DE1042000B - Counter for axle counting systems - Google Patents

Description

Counter for axle counting systems In counters for axle counting systems in railway safety systems, the number of possible counting positions must be one greater than the largest number of axles in the track section, otherwise the starting position of the counter will be reached when the train arrives and the track section will be reported as "free" ahead of time . In order to achieve the prescribed number of different counting positions of the counter with as little effort as possible, a staggered arrangement of several counting devices is often chosen. Here, a counter changes its state with each counting pulse. A subordinate counting organ changes its state only when the preceding one has once passed through all the states that it can assume. This downstream counting organ can be followed by a further counting organ in a corresponding manner, and so on. If there are N counting devices, each with n different states, the maximum number of axles allowed in the track section is x = zaz - 1.

A staggered arrangement of the counting organs can be dangerous for the Railway operations arise when, as a result of a malfunction, a subordinate counting unit is not advanced. Let it be B. assumed that counting organs with only two different states are used, counting according to the binary number system cut. If the forwarding of the first downstream counter is then disrupted, so the track section is reported as "free" after every second axle has entered, there the upstream counting element returns to its starting position after every second axis. This creates a considerable risk for railway operations.

To avert this danger it is proposed according to the invention to assign to the first counting step following the basic position that change in status of each counter that causes a change in the state of the downstream counter, and to provide a monitoring device whose response depends on the state of the Z, Vhlorgane after proper processing of the counting pulse following the initial position occurs. The basic effect of the arrangement according to the invention can be seen from the table in FIG. It is here, for. It is assumed, for example, that the counter consists of the three counting elements A, B, C , each of which can assume two different states 1 and 0. In the basic position, the z. B. may be assigned to the free track (x = O axes), all three counting elements have the state 1. If an axis enters the track section, the state of the counter A changes from 1 to 0. This has the consequence that the counter B also changes from 1 to 0. This process in turn causes the change from 1 to 0 in the counter element C. The process described only works properly if the further switching of all the counter elements works without errors. So you have the opportunity to monitor the counter when this state is reached and to ensure that it is working properly, e.g. B. to make the later vacancy of the track dependent. If there is a fault in the indexing of the counting elements only after the first axle has entered, the track cannot be reported as being free, at least during the counting. The track is then reported as "free" when the train leaves if the number of axles remaining in the section is equal to the counting error that occurred; however, since it is very unlikely that a train will stop in this position, such an error can usually be accepted -, verden. In the event of a fault, an occupancy message is given when the track is free, so that the fault is automatically noticeable.

The states change when the second, third, etc. axis is approached the counting organs as indicated in Figure 1, d. that is, the second axis brings the counting element A from 0 to 1 and the third axis again from 1 to 0. This changes the status this downstream counter B from 0 to 1 comes about. Also all other changes of state take place according to the binary number system.

Application examples of the invention are explained in more detail in FIGS. To simplify the representation, the logic circuit symbols are shown in FIGS. 2 to d electronic circuit technology using transistors and blocking cells used as far as the clarity of the representation allowed. But the invention is not limited to this type of circuit technology. You can z. B. also through Relay circuits or with the help of magnetic core memories or Like. Realized. Fig. 5 shows an example of the technical implementation of part of the circuit of FIG. 3. It is also assumed in all examples -be that counting according to the dual number system, on the one hand because of the simplicity of the illustration and, on the other hand, because the application of the invention in use of counting organs with only two different states is particularly advantageous. However, the invention is not restricted to this either. It can also be useful at Counting tverken with counting organs are applied that have more than two different ones Allow states such as B. when using shift registers with three or more links, with rotary selectors or with relay chains with any number of different ones Counting positions. Furthermore, in the examples there are always only three staggered counting organs has been presupposed; the circuits can, however, on an arbitrarily large number of Counting organs are easily expanded.

