EP0007023A1 - Emergency-call stations for traffic roads using light signal devices - Google Patents

Abstract

A communication cable used for emergency purposes is also used for a light signal device, whereby emergency call pillars (NRS) lying in the course of this cable are made to flash. A rectifier and charging unit is supplied remotely from central points (ZB, ZU) via feed circuits of the communication cable in each emergency call pillar. Code signals sent via the communication cable are evaluated in the emergency call pillars by means of signaling devices. During the flashing operation, this signaling device is disconnected from the rectifier and charging unit in each flashing emergency call pillar and all electrical devices of the light signaling device are disconnected from the supply circuit in each non-flashing emergency call pillar. It is thereby achieved that the transmitted energy is used exclusively during the blinking operation to supply the flash device and its signal lamps.

Description

The invention relates to a light signal device, in particular for traffic routes, in which a message cable used for emergency purposes is additionally utilized and in the course of this cable lying emergency call pillars are made to flash, in which a rectifier and charging unit are remotely fed in each emergency call pillar via feed circuits of the message cable is and in which code points are transmitted from the central offices via the communication cable to the emergency call pillars and are evaluated in each emergency call pillar by means of a signaling device.

From the literature reference ADAC-Motorwelt 11/76, pages 30 to 32, it is known to use the emergency call devices along the highway to visually warn drivers of danger spots. The visual warning should be given by the flashing of the outside lighting of the emergency call pillars. In the event of a danger, it is intended to switch the associated emergency call columns to flashing from a motorway maintenance center. To increase the intensity of the flashing signals it is proposed in DE-AS 19 33 436 to provide electron flash tubes with a charging capacitor as an energy store instead of conventional incandescent lamps.

In the known circuits, the low power which can be transmitted is not optimally used for operating the signal lamps. For example, DE-AS 19 33 436 provides signal receivers for evaluating signals in the emergency call pillars. Through this signal receiver is part of the anyway does not consume very large remote feed energy and is therefore lost for the energy supply of the flash tubes.

The object of the invention is to provide a light signal device in which, during the blinking operation, the energy transmitted via the communication cable is used exclusively to supply the flash device and its signal lamps.

The above object is achieved by the features of the characterizing part of claim 1.

By the invention it is achieved that during the flashing operation in the non-flashing emergency call columns all electrical devices of the light signal device including the food transmitter are disconnected from the remote feed circuit and in the flashing emergency call columns the signal devices are disconnected from the power supply. Magnetic losses are avoided by including the food transmitters that are not required in the partition. The separation of the signaling devices ensures that the entire transmitted remote feed energy is available exclusively to the flash device and its signal lamps. Of course, the previously used emergency call devices are not affected by the separation.

During the flashing operation, only one activation device located in each emergency call column remains connected to the remote feed circuit. This contains threshold switches, the response limit of which is above the remote supply voltage for flashing operation. The leakage current of the threshold switches is negligible compared to the useful current in the flash device.

• Fig. 1 eine übliche Kabelstrecke mit Notrufsäulen zwischen zwei Autobahnmeistereien,
• Fig. 2 den mechanischen Aufbau der Lichtsignaleinrichtung an einer Notrufsäule,
• Fig. 3 eine Schaltung zur Steuerung der Blitzfolge in einer Notrufsäule,
• Fig. 4 die Erzeugung der in einer Notrufsäule benötigten Spannungen,
• Fig. 5 eine Wechselstrom-Impulsfolge zur Aktivierung einer Notrufsäule,
• Fig. 6 ein Ausführungsbeispiel für eine Gruppe von Kodesignalen,
• Fig. 7 eine Aktivierungseinrichtung einer Notrufsäule.

Advantageous embodiments of the invention result from the following description. The drawing shows:

• 1 shows a conventional cable route with emergency call pillars between two motorway maintenance companies,
• 2 shows the mechanical structure of the light signal device on an emergency call pillar,
• 3 shows a circuit for controlling the flash sequence in an emergency call column,
• 4 the generation of the voltages required in an emergency call column,
• 5 shows an alternating current pulse sequence for activating an emergency call pillar,
• 6 shows an exemplary embodiment for a group of code signals,
• 7 shows an activation device for an emergency call column.

