FR2500662A1 - METHOD AND ASSEMBLY FOR CONTROLLING ROAD TRAFFIC SIGNALING LIGHT SYSTEMS - Google Patents

Abstract

Typical faults occurring in semiconductor lamp switches are detected by integrating weighting of the half waves of the lamp current (red-signal sensor circuit) or respectively of the voltage across the lamp switch (green-signal sensor circuit), and, using a dynamic monitoring signal which has a polarisation which is opposite to the feed DC of the monitoring circuit and has in each case been derived from the integration results, it is reliably prevented that a nominal state of the traffic signal system can be simulated by faults in the monitoring system itself.

Description

 The invention relates to a method for controlling installations of traffic signal lights, supplied with alternating current, in which signal generators are capable of being controlled from the point of view of the appearance of states. of incompatible signals between them while at least part of the detection circuits (red light detection circuit, green light detection circuit) associated with the signal lamps interacts in such a way with logic elements that at the output of these present a dynamic control signal only if the signaling installation is in its set state, as well as to an assembly for the implementation of such a method.

 The patent granted in the Federal Republic of Germany under No. 20 42 573 made it known to apply a dynamic signal produced in a cadence generator provided for this purpose, to elements of logical combination and to link these elements of logic combination in such a way with the red light detection circuits that at the output of the logic combination devices, a dynamic signal can only appear if the signaling installation is in its set state. If inadmissible signal states appear in the signaling installation, the logic combination elements block the passage of the dynamic signal. The absence of the dynamic signal at the output of the logic combination elements is then used, for example, to activate the 'traffic signaling installation or to switch it for example on the yellow flashing light.

 The object of the present invention is to develop a method of the type mentioned at the head of this memo so as to allow, in the case of high operational safety, the control of the traffic signaling installation, without implementation. important.

 According to the invention, the solution to this problem lies first in the fact that the dynamic control signal is obtained by the logical combination of signals, dynamic and synchronous in time, available at the output of the detection circuits and which are derived, from alternating current (red light detection circuit, figure 2) or from alternating voltage (green light detection circuit, figure i) applied to the lamp switch t by the detection circuits concerned themselves.

 In this way, the dynamic signal, the evaluation of which indicates the setpoint state of the road signaling installation, is produced by the detection circuits themselves, the reciprocal synchronization of the dynamic signals supplied by the individual detection circuits , by deriving these signals from the alternating current of the lamps or from the alternating voltage acting at the level of the lamp switch, being ensured without any special measures being required.

 According to another embodiment of the method according to the invention it is provided that in the detection circuits, one proceeds directly or indirectly and according to a direction of integration changing according to the polarity of the alternating current of the lamp or of the voltage of the switch, to the integration of a current or of a voltage derived from the alternating current of the lamp (red light detection circuit) or of the alternating voltage (green light detection circuit) applied to the lamp switch the result of the integration in the direction of integration considered is differentiated, and that among the dynamic signals obtained by the differentiation are only applied to the logic elements, those which have a polarity opposite to that of a DC supply voltage for a control circuit comprising the detection circuits and which exceeds a minimum amplitude.

 Thanks to the integral evaluation thus carried out of the positive alternation as well as the negative alternation of the alternating current of the lamps by the red light detection circuit or by the alternating voltage applied to the switch of the lamps by a detection circuit of the green light, we surely recognize, in the case of the use of semiconductor lamp switches, the typical errors of these switches, errors which can for example consist in the fact that the semiconductor lamp switch only blocks during an alternation but passes, during the next alternation, inadmissibly, in its conductive state. In all cases of faulty operation of a lamp switch, the dynamic signal at the output of a detection circuit does not reach the minimum amplitude expected and cannot reach or influence the elements of logical combination. In addition, and by the polarity of the dynamic signal, which is opposite to the DC supply voltage, it is prevented that the signal can be simulated by a disturbance which appears in the control assembly. The dynamic signal therefore appears, more particularly at the output of a green light detection circuit, with its set intensity only if the full alternating voltage is applied to the green lamp switch, therefore if the green lamp is surely cut off from the circuit.