The count value of FIG. 2 has two separate groups of Zählorganen, of which the group 10, 20,30 38 intended only for the Einzählung, the group 18, 28, only for the enumeration. The counting elements may be, for example, bistable switching circuits, each consisting of two transistors. In the position shown, all tilting circles may have position 1. Here the upper transistor is conductive and there is a positive potential at its outputs. The lower transistor is blocked, its outputs have negative potential. If a pulse is fed to the counting input EE when an axis is moving in, then a brief positive potential occurs at the input of the tilting circuit 10, which causes the tilting circuit to move to the 0 position. In doing so, the negative potential at the outputs of the lower transistor is transformed into positive potential. An equalizing current flows via the capacitor 201 and the resistor 202 to the fixed voltage U4. The voltage U4 is selected so that the sum of this voltage and the voltage drop across the resistor 202 when the breakdown circuit 10 overturns is sufficient to cause the breakdown circuit 20 to tilt. This trigger circuit then also changes its state from 1 to 0. As a result, the same equalizing process takes place on capacitor 301 and resistor 302 as before on capacitor 201 and resistor 202, so that trigger circuit 30 also switches from state 1 to state 0 is brought. In this way, the count-in pulse of the first axis has brought all tilting circles to the 0 position. Therefore, there is now a positive potential at all inputs of the coincidence gate 40. The gate now also gives positive potential a1) at its output. which is fed to the bistable tilting circuit 46. As a result, the upper transistor of the trigger circuit 46 is blocked, and the trigger circuit changes its state, so that the lower transistor is now conductive. The tilting of the tilting circle 46 is thus a confirmation that the change in state of all the counting organs has perfectly occurred in the first counting step. After the circle 46 has tilted, our transistor emits a positive potential, which reaches one of the inputs of the coincidence gate 49. This is a condition for the later vacancy report of the track section.

When further axes enter the state of the counting devices changes, as indicated in the table shown in FIG. Now move the axes out of the way Track section, the corresponding processes take place in the counting group for the count. If as many axles are extended as retracted, they have Corresponding counting elements in the counting-in and counting-out group are in the same position. The gates 12, 14, 16, 22, 24, 26 and 32, 34, 36. In the position shown is at both entrances of the coincidence gate 14 has a positive potential. Therefore, the outcome is positive Potential that is passed through the mixer 16 to the lower input of the coincidence gate 42 arrives. If both counting members 10 and 18 were in position 0, it would the output of the coincidence gate 12 lead positive potential, which is also about the mixing gate 16 would go to the lower input of 42. Only if the counting organs 10 and 18 occupy different positions, none of the coincidence gates lead 12 and 14 positive potential. The output of the mixing gate 16 therefore also leads in this case no positive potential. Now all three counting organ pairs have 10/18, 20/28 and 30/38 have the same position among each other, so all three inputs lead of the coincidence gate 42 positive potential, so that the output of the gate 42 leads to a positive potential. This is a further condition for the vacancy report of the track section.

It is difficult to find gates 12, 14, 16, 22, 24, 26 and 32, 34, 36 to be designed in such a way that in the event of a line break or failure of a component the coincidence in the position of the counting organs is not indicated even if it does not exist. This could, under certain circumstances, already occur at the entrance a certain number of axles the track can be reported prematurely "free". To this To avoid this, the bistable trigger circuit 48 is provided. He's gonna tip over as soon as a counting pulse reaches the counting input AE. This positive impulse blocks the upper transistor of the breakdown circuit 48, so that the breakdown circuit its state changes and the lower transistor becomes conductive. It appears at the lower output of the Tilt circle 48 positive potential, which is the left input of the coincidence gate 49 is fed. The bistable trigger circuit 48 thus prevents a vacancy message comes about before axles move out of the track section. This will make the The danger that can arise from the failure of the gates 12, 14, etc., is essential reduced, since it is unlikely, as already explained above, that im Track section remains an axle number that is equal to the error caused by the Failure of the gate is caused. With the concern of this positive potential At the left input of gate 49, all three conditions for coincidence are met, so that a positive potential also appears at the output terminal F. It can now The track section should be reported as "free". In the practical implementation of the system it will be useful to first use the positive potential at terminal F. Resetting of the tilting circuits 46 and 48 as well as the counting elements 10, 20, 30, 18, 28 and 38 by applying positive potential to the terminal R, and only to release the track when it has been checked that all these tilting circles have returned to the basic position. The facilities required for this are not shown in the figure, as they are only loosely related to the subject matter of the invention stand.

