WO1995012512A1

WO1995012512A1 - Circuit for emitting optical signals

Info

Publication number: WO1995012512A1
Application number: PCT/CH1994/000205
Authority: WO
Inventors: Arthur Windisch
Original assignee: Siemens Integra Verkehrstechnik Ag
Priority date: 1993-11-05
Filing date: 1994-10-17
Publication date: 1995-05-11
Also published as: ATE170472T1; EP0678078B1; EP0678078A1; DE59406833D1; NO951743L; NO951743D0; DK0678078T3

Abstract

The circuit for emitting optical signals adapted to the ambient light consists of a transformer (XFMR) connected on the primary side to an a.c. input (INP) and on the secondary side via a rectifier circuit (GS) to the input of at least one lighting unit (BE1) fitted with electroluminescent diodes (LD1, ..., LDx). The circuit is compatible with circuits using incandescent lamps, but has a much lower error probability.

Description

Circuit arrangement for emitting optical signals

The present invention relates to a circuit arrangement according to the preamble of patent claim 1 or 2.

For well-known reasons, railway light signal systems require an extraordinarily high level of operational safety. The systems, which are generally exposed to high environmental pollution, should function without problems over a long period of time and report any defects that may arise to a control body immediately. From the Swiss patent specification CH 675 922 a railway light signal system is known, which is provided with two light bulbs. This circuit arrangement, which consists of only a few, non-critical components, has a simple structure and is therefore largely immune to external influences (in particular temperature fluctuations). A disadvantage of these known railway light signal systems is that the service life of the incandescent lamps used is relatively short. The maintenance required for these systems is therefore still quite high. Furthermore, the light intensity of the lamps is difficult to adapt to the lighting conditions of the plant location, since incandescent lamps have a non-linear behavior. For the sake of simplicity, the lamps are therefore always operated with one or two power levels. Furthermore, the overall function of known railway light signal systems is significantly influenced by the failure of a single lamp.

However, replacing the incandescent lamp with a light body that does not have these disadvantages leads to further disadvantages. Controls are normally required for the improved light bodies, which can have an increased probability of error due to the larger number of components and under the given environmental influences. Furthermore, these circuits are difficult to fit into the existing infrastructure. Extensive investments would therefore have to be made to modernize the traffic light systems.

The present invention is therefore based on the object of creating a circuit arrangement which has increased operational reliability compared to known systems and which is compatible with the unit to be replaced.

This object is achieved by the measures specified in the characterizing part of patent claim 1 or 2. Advantageous refinements of the invention are specified in further claims.

The circuit arrangement according to the invention allows the use of light-emitting diodes, such as those e.g. in

Klaus Beuth, Bauelemente, Vogel Verlag, Würzburg 1991, 13th edition, page 292-294. It is known from this that light-emitting diodes react almost without inertia and emit a luminous intensity that is proportional to the forward direct current. LEDs are also for different wave length ranges (including infrared) are available and have a good (but dependent on the wavelength) efficiency. It is also known that light-emitting diodes have a much longer life expectancy than incandescent lamps. The circuit arrangement according to the invention can be used instead of the circuit arrangement to be improved, without changes in the existing infrastructure or in the course of operation being necessary.

The invention is explained in more detail below with reference to a drawing, for example. It shows:

1 shows a circuit arrangement according to the invention. FIG. 2 shows a circuit arrangement according to the invention with optimized light intensity adjustment

Fig. 3 shows a circuit arrangement according to the invention with a decision logic

4 shows a circuit arrangement according to the invention realized without a transformer

1 shows a circuit arrangement according to the invention which has a transformer XFMR connected on the primary side to an AC voltage input INP and on the secondary side via a rectifier circuit GS to n lighting units BE1Bn. When it is installed, the input INP of the circuit arrangement is connected via a line to the supply circuit of a main station or a railway signal box. An AC voltage is emitted by this supply circuit, the amplitude of which is switched between two values for day and night operation. The change in amplitude is adapted to the circuit arrangements provided with incandescent lamps, as are known from the aforementioned patent specification CH 675 922.