 In addition, it is provided, within the framework of the invention, that one chooses as reference potential for the DC supply voltage of the control circuit containing the detection circuits, the phase potential of the alternating voltage of the lamp supply, connected on one side to earth.

 In this way, a particularly simple constitution is obtained, in particular for a green light detection circuit, since the voltage which is applied to a switch of a green lamp can be taken galvanically, therefore directly.

 In the context of the present invention, it is further provided that an assembly for the implementation of the control method is carried out in such a way that the detection circuits comprise a Tiller integrator controlled by the alternating current of the lamps or by the alternating voltage applied to the lamp switch, that a capacitor provided for differentiation and connected to the Miller integrator is brought to the potential of the direct supply voltage via a diode of polarity passing for the voltage continuous supply of the detection circuit and that the connection points of the capacitor with the diode of two detection circuits are each connected, by means of a second diode connected in series with the preceding diode, to a point of the circuit connected to the terminal of the direct supply voltage which is of opposite polarity to that of the reference potential.

 Such an embodiment of the control assembly for respectively two detection circuits leads to a simple and safe OR combination of these two detection circuits, more particularly of a red light detection circuit with a green light detection circuit, associated with groups of signals which can assume mutually incompatible states. Thanks to such an OR combination, it is ensured that one of the signal generators must be in the "non-green" state or that the other signal generator assumes the "red" state.

It is only under these conditions that the dynamic signal is present at the output of the logic combination element.
OR.

 According to another embodiment of the assembly according to the invention, it is provided that each of said mounting points is connected, by means of a diode of polarity opposite to that of the other two diodes, to the base electrodes of two transistors whose collector-emitter circuits are connected in series, and that the series connection of the two transistors is mounted in the supply conductor of the base of an additional transistor.

 Therefore, all the outputs of the OR circuits are connected to two redundant AND circuits which, in turn, are linked in an AND combination, and which are formed by the two transistors which are connected in series. It is only when all the OR circuits emit the dynamic signal and thereby cause a logical AND signal, that the transistors of the two AND circuits are blocked at the rate of the dynamic signal. Thanks to the series mounting of the two ET circuits, the operating safety of the control assembly is significantly increased, because the absence of the dynamic signal at only one input from one of the two AND circuits is sufficient to prevent the appearance of the dynamic signal from the output of the AND circuits.

 In the context of the assembly according to the invention, it is also possible to provide that two additional transistors of opposite conductivity types are connected to their additional transistor and connected by their emitters, and that one of these transistors is carried by its collector at the potential of reference while the other is connected by its collector to the potential of the DC supply voltage source which is the opposite of the reference potential.

In addition, it can be arranged that, in pa rallie to the emitter-collector circuit of the transistor brought to the reference potential, a series circuit consisting of a capacitor and a diode of polarity parallel to the DC voltage power supply, that in parallel on the diode is provided a series connection consisting of a diode of opposite polarity and a capacitor, and that in parallel to the capacitor is provided the series connection consisting of a diode of the same polarity as the above diode and by a relay.

 In this way, a capacitor which serves as a supply voltage source for the relay is charged in such a way that the supply voltage for the relay has a polarity which is opposite to that of the DC supply voltage of the circuit. control.

 This further increases the operational safety of the control assembly against disturbances which may appear in the assembly itself, since a DC voltage of opposite polarity to the DC supply voltage can only be derived from the dynamic signal after passage correct by all the stages of the assembly which are upstream of the supply capacitor.

 In the context of the invention, it is also possible to provide an additional capacitor at the connection point between the diode and the relay and that this capacitor is capable of being connected by its electrode remote from the connection point, optionally, via an ohmic resistor, at the pole of the DC supply voltage source which is opposite to the reference potential, or directly at a point on the circuit brought to the reference potential of the source DC supply voltage.