Fig. 3 shows a forward and backward running counter, which consists of three bistable Tilting circles 50, 60 and 70 are available. The counting happens atioh here according to the binary number system. The switching of the subordinate counting organ takes place when counting up, if the upstream counting element has its status from 1 in 0 changes. When counting down, the subordinate counter must be switched on when the position of the upstream counter changes from 0 to 1. the Continuation of the downstream counter is therefore dependent on two criteria. One criterion indicates which state change occurred in the upstream counter is, the other criterion indicates the direction of counting. It is convenient that Circuit which changes the state of a downstream counter, to be designed in such a way that the change of state occurs in the event of a line break or failure of a component of the downstream counting device is not already due to one of the two switching criteria alone, otherwise the starting position of the Counter reached far too early and thus the track section was reported "free" ahead of time will. Also in this case would be the fact that all counting organs in the first counting step have changed their status after the initial position, not a perfect label for the fact that the counter is in order. The demand made can thereby achieve that the circuits, which the incremental pulse to the downstream Transfer register, be designed as working circuits. It is also advisable to the balancing process in a capacitor or an inductor that occurs when tilting of the upstream counter is created as a switching criterion for the tilting process use.

In the circuit according to FIG. 3, the state change is transmitted from the upstream to the downstream counting element, the pulse transmitters 54, 56, 64 and 66 provided. The pulse transformers have toroidal cores made of a material with approximately magnetizing loop. The transformers 54 and 64 are used for switching when counting up, the transmitters 56 and 66 for advancing when counting down. A winding is provided on each transformer, which is the criterion for the change in state of the upstream tilting circle supplies. Another winding marks the counting direction. So z. B. on the transformer 54 the winding 541 to identify the change of state of the tilting circle 50, the winding 542 to identify the counting direction. The winding 543 is used to pass the pulse on to the breakover circuit 60.

If a count-in impulse is given to the counter, it occurs for a short time negative potential via the counting input EF to the monostable trigger circuit 72. This changes its state only for a certain time, which results from the dimensioning its components results. It then returns to its original state by itself. If the tilting circuit 72 is in the working position, then due to the voltage -I- U2 a current through the windings 542 and 642. These windings are dimensioned so and the voltage + U2 is chosen so that the current flowing in the windings is from the size i 1 generates a field strength that is smaller than the coercive force of the Toroidal cores. This means that there is no change in state in the toroidal cores. At the upper output of the trigger circuit 72 has a positive potential in the working position, which is fed to the tilting circuit 50 via the mixing gate 52 and this for tilting brings. As a result, an equalizing current flows through capacitor 544, winding 541, winding 561 and capacitor 564. Let this equalizing current in winding 541 be an AW number generate, which together with the AW number of the winding 542 results in a field strength, which exceeds the coercive force of the toroidal core material and thus the induction in the toroidal core changes from -I- B max to - B max. The induction change produced in the winding 543 has a voltage which is fed to the breakover circuit 60 via the mixer gate 62 and, since it is directed positively at the entrance of the tilting circle 60, this to Tilting brings. Corresponding processes then take place in the pulse transmitter 64, which also cause the tilt circle 70 to tilt. The delay time of the monostable Tilt circle 72 is dimensioned so that all tilt circles 50, 60, 70 during this Time can change its state; thereafter, the flip-flop circuit 72 returns to the initial state return. The voltage -I- U2 is now selected so that when the circle tilts back 72 reverses the direction of current in windings 542 and 642. It arises in these Windings a current of size -i2. The coercive force of the core material becomes overcome by this current, and the magnetic induction changes from -B max to + B max.This creates a negative voltage at the inputs of the mixer 62 and 71, which cannot change the state of the trigger circuits 60 and 70. This restores the original state in the pulse transmitters.

With the next count-in pulse, only the trigger circuit 50 changes its state. The equalizing current in windings 541 and 561 has the opposite direction as with the first count-in. As a result, no induction changes can be made in the toroidal core 54 due to the effects of the currents in windings 541 and 542 are oppositely directed. Neither can there be any in the winding 563 of the core 56 Voltage can be induced because the breakover circuit 74 is in the basic position. The directions of current in windings 561 and 562 counteract one another. First with the third count-in pulse, the trigger circuit 60 receives a positive pulse again, which now changes its state from 0 to 1. The third remains on the tilting circle 70 Count in without effect.