According to FIG. 1, emergency telephones NRS 1 to 22 are located between two autobahn departments, the manned central offices ZB, at a distance of about 2 km. These are connected to the autobahn administrators ZB by a continuous voice line (not shown). The central stations ZB supply the emergency call pillars NRS 1 to 6 and NRS 17 to 22 assigned to the motorway maintenance authorities. The emergency telephones NRS 7 to 16 are powered by an unmanned central station ZU. The supply circuits of the manned central units ZB and the unmanned central unit ZU are electrically isolated from each other. Two pairs of conductors are used to power existing devices. The external lighting of the emergency call pillars is supplied with alternating current via one pair of conductors. The other pair of conductors is used to supply an illuminated kilometer reading inside the funnel of the emergency call pillars. 1, these are shown two pairs of conductors together.

The emergency call pillars of the two directions of travel are also shown together. For example, the designation NRS 4, that at this point an emergency call column is arranged in the direction of travel A - B and in the direction of travel B - A. The emergency call pillars in both directions are connected to a common cable, a so-called bus line. This cable is only laid on one side of the highway. The emergency telephones on the opposite side are connected to this cable by spur lines.

The voltages and currents for the light signal device are transmitted via a phantom circuit. It is formed, for example, from the two pairs of conductors for supplying the outside lighting and the lighting for the mileage. The principle of phantom circuit formation by means of chokes tapped in the middle or by means of so-called phantom transformers is known.

Several, e.g. three emergency call stations switched to flashing mode simultaneously. They are grouped into a group of flashing emergency call pillars. Within such a group, the individual emergency call pillars differ by different types of flashing. The corresponding emergency call pillars are activated by code signals and the way in which they flash is defined.

The code signals are also transmitted from the central stations to the emergency call pillars via the above-mentioned phantom circuit. The code signals consist of a series of alternating current pulses with different Voltage values. The voltage values Ul, Uh, Um used (cf. FIG. 5) are generated in the central locations in a known manner by voltage shift keying. The energy of the code signals is used in the emergency call pillars to feed signal devices with which the code signals are evaluated.

The code signals are transmitted from one of the manned central stations ZB either directly to the emergency call stations or indirectly via an unmanned central station ZU. In the latter case, the code signals in the manned central station are converted into a form suitable for data transmission, transmitted on the continuous voice line to the unmanned central station, converted there into the original code signals and transmitted from there to the assigned emergency call pillars.

Four flash tubes BR1 to BR4 are provided on each emergency call pillar NRS (cf. FIG. 3). These are part of the signal lamps SL1 to SL4 (see FIG. 2). All signal lamps are attached by brackets Ha close to the head part KT of the emergency column. This avoids large leverage effects in strong winds.

Depending on the position of an emergency column within a group of, for example, three flashing emergency columns, one, two or three signal lamps light up in succession. Since several signal lamps are provided, different light sequences can be formed and thus more information can be signaled.

Fig. 3 shows an embodiment for the generation of a desired flash sequence in an emergency column.

Two pairs of conductors, stem Stl and stem St2, form the phantom circle. Via this, code signals are transmitted from one of the central stations to the emergency call pillars and there, via phantom decouplings Ph2, to a transmitter U4 with a plurality of secondary windings s, z, b. The voltage tapped at the secondary winding s is rectified in a rectifier and charging device GLE and fed to a signal device SE as code signal voltage Us and evaluated there. A power supply capacitor Cv (cf. FIG. 4) is charged in the rectifier and charging device GLE by the code signals transmitted with high energy. Its voltage is used to power various electronic circuits; this is indicated by the voltage arrow Uv. An exemplary embodiment for the rectifier and charging device GLE and details about the derivation of the voltages Ub, Uz, Us and Uv are explained with reference to FIG. 4.