The rectifier circuit GS shown in FIG. 1, which is known to the person skilled in the art, consists of a bridge rectifier formed from four diodes D1, D2, D3 and D4 as well as a charging and a filter capacitor C1 and C2. Of course, other constant light circuits (switching power supplies, etc.) known to the person skilled in the art can also be used instead of this circuit. To protect against overvoltages, the connections of the primary and the secondary winding of the transformer XFMR are each connected to a protective element Rs (e.g. a resistor or varistor, etc.). The connections of the primary winding of the transformer XFMR or the connections of the input INP are also connected to one another by a resistor Rg (base load resistor).

Each lighting unit BE1, .... BEn has a current source ICV connected to the rectifier circuit GS, which is connected in series with a winding of a relay RLS11, with a series resistor Rv and a group CL1 of light-emitting diodes LD1, .... LDx. To limit the current through the winding of the relay RLS11, a Zener diode (see FIG. 3, diode ZD) connected in parallel to the relay winding can also be used, by means of which the voltage across the relay RLS11 is limited. The relay RLS11 has a switch contact K11, through which a further relay RLS2 can be connected to the connections of the primary winding of the transformer XFMR. It is of course assumed that the contacts K12, .... K1n controlled by the lighting units BE2, .... BEn, which are connected in series with the contact K11, are closed. By the Relay RLS2 two different contacts K21 and K22 are actuated. A further resistor Rr (residual load resistor) can be connected to the connections of the input INP by the first contact K21. The two contacts of a line FML, which leads to a control station, for example in the main station, can be connected to one another by the second contact K22.

The circuit arrangement shown in FIG. 1 functions as follows:

An AC voltage is supplied to the input INP of the circuit arrangement by the main station, which is transformed in the transformer XFMR and output to the rectifier circuit GS. The current source ICV connected to the rectifier circuit GS leads a current through the winding of the relay RLS11 and the diodes LD1 LDx. The relays RLS11, ..., RLS1n provided on the lighting units BE11, ..., BE1n therefore close the contacts K11, ..., K1n, after which a current is passed through the winding of the relay RLS2. This causes the contact K21 to close and the contact K22 to open. A current is therefore passed through the resistor Rr via the first contact K21. In addition to the current through the primary winding of the transformer XFMR and through the resistor Rg, a current is therefore also conducted through the resistor Rr in the fault-free operating state of the circuit arrangement. By flowing the operating current composed of these three components, the main station is informed that the light body has been activated. This operating current, which is reached with the assistance of the resistors Rg and Rr, corresponds to the operating current of circuit arrangements which are equipped with incandescent lamps. The second contact K22 is opened, thereby eliminating the short circuit of the line FML. In the main station it can therefore also be determined by means of the line FML that the circuit arrangement has changed into the trouble-free operating state. If a serious problem occurs, e.g. if an interruption occurs in one of the diodes LD1 LDx, the current through the winding of the first relay RLS11 is eliminated, after which the contact K11 is opened and the second relay RLS2 is reset. As a result, the line FML is short-circuited by the contact K22, with which an error message is transmitted to the main station. The error which has occurred is also indicated to the main station by the interruption of the current caused by the contact K21 through the resistor Rg. Resistor Rg, which remains connected to the terminals of the input INP, continues to flow a permanent base current. Switching off part of the current flowing through the resistor Rg causes no or only slight transient processes. Switching off the entire current flowing through the resistors Rg and Rr, which (together with the current through the primary winding) approximately corresponds to the simulated light bulb current, could, however, lead to undesired transient processes.