It is readily apparent that line breaks in the Circuits that are used to transmit the impulse from the upstream to the downstream Serving counting organ, thereby making themselves noticeable that a tilting of the subordinate Counter does not occur. So the first counting step is all Brings counting organs from state 1 to state 0, a flawless check the circuit possible.

After the first counting step has been carried out, all three inputs lead of the coincidence gate 76 positive potential. This also appears at the exit of the Gate 76 and blocks the upper transistor of the bistable trigger circuit 78. This changes its position and thus confirms the proper execution of the first Counting step. Corresponding processes take place when axles move out. Only by corresponding polarity of the windings 561, 562 and 661, 662 it is ensured that that the progression of the downstream counting organ occurs when the upstream changes its state from 0 to 1. If the number of axles extended is the same the number of axles retracted, the tilting circles 50, 60 and 70 have again the position shown in FIG. It is now at the three entrances on the left of Coincidence gate 80 positive potential. There too after the first axis has entered the tilt circle 78 has left its starting position, the right entrance also leads of the gate 80 positive potential, which thus also appears at the Freimeldeklemme F. The track section can now be reported as being vacant, whereby it again it will be useful to report the track section "free" only when the Tilt circle 78 reset via the reset terminal R and the proper reset has been checked.

For axle counters that are to secure a section of the route usually a counting ability of at least 250 axes is required. That’s why when counting according to the dual number system, eight dual counting organs are necessary. That means. that this Gate 76 in FIG. 3 has eight inputs, and gate 80 should have nine inputs. It it is difficult, when using electronic components, to design these gates in such a way that that see a line break or the failure of a component immediately automatically indicates. However, safety depends on the proper functioning of these gates the circuit against premature notification of the track section being vacant. It will a circuit arrangement is therefore proposed in FIG. 41 which avoids these gates, by adding an additional counting device to the counting devices required for the counting itself addition is provided. This counting organ is designated 90 and is attached to the last one Counter 70 necessary for counting connected to the same circuits, which connect the other counting organs required for counting. It is sufficient to train this additional counting element so that there are only two stable ones Can assume states, even if the counting is not according to the binary number system happens. The counter 90 also assumes state 1 in the basic position. which the other counting organs, which are only used for counting, also have. Runs the first Axis into the track section. so the counter 90 changes as well as the rest Counting organs change their state from 1 to 0. It maintains this state as long as itself Axles are in the track section; because during the counting the counting organ can now 70 only change from 0 to 1, only change from 1 to 0 during the counting. With this change but the downstream counting element 90 is not taken along. Only when the last When the extending axis brings the tilting circle 70 from 0 to 1, the tilting circle is carried along 90, which now also changes from 0 to 1. The change of the tilting circle 90 from 1 in 0 it is an indicator that when "counting the first axis, the counter has worked properly. The change from 0 to 1, on the other hand, shows that all Axes have left the track section. It is therefore to the lower output of the Kipplzreises 90 connected to the bistable tilting circuit 94, from its basic position is brought out when the tilt circle 90 flips from 1 to 0. This causes the message that the counter has worked properly on the first axis, thanks to the tilting circle 94 saved. It now indicates positive potential through its lower output the coincidence gate 96 from. If the tilt circle reaches 90 after the exit of the last one Axis back to the starting position 1, it also reaches the upper output of the Gatters 96 positive potential. The gate 96 is also positive at its output Potential and thereby reports the track section free. The security-related Perfect execution of the gate 96 is possible without any particular difficulty. It can possibly be replaced by a relay circuit, especially a special one fast working of this facility is not required.

