the external mechanism, incorrect adjustments when handling the external mechanism (for example, a crossover switch), defects in the three-phase line, errors caused by ground shifting (pre-survey errors) and Similarly. For example, a vein condition is a vein test to determine if it has been interrupted or a short circuit has occurred. The condition of the external device is to be understood, for example, to detect a faulty or prescribed position of the external mechanism (for example, a switch jumped out). The position (position) of the external mechanism is to be understood, for example, as end positions or one of the intermediate positions. Depending on the design of the external mechanism, a plurality of said states or positions of the external mechanism may be checked by means of detected measurement quantities derived from the test signals. Said detected signals are compared with predetermined or desired signals corresponding to the prescription function of the device (expected values) and the result of the comparison is then evaluated.

In addition, it is an extremely robust circuit that allows the simultaneous measurement of a plurality of measured quantities, so that sequential sensing or measurement of the measured quantities is no longer necessary. The signal generators used need not only be connected during the measurement process, but can remain connected at the same time as the three-phase lines conduct the current, without the danger to the device itself. In addition, the test signals used are selectable in such a way that they do not cause any difficulties in terms of safety technology. The device according to the invention allows the use of any available measuring instruments for measuring current, voltage, phases and / or other derived measured quantities. Here robust and permanently connected measuring instruments can be used which provide corresponding measured quantities with corresponding accuracy.

A preferred embodiment of the invention is included in claim 2. Within this preferred embodiment, it is possible to provide a corresponding circuit comprising a signal generator and at least three of the four existing wires of the three-phase line. However, it is particularly advantageous if the signal generator is connected to all four cores of the three-phase line, since in this case a larger number of measured quantities are available for evaluation. In principle, however, it is also possible to obtain sufficient information about the fourth vein and the three-phase drive even when the signal generator is connected to only three veins of the three-phase line.

In addition, at least one additional generator can be associated with such a signal generator connected to three or four wires of the three-phase line, which additionally affects the distribution of the current or the distribution of the measured values over the whole circuit or at least in its sub-range.

Alternatively, the feature of claim 3 may also be followed. In this case, the additional generator forms a circuit together with the signal generator by interconnecting the individual wires of the three-phase line.

It is essential for the invention to provide a circuit which determines that in the individual veins or in the three-phase drive there is a defined or sufficiently different and detectable distribution of the measured quantities, these measured quantities being characteristic of a certain external mechanism position and / or a three-phase condition and / or three-phase drive.

Using this connection, the distribution of the measured quantities in the cores of the three-phase line and in the three-phase drive corresponding to the prescribed state is first determined and stored for certain test signals applied. During the subsequent inspection of the external mechanism, the actual measured values for the different positions and / or states are then compared with the stored setpoint values and the detected deviations are evaluated as detected faults. If the actual measured values coincide with the stored measured values for the different positions and / or states of the external mechanism, then this situation is evaluated as a determination of the prescribed operating state. By corresponding selection of the test signals or the connection of the wires of the three-phase line, the distribution of the measured values can be achieved in the circuit, in particular the current distribution, which gives the greatest possible redundancy or the greatest possible signal difference.

This also improves the evaluation of the distribution of the measured quantities in the circuit.

For example, it is possible to use a DC or AC generator, a pulse generator or a DC or AC voltage source as a signal generator. Into account

Ďalšie there are also other signal generators.

Using the measured quantities determined in the circuit based on the distribution of the measured quantities, the state of the signal generator can be checked by checking the distribution of the measured quantities at a known state and / or a known external mechanism position. If, on the basis of previous and subsequent measurements, it is established that the external mechanism is in preset mode and that there are deviations in certain measured values during this preset operation of the external mechanism, then it can be inferred that the signal generator is malfunctioning.

The logistics, by means of which the measured variables or the distribution of the measured variables are evaluated with respect to the determination or control of faults in the cores of the three-phase line or in the external mechanism, has the form corresponding to the program in the evaluation unit or computer.