 In this way, a simple tripping circuit is formed which is safe to operate, since the additional capacitor which can be connected as desired and which is charged correspondingly by the DC supply voltage, can keep the relay in operation. and, therefore, the signaling installation until the voltage of the supply capacitor, derived from the dynamic signal, supplies the holding current for the relay. If the dynamic signal fails, the relay drops and the signaling system is switched off.

 Finally, it can also be provided, in the context of the present invention, that in the case of at least one detection circuit (for example red light detection circuit) a capacitor, connected to the Miller integrator, is connected , via a diode of polarity opposite to the DC supply voltage, at a point on the circuit brought to the reference potential of the DC supply voltage, that in parallel with this is provided a circuit series consisting of a diode, a capacitor and a diode, the two diodes being of identical polarity and opposite to that of the diode mentioned in the first place, and that a second detection circuit (for example green light detection circuit ) is connected, via a diode of opposite polarity to the DC supply voltage, at the connection point between the diode and the capacitor of the series circuit mentioned last.

 In this way, a logical combination AND of two detection circuits, more specifically a red light detection circuit with a green light detection circuit, which can, for example, be obtained in a safe and low technical means. for example, be associated with signal lamps from the same signal generator. A dynamic signal is only emitted by these logically combined detection circuits if there is both the "red" signaling state and the "non-green" signaling state.

An exemplary embodiment of the invention will be explained below using five figures. In the form of an assembly diagram,
FIG. 1 represents a green light detection circuit,
FIG. 2 shows a red light detection circuit,
FIG. 3 shows a logical combination of a red light detection circuit and a green light detection circuit,
FIG. 4 is a logical combination of the outputs of the detection circuits, and
FIG. 5 shows an evaluation circuit provided for evaluating the dynamic signal.

 The green light detection circuit, shown in Figure 1, emits a dynamic signal at its output only if no error is present which could simulate a "green signal", therefore if the signaling state "nonvert" is unequivocally present.

 Between ground 2 and the conductor 3 which is brought to the phase voltage of the alternating voltage of the lamps, there is provided, in series, the green signaling lamp 4 and a semiconductor switch 1 which is provided for connecting and to disconnect the lamp 4. If the switch 1 is unequivocally blocked, the full amplitude of the alternating supply voltage for the lamp 4 is applied to it.

 The base electrode of a transistor 5 is connected, via a series resistor R1, to a point on the circuit or circuit which is located between the switch 1 and the lamp 4. The transistor 5 is connected by its transmitter at terminal 3 which is brought to phase voltage, and on the collector side, it is connected, via two ohmic resistors R3 and R2 connected in series, to terminal 7 of a DC voltage source whose other terminal 34 is connected to the terminal or to the conductor 3. The point 1 of the circuit, located between the two resistors R2 and R3 is connected, by means of a capacitor C1, to the base of the transistor 5. Between the point A of the assembly and terminal 3, the series circuit is also provided, consisting of a capacitor C2 and a diode 8 of polarity parallel to the direct supply voltage. The connection point between diode 8 and the capacitor C2 is designated by reference 9.

 If the negative alternation of the alternating lamp voltage is applied to terminal 3, the base of transistor 5 is at a positive potential, and since transistor 5 is a transistor of the npn type, the capacitor Cl, which forms with the transistor 5 a Miller integration circuit, is charged, during the negative alternation of the alternating lamp voltage which is applied with its full voltage to the switch 1, so that the state of charge of the capacitor C1 allows recognize, at the end of the alternation, if the switch 1 blocks in a certain way.

 The fall in potential, which can take place at point A (the charged capacitor C2 is discharged by the transistor 5 which becomes conducting), results in a negative pulse at the point 9 of the circuit (differentiation).

 The positive alternation of the alternating lamp voltage, at the switch 1, controls the transistor 5 in its blocked state. The potential at point A therefore increases during the positive alternation of the alternating lamp voltage in the direction of the potential of terminal 7 of the direct supply voltage, which is opposite to terminal 3. The increasing potential at point A again charges the capacitor C2 via the diode 8. The voltage at the diode 8 remains however limited to approximately + 0.6 V.