5 shows an example of the technical realization of the logic circuit of FIG. 3. It is shown in Fig. 5, only the monostable tilt functions 72, the bistable Tilt Circuit 50, the mixing gate 52 and 6, 2 and the pulse transformers 54 and 56, as a representation of further component groups would essentially only bring an unnecessary repetition of what has already been shown. The one-sided stability of the circuit of the rüönostabilen breakover circuit is brought about by the fact that the voltage divider resistors 723, 724 and 725, 726, which define the emitter potentials of the two transistors 720 and 721, are dimensioned differently. In the conductive transistor 721, the emitter is at a more positive potential than the emitter of the blocked transistor 720 due to the voltage divider ratio. The collector potential of the transistor 721 is given via the resistor 730 to the base of the transistor 720. However, the emitter of transistor 720 has a lower potential due to the described asymmetry of the voltage dividers. so that transistor 720 is blocked. If a negative potential is now briefly applied to the count-in input EE, this reaches the base of the transistor 720 via the capacitor 731. The transistor 720 becomes conductive as a result. Current now flows through resistor 722, and the collector of transistor 720, which previously had practically ground potential, comes to a strongly positive potential. A charging current therefore flows through the capacitor 727 and the voltage component resistors 728, 729. As a result, the base voltage of the transistor 721 is briefly positive to such an extent that the transistor 721 is blocked. This state lasts as long as the charging current of the capacitor 727 does not fall below a certain value. The circuit in which this equalizing current flows is dimensioned so that during this period of time the bistable trigger circuit 50 and the trigger circuits 60 and 70 (not shown), possibly also 90, can change their state in the manner described above. Gradually, the base voltage of the transistor 721 drops again to a value which is determined by the circuit consisting of the blocking cell 732 and the resistors 728 and 729. The transistor 721 becomes conductive again, and the starting position of the breakover circuit is reached: At the collector of the transistor 721, the voltage for supplying the windings is taken, which characterize the counting direction on the pulse transformers. B. the resistor 546 brings the amperage in the winding 542 to the value required for the correct effect. At the collector of transistor 720, the pulse for switching on the trigger circuit 50 is picked up. It reaches the input of this tilting circuit via the mixing gate 52. The mixing gate 52 consists of the blocking cells 520 and 521 and the resistor 522. In the basic position of the monostable trigger circuits 72 and 74 (not shown in FIG. 5): there is resistor 522, the blocking cells 520, 521, the collector of the transistor 720 and the collector of the corresponding transistor in the breakover circuit 74 ground potential. If transistor 720 becomes conductive with a count-in pulse, the potential at its collector rises, and current flows from there via blocking cell 520 and resistor 522 to earth. The potential at the junction of the resistor 522 with the capacitors 512 and 513 rises, and the blocking cell 521 is blocked. If the transistor 500 is conductive and the transistor 501 is blocked in the bistable multivibrator 50, a more positive potential is present across the resistor 514 at the blocking cell 510 than at the blocking cell 511 via resistor 515. The positive counting pulse on the capacitors 512, 513 therefore increases the base potential of the transistor 500 so far that this transistor is blocked. A negative potential now reaches the base of the transistor 501 via the voltage divider resistors 504, 509, a process that is still supported by the capacitor 506. The transistor 501 is now conductive. The change of state in the counter 50 has occurred. Corresponding processes take place with the next counting pulse, only now transistor 501 is blocked and transistor 500 is conductive. Between the collectors of the transistors 500 and 501 and the collector resistors 502 and 503, the voltage for the inputs of the coincidence gates 76 and 80 is taken, and this voltage in the windings of the pulse transformers 54 and 56 causes the equalizing current, which causes the breakover circuit 50 in the if necessary, via the mixer 62 to the downstream tilting circuit 60. Resistors 545 and 565 ensure that this current is limited to the required value. There is no need to describe the effect of the pulse transmitter, since this has already been done when explaining the logic circuit (FIG. 3).

It is not absolutely necessary that the change of state in axle counting systems of all counting organs occurs with the first counting pulse. It is only essential that this change of state occurs at least once each time the section is traveled is. So a track section is regularly used by trains with a larger number of axles drive on, a different position of the counting devices can be assigned to the free track are referred to as those previously referred to as "basic position" is.

There is a particular advantage of counting according to the binary number system when applying the invention that in the first, following the basic position Counting step not only for the incremental switching of the counting elements in the switch-on direction necessary circuits, but also a particularly large part of the circuits is checked in the counting organs themselves.

The applicability of the invention is not only on Aohszählanlagen limited in the case of railways, but can also be used to advantage in other cases, in which a regular automatic check of counting devices is required is.