The second relay RLS2 is preferably provided with positively driven contacts due to the requirements. Such safety relays are described in Hans Sauer, Relay Lexicon, Hüthig Verlag, Heidelberg 1985, 2nd edition, pages 199-201. The contacts K21 and K22 therefore exist each from two serially connected contacts, one of which can always be removed, even if the second contact is welded. In practice, it can be assumed that one and the same fault, such as contact welding or spring breakage, only occurs on one contact. Errors that occur within the safety relay are detected by an evaluation circuit (not shown in FIGS. 1 and 2), which also prevents a next switch-on process when an error is evaluated.

The circuit arrangement shown in FIG. 2 is supplemented by a module TN, which is used for day / night switching of the light intensity emitted by the diodes LD1 LDx. Furthermore, a measuring and amplifier circuit is provided which consists of a light-sensitive element PSD (photoresistor, element, diode or transistor, as described in Klaus Beuth, Bauelemente, Vogel Verlag, Würzburg 1991, 13th edition, chapter 12) and at least one amplifier OP2, the output of which is connected to a control input of the current source ICV.

The module TN consists of a differential amplifier OP1, the first input of which has a voltage divider formed by two resistors R1, R2, the second input of which has the output of a constant voltage source UC and the output of which has the control input of a switching unit SW, e.g. a switching transistor is connected, by means of which a shunt resistor Rn can be connected in parallel with the group CL1 of light-emitting diodes LD1,... LDx provided with the series resistor Rv. The voltage source UC connected to the input of the lighting unit BE1 is connected in parallel to the resistors R1 and R2 connected in series.

The TN module works as follows:

During the day, the main station delivers the maximum voltage provided to the INP input of the circuit arrangement. A sufficiently high difference in luminance between the maximum expected ambient brightness and the optical signals emitted by the diode groups CL1,... CLn is guaranteed. The voltage emitted by the main station is, however, calculated for the operation of incandescent lamps. The diode groups CL1 CLn provided in the circuit arrangement according to the invention and that from the transformer XFMR and the

Rectifier circuit GS existing power supply part must therefore be designed in such a way that at least approximately the same luminance is present as when operating with incandescent lamps. For night operation, the voltage applied by the main station to the INP input is reduced in order to adapt the luminance of the optical signals to the changed ambient conditions and to achieve a reduction in the energy output. The lowering of the voltage emitted by the main station is in turn adapted to the circuit arrangements provided with incandescent lamps, to which the circuit arrangement according to the invention should be compatible. Since the current sources ICV provided in the lighting units BE keep the current constant despite the lowering of the voltage (among other things so that the RLS11 is not reset), it is used for night operation the shunt resistor Rn is switched on, so that only a fraction of the original current is conducted through the series-connected diodes LD1, ..., LDx, which is sufficient to achieve a luminance comparable to that of incandescent lamps. When calculating the shunt resistance Rn, it must be taken into account that light-emitting diodes and incandescent lamps have different characteristics. In the case of light-emitting diodes, in contrast to incandescent lamps, the light intensity emitted changes proportionally to the current supplied.

The differential amplifier OP1 compares the (variable) voltage taken from the voltage divider with the constant voltage delivered by the voltage source UC. The voltage divider formed by the resistors R1 and R2 is designed in such a way that no voltage difference arises at the input of the differential amplifier OP1 during daytime operation. It is only by lowering the input voltage when switching to night mode that a voltage difference arises, by means of which a control signal arises at the output of the differential amplifier, which leads to the activation of the switching unit SWb. The switching unit SWb, e.g. a switching transistor, then switches the shunt resistor Rn in parallel with the diode group CL1 provided with the series resistor Rv. When switching to day mode, the switching unit SWb is reset.

Instead of the day / night switchover with switching on or off of the shunt resistor Rn shown in FIG. 2, a switch SWa connected to the current source ICV and actuated by the differential amplifier OP1 can also be provided, through which a lower constant current is applied for daytime operation ¬ can be put as for night operation.