 The red light detection circuit, represented in FIG. 2, differs from the green light detection circuit, represented in FIG. 1, by the fact that the control quantity for the Miller integrator, constituted by the transistor 5 and the capacitor C1, is not derived from the alternating lamp voltage which is applied to switch 1, but from the lamp current.

For this purpose, an intensity transformer 10 is provided, the sheets of which have a rectangular hysteresis, so that a minimum current results in a secondary current in the drive circuit of the transistor 5. The secondary winding of the transformer of intensity is shunted by two Zener diodes II in anti-parallel circuit, so that as a result of a limitation of the resulting voltage, one obtains, during an alternation, a sufficiently long voltage pulse on the secondary side. For the rest, the red light detection circuit works just like the green light detection circuit, that is to say that at point 9 of the circuit it is possible to sample, in time synchronism with the pulses of a green light detection circuit, a dynamic control signal, if the red lam 4 is switched on and has the expected signal intensity.

 FIG. 3 shows an arrangement in which a green light detection circuit and a red light detection circuit are, on the output side, logically combined in AND, in a particular way.

 For this purpose, provision is made between point A of the mounting of a red light detection circuit and the capacitor C2, which is common to the two detection circuits, an additional capacitor C3 and a diode 12 which is mounted so as to be busy for positive impulses. On the other hand, point A of the mounting of the green light detection circuit is connected via a diode 13 to a capacitor C2, the diode 13 being polarized in the opposite direction to the direct supply voltage.

 The negative pulses, which are emitted by the capacitor C3 of the red light detection circuit, are derived from a diode 14 mounted with a corresponding polarity.

 Therefore, the device operates in such a way that the capacitor C2 is discharged only by the green light detection circuit and can only be charged by the red light detection circuit. Negative pulses can therefore appear at point 9 of the circuit only if previously the capacitor C2 has been charged by a red light detection circuit. If the positive pulses of the red light detection circuit are not present, the capacitor C2 can no longer be discharged by the green light detection circuit. In this way, the assembly according to FIG. 3 cannot give, at the level of the point 9 of the assembly, a dynamic control signal that if the red light detection circuit as well as the green light detection circuit make it possible to establish by the evaluation of integration of the alternations of the lamp current or of the alternating voltage which is applied to the lamp switch, the green lamp is dark and the red lamp lights up with the expected signal intensity.

 As a traffic signaling installation is generally made up not only of two signaling groups which are associated with intersecting traffic directions, all the signal generators of a traffic signaling installation which have the possibility of assuming signaling states which are not compatible with each other, for example red signal - for two crossed directions of the traffic type, must be checked.

 To this end, a logical sequence is provided for all the detection arrangements, which sequence is shown in FIG. 4 in the form of an arrangement diagram.

 Point 9 of the mounting of two detection circuits of non-compatible signaling groups, which are for example constituted according to FIGS. 1, 2 or 3, are for this purpose respectively connected to the two inputs of an OR circuit.

 Two such OR circuits are produced in FIG. 4, upper left part, by the two pairs of diodes 35, it being noted that each diode connects a point 9 of the circuit with a point 15 of the circuit, which represents the output of an OR circuit . At point 15 of the assembly, the positive potential of terminal 7 of the DC supply voltage is also applied.

 The diodes of the pairs of diodes 35 are therefore mounted in the passing direction, on the one hand for the negative pulses produced by the detection circuits, and on the other hand for the positive potential of terminal 7 of the DC voltage source.

 Each output 15 of an OR circuit is further connected, via a diode 18 mounted in the blocking direction for negative pulses of the detection circuits, with a point 16 of the circuit, to which the base d a transistor 17. The transistor 17 receives, in the event that no negative pulse originating from the detection circuits (point 9) is active at the points 15 of the circuit, its base emitter current of the terminals 7, via the diodes 18 which are mounted in the blocked direction for negative pulses. The transistor 17 is therefore on in the absence of pulses coming from the detection circuits, i.e. in the absence of a negative signal, and there The same is true of a transistor 19 which receives its base current from a terminal 7, via the emitter-collector circuit of the transistor 17. It should be noted here that a conductive link between the mounting point 9 and the mounting point 13, conductive link yes can be established ir in the event of a fault, cannot cause the blocking of transistors 17 to 19, which leads to a decisive increase in the operational safety of the control assembly.

