DE3901802C1 - Arrangement for monitoring the red light in traffic signals - Google Patents

Abstract

The invention relates to an arrangement for monitoring the red light in traffic signals, in which the lamp current is measured by means of a primary winding, connected in series with the red signal lamp and a lamp switch, of a current transformer, and in which the secondary winding of the current transformer controls via a rectifier bridge a threshold value switch whose dynamic output signal is used to derive fault signals. The arrangement requires no separate signal clock and permits the lamp current to fall briefly below the minimum when it is provided that the output of the threshold value switch, when overshooting the minimum lamp current, emits a dynamic output signal consisting of pulses, which signal can be routed to the input of a monostable multivibrator (flipflop), that the "on"-time of the monostable multivibrator is set to the duration of a few half cycles of the AC mains voltage and therefore extends over a plurality of pulses of the dynamic output signal of the threshold value switch, and that, when the monostable multivibrator is not triggered and when a red light command is imminent, an individual static fault signal can be derived via a logic AND circuit and a general fault signal can be derived via a logic OR circuit connected downstream of the logic AND circuits of a plurality of red-light monitorings.

Description

The invention relates to an arrangement for monitoring red lamps in traffic signal systems in which the lamp current is with the red signal lamp and a lamp switch in series switched primary winding of a current transformer is detected and in which the secondary winding of the current transformer via a Rectifier bridge controls a threshold switch, the dynamic output signal to derive error signals is used.

An arrangement of this type is known from DE-AS 27 33 798. The blocking signal comes in traffic light signal systems crucial role in. This already results from the choice of the color red, the least as long-wave light is steamed. The blocking signal must neither fail nor in its light intensity falls below the perceptual limit - which is tantamount to failure - if it is not too dangerous Traffic situations should come. Therefore, in the known Arrangement of the lamp current of the red signal lamps detected and on a minimum lamp current is monitored. In the known arrangement four states are monitored:

• 1. Red lamp should burn, and it burns too,
• 2. Red lamp is not supposed to burn, nor is it lit,
• 3. Red lamp should burn, but does not burn,
• 4. Red lamp should not burn, but burns.

States 1 and 2 are good and states 3 and 4. marked as faulty. To make this distinction  To be able to make, the known arrangement requires one separate dynamic signal clock, that of the red lamp monitoring is fed.

It is an object of the invention, the arrangement for Red lamp monitoring in light signal systems at the beginning mentioned kind so that no separate dynamic Signal clock is required and that temporary Falling below the minimum lamp current of a red signal lamp do not yet trigger any error signals.

This object is achieved according to the invention in that the output of the threshold switch when the Minimum lamp current is a dynamic consisting of pulses Output signal that the input of a monostable Toggle switch can be fed that the service life of the monostable Toggle switch for the duration of a few half-waves of Mains AC voltage is set and therefore over several Pulses of the dynamic output signal of the threshold switch extends and that in the absence of control of the monostable Toggle switch and if there is a red command via an AND Circuit an individual static error signal and over one of the AND circuits of several red monitors downstream OR circuit a general error signal are derivable.

Due to the service life of the monostable multivibrator specify a protection period in which the minimum lamp current can be fallen below without triggering an error signal. In addition, not only can one with the arrangement lamp-specific error signal, but also a general one Error signal can be derived. The latter can e.g. B. acoustically are emitted during the lamp-specific error signal can be visually displayed.  

Is provided according to an embodiment that the exit of the Rectifier bridge a Zener diode is connected in parallel and optionally one of several adjustable voltage dividers is switchable, at which the control voltage for the Threshold switch is adjustable and tapped, then lets red monitoring for different lamp powers, d. H. Lamp currents, adjust.

A further configuration provides for increasing the redundancy proposed that a threshold switch with two outputs be used is that each output of the threshold circuit is a monostable Toggle switch controls and that each monostable toggle switch an AND circuit is assigned, which once by the Red command and the other from the assigned monostable Toggle switch can be controlled.

The red command is always given when one Red signal lamp of a red lamp monitoring is controlled. By using another monostable multivibrator you get two display circuits per red lamp monitor, which increases the display security accordingly. Here is an individual error signal in each display circuit derivable and for deriving a common error signal the two display circuits via the OR circuit summarized.

Individual optical error displays are obtained after a Design in that the outputs of the AND circuits individual fault circuits with operational amplifiers Control LEDs and that the outputs of the Operational amplifier additionally via diodes of an OR circuit on a single line to deliver a joint Lead error signal.  

It is also envisaged that the red command, which when driving every red signal lamp to be monitored is on, everyone AND circuits of all red lamp monitors can be fed and that the outputs of all operational amplifiers of all Red lamp monitoring via diodes of a common OR Single line circuit to deliver a common Error signal are connected, then for several Red lamp monitors the same common error signal used.

The invention is based on a block diagram illustrated embodiment explained in more detail.