With a corresponding address signal AS (cf. FIG. 6), which determines the emergency call column to be activated, a corresponding type signal TS (cf. FIG. 6) at the output of the signaling device SE provides appropriate information which specifies the type of blinking. For this purpose, the signaling device SE in FIG. 3 contains a commercially available series-parallel converter, which converts the series information arriving at the input of the pulses arriving one after the other into parallel information at the output; this is indicated by a multi-core connection line to a distributor Vt in a lightning sequence circuit Bfs. The parallel information at the output of the signal device SE controls the distributor Vt of the lightning sequence circuit Bfs in the lightning device BE in such a way that the switching points 1 '... 4' are connected to the switching points 1 ... 4 according to the type signal. The switching state that arises is saved. After the code signals KS have been transmitted, the flashing mode begins. Here, the power supply capacitor Cv is constantly recharged in order to maintain the power supply voltage Uv.

The energy required for the blinking operation is also transmitted via the phantom circuit on the stems Stl and St2. The voltage supplied is stepped up in the secondary winding b of the transformer U4, rectified in the rectifier and charging device GLE and fed as a flash voltage Ub to the flash tubes BR1 ... 4 in the flash device BE. The flash voltage Ub is smoothed by the charging capacitor Cb. The diode D prevents the energy of the charging capacitor Cb from flowing back.

The flash sequence circuit Bfs has a clock switch T, which is controlled by a counter ZG. 50 Hz half-waves serve as counting criteria, e.g. the supply voltage for the emergency pillar exterior lighting or for the lighting of the mileage. The counter ZG switches the clock switch T cyclically step by step after a predetermined number of half-waves. As a result, the ignition voltage Uz formed in the rectifier and charging device GLE via the secondary winding z is cyclically switched through to one of the switching points 1 '... 4'.

In accordance with the connections between the switching points 1 '... 4' on the one hand and 1 ... 4 on the other hand, which were previously brought about by the signaling device SE, the ignition voltage becomes Uz in sequence in the desired order on ignition transformer Ü5.1 ... Ü5.4. A glow lamp and a flash tube with auxiliary electrode are assigned to each of these ignition transmitters. For reasons of clarity, only a glow lamp G11 and a flash tube BR1 with auxiliary electrode H1 are shown. When the ignition voltage Uz is applied to the ignition transformer U5.1, the glow lamp G11 ignites and in a known manner, via the high-voltage winding of the ignition transformer U5.1 and the auxiliary electrode Hl, together with the flash voltage Ub, ignites the flash tube BR1. The other flash tubes are ignited in an analogous manner.

The ignition trigger shown in Fig. 3 represents an external triggering of the ignition, in contrast to the usual method in which the ignition timing is determined by the state of charge of an energy store (see e.g. DE-AS 19 33 436). The charging times of the charging capacitors Cb, Cz for the lightning voltage Ub and the ignition voltage Uz are dimensioned such that the charging capacitors have reached their intended charging energy by the next switching step of the clock switch T.

FIG. 4 shows an exemplary embodiment for the generation of the voltages Ub, Uz, Us and Uv shown in FIG. 3. The AC voltage U decoupled from the phantom circuit is raised in the secondary winding b of the transformer U4 directly to the value required for the flash tubes, fed to a full-wave rectifier Gb of the rectifier and charging device GLE and output as rectified, still unscreened voltage Ub. The usual voltage stabilization, which primarily serves to keep the frequency of the flashing sequence constant, is not required since the triggering of the ignition, as already mentioned, takes place independently of the charge state of the charging capacitor Cb (cf. FIG. 3).

To generate the ignition voltage Uz, the capacitor Cz is charged with the voltage taken from the transformer winding z via a diode D9.

To generate the power supply voltage Uv, a low voltage is tapped from the transformer winding s and rectified in a rectifier Gv. The power supply capacitor Cv is charged with the rectified voltage via the diode Dll and the resistor Rll.

The code signals are also output on the winding s. taken and after rectification in the rectifier Gv as code signal voltage Us of the signal device SE for evaluation. Since the code signal transmission works with two different voltage values and the power supply capacitor Cv is recharged during the code signal transmission, the voltage at Cv is stabilized by a Zener diode Zll. The diode Dll prevents the charge from Cv from reaching signal-evaluating parts of the signaling device SE. The resistor Rll serves for decoupling.