The light-sensitive element PSD shown in FIG. 2 and the downstream amplifier OP2 are provided to better adapt the light intensity emitted by the diodes to the ambient brightness. These units supply an electrical control signal to the control input of the current source ICV, which depends on the luminance of the surroundings measured by the element PSD (preferably in the direction of view of the light signal). If the ambient brightness drops, the current carried by the diode groups CL1, .... CLn is therefore reduced. The characteristic curve of the amplifier OP2 is selected in such a way that the desired difference in luminance is always present. It is envisaged that the holding current for the relays RLS11-RLS1n is never undercut when the current is reduced.

A symbol to be signaled is formed by preferably at least two diode groups CL1, CL2. The light-emitting diodes LD of these groups CL1, CL2 are arranged in such a way that if a group CL1 or CL2 fails, which is caused, for example, by the interruption of a diode LD, the symbol still remains recognizable. For example, the symbol is displayed by both groups CL1, CL2, so that if one group CL1 or CL2 fails, there is only a drop in luminance. The light signal system therefore remains in operation until the error reported to the main station is eliminated. Although the resistors Rg and Rr (base and residual load resistance) are arranged on the primary side of the transformer XFMR in FIGS. 1 and 2, these load resistors can also be arranged on the secondary side, taking into account the transformation ratio of the transformer XFMR. Likewise, the relay RLS2 can also be provided on the secondary side of the transformer XFMR, before or after the rectifier circuit GS.

Some of the measuring and switching processes could also be controlled by a microprocessor.

In Fig. 3, the state of the lighting units BE1, ..., BEn or the state (attracted / released) of the relays RLS11, .... RLS1n is reported to a logic circuit LC, which is a function of the state of the lighting units BE1,. ... BEn the relays RLS2 and RLS3 actuated. The contacts K21 and / or K22 are actuated by the relay RLS2. Relay RLS3 actuates a contact K31, through which a resistor Ra or Rb can be short-circuited, which connects lines a and b or a and c, which are connected to a control station. The position of the contact K31 can therefore be easily determined in the main station or in the signal box. The logic circuit LC is constructed such that the relay RLS3 is actuated in the event of a number (1 to m) of error messages and the relay RLS2 is actuated in the event of a number (m + 1 to n) of error messages. The construction of such a circuit in analog or digital technology is known to the person skilled in the art. The number m is normally chosen to be significantly smaller than n (e.g.: 10 * m = n). When the number (m + 1) to n error messages occurs, several lighting units BE1,... BEn have failed, which indicates a serious defect that must be remedied as quickly as possible. If only one or two lighting units BE1 BEn have failed, the optical signals are still legible. When the relay RLS3 is actuated, an error is reported via lines a, b and c, which should be handled with less urgency. The single fault case corresponds to the failure of the main turning ice of an incandescent lamp. The multiple error case corresponds to the failure of the reserve turning ice. The logic circuit LC can of course also be connected directly to a control station.

FIG. 4 shows lighting units WBE1 WBEn which are provided with a module TN for day / night switching already described above and are supplied with alternating current. Rectifier diodes DG1, DG2 and a rectifier circuit (not shown) are provided for the power supply of the module TN. The LEDs LD1 LDx are in series with an adjustable

Resistor or a transistor TR, which is controlled by the module TN. In the circuits shown in FIGS. 1 to 3, the light-emitting diodes LD1,..., LDx can also be connected directly to AC voltage.

Claims

PATENT CLAIMS

1. Circuit arrangement for emitting optical signals, with a transformer (XFMR) which is connected on the primary side to an AC voltage input (INP) and on the secondary side via a rectifier circuit (GS) to the input of at least one lighting unit (BE1 BEn), characterized in that that the rectifier circuit (GS) is connected via the winding of a first relay (RLS11) and a series resistor (Rv) to at least one light-emitting diode (LD1, ..., LDx) that is actuated by one of the first relay (RLS11) Contact (K11) the winding of a second relay (RLS2) on the primary or secondary side can be connected to a direct or alternating voltage and that the second relay (RLS2) has a first contact (K21) and / or a second contact (K22) a residual load resistor (Rr) can be connected to both connections of the primary or secondary winding of the transformer (XFMR) or the impedance of an error signal line g (FML) is changeable.