 As is also apparent from FIG. 4, the outputs of the OR circuits are connected respectively by means of a diode 18 both to a first transistor 17 and to a second transistor 17, the two transistors 17 being connected in series by their emitter-collector circuits.

 Thanks to this redundant assembly, the operational safety of the control assembly is improved more.

 If at any point 15 of the circuit the dynamic control signal, consisting of negative pulses, is absent, the dynamic control signal which is present at all the other points 15 of the circuit cannot exert any action on the transistors 17 , because at least one of the transistors can receive its base current from a terminal 7, through -this of the points 15 of the assembly and of the associated diode 18, at which a dynamic control signal does not exist (logical AND combination of OR circuits).

 If the dynamic control signal is present at all the points 15 of the circuit, the transistors 17 are blocked for the duration of a pulse of this signal, since the diodes 18 are blocked by the negative pulse which is produced by the detection circuits and that therefore the base current for the transistors 17 is interrupted.

 By deriving the control signal of each detection circuit from the AC operating voltage, it is furthermore ensured that negative pulses always appear at the same time at the points 15 of the assembly, if the traffic signaling installation is present. in its set state, therefore operates correctly.

 At the output 20 of the transistor 19 therefore appears, and only in this case, between the two terminal potentials of the DC voltage source, an output signal which changes at the rate of the dynamic control signal.

 The signal at point 20 of the assembly controls two transistors 21, 22 (FIG. 5) which are of opposite conductivity types and connected by their emitters, alternately in their on state, the other transistor being blocked. Therefore, a capacitor 23 is alternately brought to the potential of the two terminals of the DC voltage source. The charging current for the capacitor 23 passes from terminal 7, through the transistor 21, through a resistor 25, through the capacitor 23 and a diode 24, to terminal 3, and the discharge current circuit passes through terminal 3 , by the transistor 22, by the resistor 25, by the capacitor 23, by another diode 26 and by an additional capacitor 27. As a result, the capacitor 27 is charged each time the capacitor 23 is discharged. The capacitor 27 cannot be discharge only by a relay 29 and a diode 28. The relay 29 thus supplied maintains in its closed state a circuit which, when open, disconnects the signal generators from the traffic signaling installation or switches it to the yellow flashing light , whereby it is ensured, in the event of a malfunction that cannot be transmitted by the traffic signaling installation, signals which are not compatible with each other.

 The relay 29 can also be inserted into other circuits via a contact 31.

Contact 31 belongs to a relay 32. When relay 32 is energized, contact 31 closes, thanks to which a capacitor 33, which is connected in series with contact 31 and relay 29, between terminal 3 and terminal 7, is loaded. The load current is dimensioned in such a way that it is not sufficient to excite the rebound 29 or to prevent the fall of this same relay. However, if the relay 32 is no longer energized, the contact 31 switches to another circuit in which only the relay 29 and the capacitor 33 are located. For an appropriate dimensioning of the capacitor 33 and for a corresponding charge of this capacitor, the discharge current from capacitor 33 energizes relay 29 and keeps it in its energized state until the traffic signaling installation commissioned by all contact 30 of relay 29 provides, when the operation is normal, the dynamic control signal via the detection circuits, thereby ensuring that the relay 29 is supplied with holding current.

 The absence of the dynamic control signal from a single detection circuit interrupts the holding current for the relay 29, so that the contact 30 reactivates the traffic signaling installation again or switches it to a static signaling state. , for example the yellow flashing light.