The circuits fed with the supply voltage Uv are integrated circuits, so that their power consumption is very low compared to the flash tubes.

FIG. 5 shows the example of a sequence of 50 Hz alternating current pulses transmitted via the phantom circuit in FIG their time course t to activate an emergency call pillar. The alternating current is represented by the hatching within the pulses. The alternating current is sensed in the central stations.

The pulse sequence shown covers the period from the start of the code signal transmission, starting with a charging pulse Il, followed by signal pulses Is, an activation pulse Ia for initiating the blinking operation BB to an end pulse Ie, which ends the blinking operation and the deactivated emergency call stations for the next blinking operation ready. Further details on this are explained in connection with FIG. 7.

The charging pulse I1 has a longer duration than the subsequent signal pulses Is. The charging pulse Il serves to charge the power supply capacitor Cv (cf. FIG. 4), which feeds the electronic devices of the light signal device.

The code signals KS, consisting of the signal pulses Is, are binary coded. Of the various possibilities for forming the two binary states, only the voltage criterion is used. The lower voltage Ul embodies the binary state zero. The higher voltage Uh embodies the binary state L. These voltages are present over several alternating current periods.

The individual pulses are separated from one another by pauses RZ, in which the voltage returns to zero. The three voltage values Uh or Ul are designated in FIGS. 3, 4 and 7 after their transformation and rectification with the common term code signal voltage Us.

6 shows a simplified, unipolar representation of a pulse example for a group of five code signals KS, which are assigned to an emergency column. A group of five code signals corresponds to five different flashing cards. The code signals consist of the address signal AS and the type signal TS. The address signal determines the emergency call column to be activated and is therefore different for each emergency call column. In Fig. 6, the address signal comprises 5 bits. The type signal specifies the number of signal lamps activated by the flash sequence and their switch-on sequence and thus the position of the emergency call columns within a group of flashing emergency call columns as well as the type of information. In the example, the type signal TS consists of 3 bits.

The number of 8 bits in the example shown is an arbitrary assumption. The number of bits actually required depends on the number of emergency call pillars to be activated and the number of different flashing cards. In the example shown, 2 = 32 different emergency call columns can be activated, whereby up to 2 ³ = 8 different flashing cards are possible for each emergency call column.

After the code signal transmission, the flashing mode BB takes place. The voltage used here is equal to the voltage Uh. During the flashing mode, the activated, i.e. flashing emergency telephones NRS switched off the signaling device SE and the non-activated, i.e. With the exception of a threshold switch, non-flashing emergency telephones are disconnected from the phantom circuit via which the remote supply takes place. These switching measures are carried out with the aid of an activation device AE (cf. FIG. 7).

7 shows an activation device AE of an emergency call column and the means for carrying out the switching measures mentioned above. The interaction of signal device SE, lightning sequencer Bfs and counter ZG, and the generation of voltages Ub, Uv and Us in rectifier and charging device GLE have already been explained with reference to FIGS. 3 and 4.

The AC voltage arriving via the stems Stl and St2 of the phantom circuit is decoupled via the phantom decouplings Ph2, for example chokes tapped in the middle, and fed to the transmitter U4 via break contacts b1 and b2 of a relay B in the activation device AE. The primary winding of transformer U4 is grounded to the center.

The activation device AE has threshold switches consisting of Zener diodes Z1 and Z2, whose breakdown voltage Ud lies above the voltage Uh of the charging pulse II and the blinking mode BB (cf. FIG. 5). As long as the Zener diodes Z1 and Z2 are blocked, a negligible current flows through the activation device. Instead of the Zener diodes, for example, thyristors or Schmitt triggers can also be used.