Each red signal lamp to be monitoredSLR is in the Series connection with the associated lamp switchLS and the primary winding of a current transformerSW involved. Becomes the lamp switchLS closed, then a lamp current flows via the current transformerSW, so that in the secondary winding Voltage is induced across the rectifier bridge G rectified but not smoothed. With the closing the lamp switchLS is also the red command on the line RL given, which is fed to all red lamp monitors. The rectifier bridgeG is the zener diodeZD downstream, so that there is a constant output voltage. The zener diode ZD is optionally one of two adjustable voltage dividers can be connected in parallel, like the solid and dashed lines Indicate switching bridge. This voltage divider from the ResistancesR 1 toR 8th can the different services from Z. B. 40 W and 67 W of the red signal lamp and with the adjustable resistorsR 3rd andR 7 so set be that at the resistanceR 8th tapped dynamic signal is the same size. The threshold switchSWSby this dynamic signal is therefore not needed to be changed to a different threshold. As long as the  Minimum lamp current through the primary winding of the current transformer SW flows, gives the threshold switchingSWS to the rhythm of 100 Hz at the outputsa 1 anda 2nd synchronous impulses via the voltage dividerR 9,R 10th andR 11,R 12th on the entrances e of monostable multivibratorsMF 1 andMF 2nd reach. How the timersZ of these monostable multivibratorsMF 1  andMF 2nd suggest that a service life can be specified for this, in which no input pulse has to occur in order to achieve the monostable Toggle switchMF 1 respectively.MF 2nd to keep in the triggered state. If the service life is designed for 100 ms, then the The minimum lamp current has fallen below for a period of 5 periods be without the monostable multivibratorsMF 1 and MF 2nd return to the non-triggered starting position. Are the monostable multivibratorsMF 1 andMF 2nd  in the starting position, then the output signals are   at the one inputs of the AND circuitsU 1 andU 2nd, while on the other inputs via the decoupling resistors R 13 andR 14 the red commandPL pending. The AND circuits U 1 andU 2nd give output signals, which over the Operational amplifierOV 1 andOV 2nd the display circuits with the series connections from resistanceR 15 respectively.R 16 and light emitting diodeLD 3rd respectively.LD 4th control and thus individual emit optical error signals. These error signals occur So only if the red command is standingRL the The minimum lamp current has fallen below for at least 100 ms. The light emitting diodesLD 3rd andLD 4th give the monitored Red signal lampSLR assigned error signals. The doubling of the monitoring circuit after the threshold switch SWS brings an increase in redundancy. Only if at standing red commandRL the monitored red signal lampSLR Not leads the minimum lamp current, an error signal is triggered.

The outputs of the operational amplifiers OV 1 and OV 2 can be combined via the diodes D 1 and D 2 of an OR circuit on a line for emitting a common error signal.

As the dash-dotted lines indicate, the red command RL is simultaneously supplied to all red lamp monitors and the diodes of the OR circuit connected downstream of the operational amplifiers of other red lamp monitors also lead to the line for deriving a common error signal FS .

Claims (5)

1. Arrangement for monitoring red lamps in traffic signal systems, in which the lamp current is detected by means of a primary winding of a current transformer connected in series with the red signal lamp and a lamp switch, and in which the secondary winding of the current transformer controls a threshold switch via a rectifier bridge, the dynamic output signal of which is used to derive error signals is characterized by
that when the minimum lamp current is exceeded, the output (a 1 , a 2 ) of the threshold switch ( SWS) emits a dynamic output signal consisting of pulses, which can be fed to the input (e) of a monostable multivibrator (MF 1 ),
that the service life of the monostable multivibrator (MF 1 ) is set to the duration of a few half-waves of the mains AC voltage and therefore extends over several pulses of the dynamic output signal of the threshold switch (SWS) and
that if there is no control of the monostable multivibrator (MF 1 ) and if there is a red command (RL), an individual static error signal (e.g. light-emitting diode D 3 ) via an AND circuit (U 1 ) and one of several red monitors connected to the AND circuits OR circuit (diodes D 1 ) a general error signal (FS) can be derived. 2. Arrangement according to claim 1, characterized in that the output of the rectifier bridge (G) is a Zener diode (ZD) connected in parallel and optionally one of several adjustable voltage dividers (R 1 , R 2 , R 3 , R 4 , R 8 or R 5 , R 6 , R 7 , R 4 , R 8 ) can be switched on, at which the control voltage for the threshold switch (SWS) can be set and tapped. 3. Arrangement according to claim 1 or 2, characterized in that
that a threshold switch (SWS) with two outputs (a 1 , a 2 ) is used,
that each output (a 1 , a 2 ) of the threshold circuit (SWS) controls a monostable multivibrator (MF 1 , MF 2 ) and
that each monostable multivibrator (MF 1 , MF 2 ) is assigned an AND circuit (U 1 , U 2 ) which can be controlled by the red command (RL) and by the associated monostable multivibrator (MF 1 , MF 2 ) . 4. Arrangement according to one of claims 1 to 3, characterized in
that the outputs of the AND circuits (U 1 , U 2 ) via operational amplifiers (OV 1 , OV 2 ) control individual fault circuits with light-emitting diodes (D 3 , D 4 ) and
that the outputs of the operational amplifiers (OV 1 , OV 2 ) additionally lead via diodes (D 1 , D 2 ) of an OR circuit on a single line to emit a common error signal (FS) . 5. Arrangement according to one of claims 1 to 4, characterized in
that the red command (RL) , which is pending when each red signal lamp (SLR) to be monitored is triggered, can be supplied to all AND circuits (U 1 , U 2 ) of all red lamp monitors and
that the outputs of all operational amplifiers (OV 1 , OV 2 ) of all red lamp monitors are connected via diodes of a common OR circuit to the single line for emitting a common error signal (FS) .