2. Circuit arrangement for emitting optical signals, with a transformer (XFMR) which is connected on the primary side to an AC voltage input (INP) and on the secondary side via a rectifier circuit (GS) to the input of at least one lighting unit (BE1 BEn), characterized in that that the rectifier circuit (GS) is connected via the winding of a first relay (RLS11) and a series resistor (Rv) to at least one light-emitting diode (LD1, ..., LDx) that is actuated by one of the first relays (RLS11) Contact (K11) the state of the lighting unit (BE1; ...; or BEn) of a logic circuit (LC) can be displayed, which a first relay (RLS3) when the number 1 to m error messages occurs and when the number (m + 1) to n error messages, a second relay (RLS2) actuates that the contacts (K21, KLS3) operated by the relays (K21, K31) change the impedance of the power supply line or an error signal line is derbar.

3. Circuit arrangement according to claim 1 or 2, characterized in that the two connections of the primary or the secondary winding of the transformer (XFMR) additionally by one

Base load resistance (Rg) are firmly connected to each other and that the base load resistance (Rg) by means of the contact (K21) for conducting a permanent base current and the residual load resistance (Rr) which can be activated by means of the contact (K21) are provided for conducting a residual current.

4. Circuit arrangement according to claim 1, 2 or 3, characterized in that the rectifier circuit (GS) is connected via a controllable current source (ICV) to the relay (RLS11), that a light-sensitive element (PSD) is provided which measures the luminance present in the vicinity of the light signal system, and that depends on the measured luminance emits an electrical signal to the input of an amplifier (OP2), the output of which is connected to a control input of the current source (ICV).

5. Circuit arrangement according to one of claims 1 to 4, characterized in that the current emitted by the current source (ICV) can only be varied within the holding range of the relay (RLS11).

6. Circuit arrangement according to one of claims 1 to 5, characterized in that the input of the lighting unit (BE1 BEn) is connected to the first input of a differential amplifier (OP1) via a voltage divider formed by two resistors (R1, R2) ¬ sen second input is connected to a voltage source (UC) which emits a constant voltage and at whose output a signal is emitted through which a switching unit (SW) can be controlled, through which a shunt resistor (Rn) parallel to the Series resistor (Rv) and the diodes (LD1, ..., LDx) can be connected or that the output of the differential amplifier (OP1) is connected to the control input of a variable resistor (TR), which is connected in series with the diodes (LD1, ..., LDx) or a current source (ICV) is provided, the current output of which can be switched between at least two values.

7. The circuit arrangement as claimed in claim 6, characterized in that the shunt resistor (Rn), which is connected when the AC voltage applied to the input (INP) is reduced, is selected in such a way or the controllable resistance (TR) is adjustable in this way, that the occurring change in the luminance emitted by the diodes (LD1 LDx) corresponds at least approximately to that which would occur in the case of an incandescent lamp if it were subjected to the same change in the AC voltage.

8. Circuit arrangement according to one of the preceding claims, characterized in that the diodes (LD1, ..., LDx) of at least two lighting units (BE1, BE2, .... BEn) are arranged such that a symbol is shown , which is preferably still recognizable if one of the lighting units (BE1, BE2 BEn) fails.

9. Circuit arrangement according to one of the preceding claims, characterized in that the input (INP) and the error message line (FML) which may be present are connected to a supply device which is arranged in a main station or in a signal box and for the supply of signal systems provided with incandescent lamps is designed and that a higher voltage is applied to the input (INP) during the day than during the night.

10. Circuit arrangement according to one of the preceding claims, characterized in that the diodes (LD1, ..., LDx) are connected to the AC voltage supplied.