If the address signal AS is correct, the signal device SE switches the supply voltage Uv through the control line S1 (not shown in FIG. 3) and a relay contact a3 to the relay A. Its excitation circuit is closed via contact a4. Relay A responds. The short-term interruption of the excitation circuit that occurs when the relay contacts a3 and a4 flip is bridged by the capacitor Ca. The Closing contacts al and a2, which are parallel to the normally closed contacts bl and b2, prepare the activation in such a way that when the normally closed contacts bl and b2 are opened later, the transformer U4 remains connected to the phantom line. If the contacts a3 and a4 are switched, the winding of the relay A is separated from the supply capacitor Cv in the rectifier and charging device GLE. The two relays A and B are magnetic, bistable latching relays. The contacts of relay A therefore remain in their new position despite being switched off by the supply capacitor Cv until the relay is brought back to its original state by a pulse of opposite polarity. Relay A does not react to further pulses of the same polarity.

As already explained with reference to FIG. 3, the control line S2 controls the lightning sequence circuit Bfs. Their switching state, which controls the ignition sequence of the signal lamps SL, is stored by means of the supply voltage Uv. For this purpose, the voltage reference point 0 of the flash sequence circuit 8fs is connected to the supply capacitor Cv via the diode 12 and the contact b3. The diode D2 prevents the voltage zero point of the signal device SE from remaining connected to the capacitor Cv via the diode D3 when the contact b3 is switched. Conversely, the diode D3 prevents the counter ZG from being connected to the capacitor Cv during the code signal transmission via 02 and b3 and thereby unnecessarily stressing it.

The activation of the other emergency call column is prepared in the same way by triggering its relay A and the switching state that arises the flash sequence Bfs is stored. The voltage on the phantom line is then briefly increased to the value Um (see FIG. 5), which is above the breakdown voltage Ud. This voltage Um is supplied via contacts b4 and n and via diode D4 to Zener diode Zl. The resulting breakdown current generates a positive current surge of the duration of the activation pulse Ia via the diode D4 (cf. FIG. 5). This current surge first switches the relay P and, delayed by a capacitor C, the bistable magnetic latching relay B. The positive current surge also reaches the winding of the relay A via the previously switched contacts a3 and a4. This does not react to this, as it has already done so was brought out of its original position by a positive current surge and can only be switched back there by a negative current surge. Contact p4, which switches before contact b4, causes voltage Um to be present at zener diode Zl for as long as activation pulse Ia continues, even after contact b4 is switched. During the switching of the contact b4, the excitation of the relay B by the capacitor C is maintained. If the delay time of the relays P and N is sufficiently large, there is no need for charging capacitors connected in parallel, which bridge the current gaps which result from the contact b4 being flipped over and due to the one-way rectification by the diodes D4 and D5. However, if such charging capacitors are required, the various charging time constants can be coordinated with one another in such a way that relay P or N responds before relay B in this case too.

When relay B responds, the contacts open bl and b2. As a result, the transmitters U4 and thus all the electrical devices of the light signal device, with the exception of the activation device AE, are disconnected from the feeding phantom circuit in all emergency call columns which were not actuated by corresponding address signals and whose contacts a1 and a2 were not actuated. The flipping contact b3 separates the signaling device SE from all emergency call pillars, including that of the activated emergency call pillars, from the supply capacitor Cv. As a result, the remote feed energy transmitted via the phantom circuit and the transmitter U4 is only available to the flash device BE in the activated emergency call pillars. The flash sequence circuit Bfs is connected to the supply capacitor Cv either via the diode D2 or via the diode D3, regardless of the respective switching position of the contact b3. In the non-activated emergency call columns, folding b3 has no effect, since there open contacts bl and b2 separate all devices connected to transmitter U4 from the feeding phantom circuit.

The contact b3, which flips over in all emergency telephones at the same time, also closes the power supply circuit of the counter ZG. A differentiating element can be provided in the counting device, which / derives a pulse from the inrush current, which brings the counting device into its zero position in all emergency call columns at the same time. This ensures that the counting devices of the activated emergency call columns work synchronously and that the mutual allocation of the ignition times is ensured according to a planned time diagram. The counters of the non-activated emergency call columns remain on their power supply capacitors Cv during the blinking operation connected. However, this is disconnected from the remote supply because of the open contacts bl and b2 and the contacts al and a2 that remain open.