Claims (21)

PATENT CLAIMS: 1. Counter for axle counting systems with two or more staggered counting organs, of which the first changes its state with each counting pulse, while each downstream counting element only receives an impulse to change its state if the upstream counting element once step-by-step all the different states that it can occupy, has passed through, characterized in that the first counting step taking place from the basic position of the counter is assigned that change of state of each counter element (10, 20 in FIG. 2; 50, 60 in FIG. 3) which has a pulse for the downstream Counting member (20, 30 in Fig. 2; 60, 70 in Fig. 3) triggers and that a monitoring device (46 in Fig. 2; 78 in Fig. 3) is provided, the response of which depends on the state of the counting members occurs after the counting pulse following the initial position has been properly processed. 2. Counter according to claim 1, characterized in that to bring about the changes in state of the counting organs Working circuits are available. 3. Counter according to claim 1 or 2, characterized in that that in the circuits, which the change of state of the upstream counting organ Transfer to the downstream, capacitors and / or pulse transformers available are, in which the change of state of the upstream counting organ is a compensation process which causes the change in state of the downstream counter. 4. Counter according to claim 1 to 3, characterized in that the pulse transmitter contain a toroidal core with an approximately rectangular magnetization loop. 5. counter for forward and backward running according to claim 1 to 4, characterized in that the pulse transmitter (z. B. 54) contain two windings (541 and 542), in one of which (541) the compensation process when the state change of the upstream counter (50) generates a current, while the current in the other winding (542) depends on the counting direction. 6. Counter with forward and backward rotation according to claim 1 to 5, characterized by such a dimensioning of the Pulse transformers (54) existing windings (541 and 542) that the field strength in the toroidal core only then the coercive force for the transmission of the change of state required direction when current is applied to both windings. 7. counter with forward and reverse rotation according to claim 1 to 6, characterized in that that each of the two counting directions is assigned a monostable trigger circuit (72, 74) is the working position when a counting pulse arrives in the assigned counting direction occupies, remains in it until all counting organs have completed their change of state and during this time current of a certain direction is applied to the windings (542, 642) of the pulse transmitter (54, 64), which characterize the counting direction. B. Counter with forward and backward rotation according to Claims 1 to 7, characterized in that that the input of each one of the counting direction associated monostable trigger circuit den The input of the counter for the pulses in this counting direction forms and that the outputs of the monostable trigger circuits are connected to the input of the counter, which is at every count pulse changes its state. 9. Counter with forward and backward rotation according to claims 1 to 8, characterized in that one end of the counting direction characteristic windings (z. B. 542, 642) on the pulse transformers to a so selected voltage is connected, that these windings are the toroidal cores of the pulse transmitter magnetize when the monostable breakdown circuit returns to the basic position. 10. Counter according to claim 1 to 9, characterized in that the monitoring device (46, 78) is actuated via a coincidence circuit (40, 76) which controls the positions of the individual counting organs. 11. Counter according to claim 1 to 10, characterized in that that a counter (90) is provided more than the largest number of axes to be counted requires. 12. Counter according to claim 1 to 11, characterized in that the additional counting element (90) a system with two stable states, e.g. B. a bistable Tilt circle, is. 13. Counter with forward and backward rotation according to claim 1 to 12, characterized in that the additional counter (90) the track vacancy causes. 14. Counter according to claim 1 to 9 and 11 to 13, characterized in that that the additional counter (90) actuates the monitoring device (94) which indicates the correct execution of the first counting step after the initial setting. 15. Counter according to claim 1 to 14, characterized in that the track vacancy message depends on the response of the monitoring device (46, 78, 94). 16. Counter each with a group of counting organs for counting and counting according to one or more of claims 1 to 4, 11, 12, 14 and 15, characterized in that only the group of counting organs (10, 20, 30) for counting with the monitoring device (46) for the correct execution of the first counting step after the basic position is provided. 17. Counter with one group of counting devices each for counting in and out according to claim 16, characterized by a counting test device (48) which on the first counting pulse responds to the counter when driving on the track section is supplied, and on whose response the track vacancy detection is dependent. 18th Counter according to Claims 1 to 17, characterized in that the basic position the counting device is available when the track is free. 19. Counter according to claim 1 to 18, characterized by a reset device (R), which the monitoring device (46) for the first counting step and, if necessary, also the counting test device (48) as well as the counting devices in the time between the track section becoming free and its renewed occupation in the basic position. 20. Counter according to claim 1 to 19, characterized by the partial or exclusive use of Components of electronic circuit technology. 21. Counter according to claim 1 to 20, characterized in that the counting elements have systems with two stable states, for. B. stable tilting circles are: Documents considered: German Patent No. 671 425.