An essential advantage is provided by the embodiment included in claim 11, since in this case the measured quantities are available continuously or permanently for inspection. The measures set forth in claim 13 are suitable for rapid evaluation of the above defects.

In the following, the invention will be explained in more detail with reference to the accompanying drawings. Figures 1 to 7 show various embodiments of an embodiment according to the invention.

Fig. 1 shows a schematic of one circuit according to the invention. The part of the wiring, which is situated within the dashed rectangle and which is indicated by the reference number 1, is usually located in the central office, while the unit indicated by the reference number AU is an external mechanism. The three-phase line switching elements E1, E2 / S3 and S4 may be located either in the central unit or, if remotely controlled, in the external AU mechanism.

In the external mechanism AU there is a three-phase drive with motor windings W1. W2 and W3 and with three-phase power lines A1, A2 and A3. which are connectable to a three-phase network with L1 phases. L2 and L3 via the switching elements L1, L2 and L3 • The neutral conductor L4 is connected to the conductor A4 via the switching element S4.

In the external mechanism AU there are position or limit switches ESI and ES2. which are actuated by corresponding adjustable parts of the external mechanism, such as switches. By correspondingly connecting and disconnecting the three-phase conductors or the wires L1, L2 and L3 and possibly the neutral conductor (N) L4 at the corresponding position of the limit switch ES1 and ES2, the external mechanism can be adjusted in the desired direction. The ESI and ES2 limit switches have a robust design and are actuated by a stable mechanical device. In the case of a switch, the mechanical device is formed by a rod which is connected to the tongues of the switch. This bar transmits the switch tongue position to a mechanism which, when reaching the switch tongue end position, increases the travel path of the tongue between the two end positions to such an extent that the switching of the respective limit switch is achieved even at a small distance between the two switch tongue end positions.

The signal generator included in the circuit according to the invention comprises, according to FIG. 1 also a connection to a three-phase network or three-phase conductors L1, L2, L3 and L4. The signal generator includes resistors R 1 _f R 2, R 3 and R 4. through which the phases of the three-phase network are routed as test signals to the external mechanism. Through high ohmic resistors £ 1, R2. R3 and R4, which preferably have a resistance value greater than 10 kn, are discharged from the three-phase network three-phase test signals, which are fed into the A1 cores. A2, A3 and A4. In the circuit comprising the resistors listed, cores A1 / A2. A3 and A4 leading to the external mechanism and driving the external mechanism create a certain distribution of detectable electrical quantities. On the basis of the phase-shifting AC test signals in those veins to stream IX, 12, 13 and 14, as between the wires form a corresponding differential voltage D l, _t IZ2, U3, U12. U13 and U23. These currents or / and voltages or / or in all cases the resulting phase shifts can be measured and evaluated. Since the test signals are known, as far as current, voltage and phase are concerned, deviations from the expected measured variables can be detected and evaluated as faults of the external mechanism, its drive or Air A2, Al and A4 cores.

In the connection according to the invention, the connection according to FIG. 1 to use the available mains voltage to generate test signals. In particular, this method is based on the principle that time-shifted measurement signals are already available in the three-phase network (h1, L2, L3) and the neutral (L4). This has the advantage that sequential measurement methods are no longer required. In addition, the signal generator need not be disconnected even during the adjusting movement of the external mechanism, when the three-phase network is connected directly to the Air Air A1 and A4 cores leading to the external mechanism, since this is only a high-ohmic connection. It is even possible to observe additionally the phases of the adjustment process (unsymmetrical operation, symmetrical operation). It is also possible to identify errors that could occur during the conversion process. It follows from the above that this is a fixed circuit and a correspondingly robust circuit with a slight probability of error in the circuit itself. Also, no semiconductor components are connected to the conductor loaded with the electromotive voltage, so that there is no cost associated with protection against electromotive voltage.