During the flashing operation BB, the voltage Uh is applied to the phantom circuit. It is less than the breakdown voltage Ud. The threshold switches Z2 of all emergency call columns remain in the locked state during the flashing mode. Their leakage current is negligible.

The blinking operation is ended by the end pulse Ie. Like the activation pulse Ia, it has the voltage Um (see FIG. 5), which is connected to the Zener diode Z2 via the contact b4, the contact p and the diode D5. This is broken. The resulting surge is negative because of diode D5. It brings the bistable magnetic relays A and B which were previously brought out of their rest position by positive current surges into their original position shown in FIG. 7. The activation device AE is thus ready for a new use after the end pulse Ie has ended. Relay N has the same function as relay P in the previous positive current surge.

Since only the difference between the excessive voltage Um and the breakdown voltage Ud is effective in the described voltage surge, despite the high absolute value of the voltage Um, no voltage-reducing measures, such as Voltage dividers, series resistors, etc., are required in the activation device AE in order to obtain the operating voltage for the relays A, B, N and P.

As a result of the different distances of the individual emergency call pillars from a feeding central point, the voltage drops on the feeding communication cable are of different sizes. In order to ensure the response currents required for relays A, B, N and P, the line resistance corresponding to a last-fed emergency call pillar is taken as a basis and the voltage selected so large that the voltage rise above the breakdown voltage Ud in the last-fed emergency call pillar results in the required minimum response currents generated. In the first-fed emergency call pillar, the resulting response currents are then greater than in the last-fed emergency call pillar, but the resulting greater load on the relays is not detrimental to them, since the voltage surge is only very short and is only so great that in of the last-fed emergency call pillar, only the minimum response currents occur. Similar considerations apply to the response currents of different sizes, which arise depending on whether there is an activated or a non-activated emergency call column, i.e. if both bistable relays A and B or only bistable relay B is excited by the voltage surge. The distance-related differences between the response currents in the individual emergency call pillars can be eliminated if necessary by adding resistances in the individual activation devices AE to the respective line resistance to the value that is effective for the last-fed emergency call pillar.

The series-parallel converter mentioned in the explanation of FIG. 3 is expediently designed so that the output information for controlling relay A and Flash sequence circuit Bfs via the control lines S1 and S2 is only present if the corresponding previous address signal. In this way, control processes are only triggered in the three emergency call pillars to be activated. The performance required for this then remains limited to these three emergency pillars. Corresponding converters are known as integrated logic circuits.

Claims (5)

1.Light signaling device, in particular for traffic routes, in which a message cable used for emergency calls is additionally used and in the course of this cable lying emergency call pillars are flashed, in which a rectifier and charging unit is remotely fed in each emergency call pillar via feed circuits of the message cable and in which code signals are transmitted from the central offices via the communication cable to the emergency call pillars and evaluated in each emergency call pillar by means of a signaling device, characterized in that in each flashing emergency call pillar of a supply circuit, the signaling device (SE) by means of a switching device (AE) from the rectifier and charging unit (GLE) is disconnected and in each non-flashing emergency call column of this supply circuit, with the exception of its switching device (AE), all electrical devices of the light signal device are separated from the supply circuit by means of this switching device (AE). 2. Light signal device according to claim 1, characterized in that the separation takes place by means of a brief voltage increase (Um) over the voltage values used for the code signal transmission (Uh or Ul). 3. Light signaling device according to one of the preceding claims, characterized in that the termination of the flashing operation (BB) and the ready switching of the emergency call pillars (NRS) for the next flashing operation by a brief voltage increase (Um) over the voltage used in the flashing operation (BB) (Uh ) respectively. 4. Light signal device according to one of the preceding claims, characterized in that the switching device (AE) contains threshold switches (Z1, Z2), which switch through the applied voltage when the voltage rises (To), and that the switching device (AE) converts the voltage rises into current surges whose polarity is opposite to the polarity of the surge of the previous voltage surge. 5. Light signaling device according to claim 4, characterized in that the switching device (AE) has bistable magnetic relays which are brought by a surge from one stable position to the other stable position and can only be brought back to the original position by a surge of opposite polarity .

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