Claims (9)

1) Method for controlling installations of traffic signal lights supplied with alternating current, in which signal generators are capable of being controlled from the point of view of the appearance of mutually incompatible signal states while at least part of the detection circuit (red light detection circuit, green light detection circuit) associated with the signaling lamps interacts in such a way with logic circuits that at the output of these there is a dynamic signal control only if the signaling installation is in its set state, characterized in that the dynamic control signal is obtained by the logical combination of signals, dynamic and synchronous in time, available at the output of the detection circuits and which are derived from alternating current (red light detection circuit) or from alternating voltage (green light detection circuit) applied to u lamp switch, by the relevant detection circuits themselves. 2) Method according to claim 1, characterized in that in the detection circuits one proceeds directly or indirectly and according to a direction of integration changing depending on the polarity of the alternating current of the lamp or the alternating voltage of the switch to the integration of a current or a voltage derived from the alternating current of the lamp (red light detection circuit) or of the alternating voltage (green light detection circuit) applied to the lamp switch, as the result of integration in the direction of integration considered is differentiated, and that among the dynamic signals obtained by differentiation are only applied to logic circuits those which have a polarity opposite to that of a DC supply voltage for a control circuit comprising the detection circuits and which exceed a minimum amplitude. 3) Method according to claim 2, characterized in that one chooses, as reference potential for the DC supply voltage of the control circuit containing the detection circuits, the phase potential of the AC supply voltage lamps, connected on one side to earth. 4) Assembly for the implementation of the method according to one of claims 2 or 3, characterized in that the detection circuits include a Miller integrator controlled by the alternating current of the lamp or by the alternating voltage applied to the switch of a lamp, that a capacitor (C2) provided for the differentiation and connected to the Miller integrator (R1, Cl, 5) is brought to the potential of the direct supply voltage via a diode ( 8) of passing polarity for the DC supply voltage of the detection circuit and that the connection points (9) capacitor (C2) -diode (8) of two detection circuits are each connected, by means of a second diode (35) mounted in series with the preceding diode (8), at a point (15) of the circuit connected to the DC supply voltage terminal, which is opposite to the reference potential. 5) assembly according to claim 4, characterized in that each of said mounting points (15) is connected, by means of a diode (18) of opposite polarity to that of the other two diodes (8, 35), to the base electrodes of two transistors whose collector-emitter circuits are connected in series, and that the series connection of the two transistors (17) is inserted into the supply conductor of the base of an additional transistor (19). 6) An assembly according to claim 5, characterized in that the additional transistor (19, are connected two transistors (21, 22) of opposite conductivity types and connected by their emitters, and that one (22) of these transistors is carried by its collector to the reference potential while the other (21, is connected by its collector to the potential of the DC supply voltage source which is opposite to the reference potential. 7) A circuit according to claim 6, characterized in that there is provided, in parallel with the emitter-collector circuit of the transistor (22) brought to the reference potential, a series circuit consisting of a capacitor (23) and a diode ( 24) of polarity parallel to the direct supply voltage, that in parallel on the diode (24) is provided a mounting constituted by a diode (26) of opposite polarity and by a capacitor (27), and that in parallel to the capacitor (27) is provided the series connection consisting of a diode (28) of the same polarity as the above diode (26) and by a relay (29). 8) An assembly according to claim 7, characterized in that at the connection point between the diode (28) and the relay (29) is connected an additional capacitor (33) and that this capacitor (33) is capable of being connected by its electrode remote from said connection point, optionally, by means of an ohmic resistance, to the pole of the DC supply voltage source which is opposite to the reference potential, or directly to a point (34) of the circuit brought to the reference potential of the DC supply voltage source. 9) A variant of an assembly according to claim 4, characterized in that in the case of at least one detection circuit (for example red light detection circuit), a capacitor (C3), connected to the Miller integrator, is connected, via a diode (14) of opposite polarity to the DC supply voltage, at a point (3, 34) of the circuit brought to the reference potential of the DC voltage power supply, only in parallel with this diode; ; 14) there is provided a series circuit consisting of a diode (12), a capacitor (C2) and a diode (8), the two diodes (8, 12) being of identical polarities and opposite to those of said diode ( 14), and that a second detection circuit (for example green light detection circuit) is connected, via a diode (13) of opposite polarity, to the DC supply voltage, at the point of connection between the diode (12) and the capacitor of the series circuit mentioned last.