In the circuit shown in FIG. 1, the signal generator SG is connected by four connections to a four-wire three-phase line leading to an external mechanism, at which time a different signal is taken at each output of the signal generator. Correspondingly, the corresponding current distribution, voltage distribution and phase distribution are thus generated. In principle, it is possible to apply signals to all veins A1, A2. A1 and A4 four-wire three-phase line leading to the external mechanism. It is, for example, possible in the connection shown in FIG. 1 to provide test signals to only three cores of said three-phase line.

If the signals are applied to only two cores, for example by applying a voltage of 60 V to one vein and a voltage of 0 V to another vein, then at least one additional generator is required to create the circuit, as is evident from FIG. 1 and FIG. 6. Here, the resistor circuit forms an additional generator whose resistors connect said conductors. For AC voltage, such an additional generator ZG1 can be realized, for example, according to FIG. 1 with a coil transformer SP1 and SP2 and a core E having coils E1 and SP2 connected to one another and thus a line to the external mechanism, which causes a current distribution on said individual lines. This current distribution allows for a corresponding current distribution, voltage distribution and phase distribution and provides a corresponding number of evaluable measured quantities, which in turn provide information on the state of the external mechanism, the set position of the external mechanism and the state of the cores A1, A2. A3 or A4. ZG2 refers to an auxiliary generator formed by a resistor and a diode. If the test signals are fed from the signal generator to only two cores of a three-phase line, these additional generators are urgently needed. If the tested generators are fed from the signal generator to the three cores of the three-phase line, then the additional generators mentioned are not urgently needed, although the number of evaluable measurands can be increased by the connection of the additional generators in these cases.

Creating and selecting the type of additional generators is a routine matter for a person skilled in the art. It is essential that such additional generators cause a distribution of the measured values, in particular a current distribution in the external AU mechanism or in the Air Air A2 veins. and M connected to a three-phase actuator and so that a sufficient number of measured quantities are available for detection.

Fig. 2 shows a signal generator 1 in which they are used similarly to the circuit of FIG. 1 for generating L1 _f L2 phase test signals. and L3 optionally a three-phase network. In this case, the phase L3 is connected directly through the high ohmic resistor R3 to the vein A3 of the three-phase line leading to the external mechanism. For the purpose of generating additional test signals, the phases L1 and L2 are directly connected through the high ohmic resistors R1 and R2 to the corresponding cores Δ1 and A2. a three-phase line leading to an external mechanism. The neutral conductor A4 leading to the external mechanism is connected to L1 and L1 phases, respectively, for the purpose of generating the test signals via resistors Rg14 and Rg24. L2. As a result, compared to FIG. 1 to a fundamentally different distribution of the measured quantities, which allows better identification of the particularly important state of the jumper. In this connection, the neutral conductor voltage is replaced by an artificial voltage, which is given by the difference between the phases L1 and L2.

The connections of FIG. 1 and FIG. 2 are also applicable when the three-phase network is connected to an external mechanism, but as long as the resistors R1, R2, R3 and R4 provide adequate protection. Otherwise, it is necessary to ensure adequate protection of the signal generator against three-phase voltages.

Fig. 3 shows an embodiment of the invention in which differentiated test signals are used. The signal generator in this case comprises four sub-generators. The generation and differentiation of the test signals or the measured quantities is achieved by using different generator voltages UG1. UG2. UG3 and UG4. Each of the four sub-generators sends a corresponding test signal to one of the A1 cores. A2, A3 and A4 four-wire guides leading to the external mechanism. Resistors R1, R2. R3 and R4 may have different resistance values, which also affects the current distribution in the circuit. Individual measured values are determined by measuring voltage and / or current and / or phase. The measuring elements used for this purpose are, in the simplest case, relays or optoelectronic couplers which, at the predetermined voltage and / or current values, change their state, which is evaluated as yes - no information.

Determination of the most advantageous combination of resistors and starting voltages, etc. in a signal generator, it may be performed based on the wiring requirements. The required criteria are optimum error intervals, adequate sensitivity to failure of the measuring circuit elements and optimum diversity for the computer or computers used.

Fig. 4 shows a circuit diagram according to the invention, in which the signal generator SG comprises two sub-generators UG3 and UG4. The test signals are fed to the four-conductor line leading to the external mechanism via possibly the same or different resistors R1. R2. R3 and R4. Both sub-generators UG3 and UG4 generate +60 V respectively. -60 V, which, through resistors R3 and R4, are applied to the conductors A3 and A4 of the three-phase line leading to the external mechanism. No generators are connected to resistors R1 and R2. However, these resistors cause a current distribution in the veins A1 and A2. With this signal generator, triple measurements can be diversified, combining voltage measurements U12-U13-U23 with I3-U14-U24. These triple combinations, which are, for example, evaluated by two computers, i. computer A and computer B provide an error interval between the correct positions and the wrong position of the external mechanism, which is large enough for a large number of application cases.

Fig. 5 shows a circuit according to the invention in which the voltages occurring between the individual cores A1, Δ2, Δ2 and A4 are sensed by differential current transformers. In principle, any measuring instrument can be used to determine the measured quantities. However, the above-mentioned measuring transformers are characterized by high robustness and surge resistance and favorable electromotive behavior with respect to the iron core saturation properties. This measurement method is based on the principle that time-shifted measurement signals are automatically available in the three-phase network due to the phase shift between the phases and the neutral. The differential current will only provide signals that are easy to evaluate when the external mechanism or circuit assumes a characteristic state (end position). In the case described above, the resistors S1, R2 are not shown in the diagram. R3 and R4.

Fig. 6 shows a circuit according to the invention in which the circuit of the measuring resistors is connected to the cores A1, A2. A3 and A4. which lead to an external mechanism. The signal generator supplies a +60 V test signal through a resistor R3 on the vein A3. while the second terminal of the signal generator is connected with a 0 V connection value through a resistor R4 to the vein A4. When using other resistors R13. R14, E2A, R34 as well as R12. R32 and R1 and R2 are a circuit by means of which current, voltage or phase distributions are achieved, which in the veins A1, A2, A3. A4, or between these cores, provide the corresponding distribution of measured values.

This circuitry has the value that by measuring a single voltage value it is possible to obtain information on the condition and / or position of the entire external mechanism. This is possible based on the selected resistance values of the individual resistors. In particular, by constructing this circuit, a high information content is obtained by measuring the transverse current in the diagonal A1-A2, since the circuit at this point behaves similarly to a measuring bridge. The number of resistors is a special type of auxiliary generator, which together with a signal generator connected to two cores A3 and A4 forms a circuit with a corresponding distribution of measured values.

The wiring shown in FIG. 7 is a special case of the measurement method of FIG. 3. In this case, the signal generator SG forms three phases L1 _r L2 _r L3 of the three-phase network together with the resistors R1. R2. R3. In a three-phase network, these three generator voltages (generator windings) are actually connected to a star.

This method is based on the principle that time-shifted measured quantities are automatically available in the three-phase network due to the phase shift between the phases and the neutral, and these quantities can be detected accordingly.

The circuit comprising the three-phase coils, the limit switch and the wires of the external mechanism alone is not considered to be useful in the present invention. It is only by supplementing this circuit with a signal generator and optionally an additional generator according to the invention that a circuit is obtained which provides a sufficient number of measured quantities.

Claims (14)

PATENT CLAIMS 1. Wiring for the control of external mechanisms adjustable by three-phase drives, such as switches, bolts, lifting and turning bridges and lock gates, in which they are connected to a three-phase line or three-phase lines or their cores leading to or leading to an external mechanism; test signals are applied to the external mechanisms and to the three-phase actuator present in the external mechanism, and these test signals are influenced by the condition and / or setting of the external mechanism and / or the condition of the three-phase actuator and / or and fed to an evaluation unit, for example a computer, where they are evaluated to determine whether they agree with or differ from the expected value, characterized in that a signal is generated to generate test signals Generator (SG) forming a circuit with three-phase drive or its windings (W1, W2, W3) and with cores (A1, A2, A3, A4) leading to a three-phase drive connected to at least two of the four cores (A1, A2, A3, A4) of the three-phase line, whereby the applied test signals create in the circuit a distribution of measured quantities, in particular current and voltage distribution, which depends on the state and / or setting of the three-phase drive or / and the state of cores (Al, A2, A3, A4) and in that the circuitry comprises a measuring device for measuring the electromagnetic quantities characteristic of a given distribution of the measured quantities, for example the current, voltage or phase intensity or electromagnetic quantities derived therefrom. Connection according to claim 1, characterized in that the signal generator (SG) is connected to at least three of the four cores (A1, A2, A3, A4) of the three-phase line leading to the external mechanism (AU), and to three or four of these cores (A1, A2, A3, A4) two, preferably three or four different voltage signals are provided. Connection according to claim 1, characterized in that the signal generator (SG) is connected to at least two of the four cores (A1, A2, A3, A4), the connection comprising at least one additional generator (ZG1, ZG2) which is connected between at least two veins (A1, A2, A3, A4) or which connects at least two veins (A1, A2, A3, A4). Connection according to one of Claims 1 to 3, characterized in that the signal generator (SG) is a DC generator, an AC generator, a pulse generator, a DC voltage source, an AC voltage source or a similar generator. Connection according to one of Claims 1 to 4, characterized in that the signal generator comprises for at least three connected cores (A1, A2, A3, A4) a resistance (R1, R2, R3, R4), in particular a high ohmic, through which the phase of the three-phase network (L1, L2, L3, L4) is connected to the vein (A1, A2, A3, A4) leading to the external mechanism, so that said phase of the three-phase network (L1, L2, L3, L4) is highly ohmic applied as a test signal into the assigned vein (A1, A2, A3, A4). Connection according to claim 5, characterized in that the test signal for one vein (A4) is taken from two phases (L1, L2) of the three-phase network (Rg14, Rg24) (Fig. 2), both phases (L1, L2). ) the three-phase networks are connected to the vein (A4) through one resistor (Rg14, Rg15). Connection according to one of claims 1 to 6, characterized in that the signal generator (SG) comprises a plurality of current and / or voltage generators (UG1, UG2, UG3, UG4), preferably a current or voltage generator for each connected one. vein (A1, A2, A3, A4). Connection according to one of Claims 3 to 7, characterized in that the auxiliary generator (ZG1, ZG2) associated with the signal generator (SG) is connected at least between two cores (A1, A2, A3, A4) or connects at least two of these cores . Connection according to one of Claims 1 to 8, characterized in that it comprises a resistor connected between at least two cores (A1, A2, A3, A4) and / or a complex impedance (inductance) for carrying out the complex circuit as an auxiliary generator (ZG1, ZG2). , capacitance) and / or a linear component (diode) or / and a transformer or transmitter inductively connecting at least two cores (A1, A2, A3, A4) or / and at least one cored diode (A1, A2, A3, A4) and / or a non-linear component and / or a complex resistance (ohmic resistance, inductance, capacitance). Connection according to one of Claims 1 to 8, characterized in that the current intensities in the veins (A1, A2, A3, A4) and the voltage between the individual veins (A1, A2, A3, A4) are measured as electrically measured circuit values; / and their phase shift (time shift). Connection according to one of Claims 1 to 10, characterized in that the signal generator (SG) is permanently connected to the cores (A1, A2, A3, A4), that is to say also during the operation of the three-phase drive when adjusting the external mechanism. Connection according to one of Claims 1 to 11, characterized in that the signal generator (SG) delivers the same test signals to the same conductors (A1, A2, A3, A4) in predetermined periods. Connection according to one of Claims 1 to 12, characterized in that the individual measured values in the circuit are substantially simultaneously measurable and ready for evaluation by a measuring device or measuring devices included in the circuit. Connection according to one of Claims 1 to 13, characterized in that the state of the signal generator (SG) is checked by means of the measured quantities of the circuit at a predetermined setting of the external mechanism and / or at a known vein condition (Al, A2, A3, A4). ) and / or three-phase drive.