DE969630C - Contactless circuit arrangement for turn signal devices - Google Patents

Description

Contactless circuit arrangement for turn signal devices The invention relates to a contactless circuit arrangement for turn signal devices, especially in railway signaling, where the blinking causes periodic repetitive electrical impulses by means of one or more direct current premagnetized Choke coils are generated, each of which has at least two windings, of which a winding with variable reactance denotes the flashing lamp of the signaling device controls the current flowing through it.

Contactless flashing signal devices are already known in which a direct current biased choke coil controls the current through the incandescent lamps, so that there is a periodic interruption of the current. In these well-known Facilities are used capacitors with a control winding of the Choke coil form an oscillating circuit through which the flashing frequency is determined will. Usually the capacitors are connected in series with the control winding and permeable to the higher harmonics of the alternating voltage to be controlled. These harmonics can magnetize the choke coil in such a way that the oscillations can be completely prevented. For this reason one was forced to do another Connect the capacitor in parallel with the control winding to get the higher harmonics away from the coil.

The well-known one is especially for railway signals Facility also disadvantageous in that the capacitors take up a lot of space and besides are sensitive to moisture and temperature fluctuations.

It is also an arrangement for generating low-period amplitude fluctuations Known in alternating current circuits, the one switched on in the circuit ferrous Choke coil contains, except for a bias winding, which is rectified Current of the choke coil or a rectified one proportional to the choke coil current Current is fed, still carries a second winding excited by the direct current, which the first counteracts. This arrangement also contains means, which a temporal variable ratio between the current of the choke coil and the voltage or cause the counter-excitation of the choke coil, so that automatically tilting processes with occur with changing signs. The effect of this known device is based on a mutual interaction between a current-dependent resistor and the pre-magnetized choke coil, which causes a tilting process. The current-dependent Resistance can be replaced by a second pre-magnetized choke coil, and one then obtains a device in which two reactors are mutually exclusive control so that a tilting oscillation is excited. The prerequisite for this is but that the one inductor current the other inductor in counter-magnetizing Direction affects and that the second inductor current the first inductor influenced in the co-magnetizing direction. For this purpose there is also a constant Magnetization necessary. In comparison with this known device, the The arrangement according to the invention is much simpler and works in different ways.

In the arrangement according to the invention, the direct current bias is the throttle coil is directly influenced by the current conditions in two circuits, the first of which contains a resistor, causing current in that circuit and voltage are in phase, and the second includes another inductor, whereby the current in this circuit is delayed with respect to the voltage. The two A voltage controlled by the choke coil is generated after rectification fed. The use of a choke coil as a retarding element enables the production of a flashing signal device whose flashing frequency always remains unchanged is. It can therefore be placed anywhere as a control device for a railway signal are and always works reliably. By omitting large capacitors requires the device according to the invention only a little space and can in a fairly small housing can be installed.

Four exemplary embodiments of the invention are shown in the drawing. The arrangement i according to FIG. I contains two choke coils: 2 and 3 each with three windings 5, 7 and 9 or 4, 6 and B. The left end of the winding 5 is connected via two series-connected rectifiers io and ii with the same forward direction the left end of the winding 4. is connected, the connection point between the two rectifiers being connected via a line 24 to the one alternating current connection 17 of the arrangement. The right end of the windings 4 and 5 is connected to one pole of a flashing lamp 16 via a line 21. The other pole of the flashing lamp is connected via a line 22 to the other alternating current connection 18 of the arrangement. The AC terminals of a rectifier bridge 12 consisting of four rectifier elements in a Graetz circuit are connected in parallel to the flashing lamp 16 to the AC connections 17, i8, while two parallel circuits are connected to the DC terminals of this rectifier bridge. One of these circles consists of the winding 6, the right end of which is connected to the positive DC terminal of the rectifier bridge, of the winding 7, the left end of which is connected to the left end of the winding 6, and two with the mentioned windings and with each other in Series connected resistors ig and 14, the size of which can be changed by means of the sliding contacts 20 and 25, with a rectifier 15 switched on in the supply line to the sliding contact 25 of the resistor 14. The other parallel circuit consists of the right end to the positive DC terminal The choke coil winding g connected to the rectifier bridge, from the choke coil winding 8, the left end of which is connected to the left end of the winding g, and from a delay coil 13 connected between the right end of the winding 8 and the negative DC terminal of the rectifier bridge be measured there ß the total ohmic resistance of the first-mentioned circle is greater than that of the second-mentioned circle.

Once it connects the terminals 17 and 18 with an AC power source, a current flows from the terminal 1 7 via the line 2.4 and divides over the from the rectifiers io and ii and of the windings 4 and 5 existing part of the assembly 21 to the line Thereupon the current is divided into two parts, one of which flows through the flashing lamp 16 and the other through the rectifier bridge 12. These two parts then reunite in the line 22 leading to the connection 18. The mentioned current magnetizes the cores of the choke coils 2 and 3, at the same time the current coming from the rectifier bridge and flowing through the windings 6 and 7 also magnetizes the core of the choke coils in the same Senses. These two magnetizations reduce the alternating current resistance of the choke coils, so that the greater part of the voltage present at the connections 17 and 18 is effective at the flashing lamp i6. This lamp will therefore come on. The direct current flowing through the delay coil 13 and the windings 8 and g counteracts the aforementioned magnetization of the choke coils. As a result of the action of the delay coil 13, this current increases more or less slowly to a certain value, and then decreases to a lower value. Meanwhile, the alternating current resistance of the choke coils increases and as a result the current flowing through them becomes weaker, so that the direct current from the rectifier bridge also becomes weaker. As soon as the current counteracting the magnetization of the choke coils has its aforementioned second. When this value has been reached, the lamp 16 goes out. After this, the current counteracting the magnetization of the choke coils decreases a little further, the choke coils being magnetized again, and the whole process is repeated. The lamp 16 will therefore light up at the same time intervals. The relationship between the length of those periods of time in which the lamp lights up or is dark can be regulated by adjusting the sliding contacts 20 and 25.

The arrangement according to FIG. 2 only differs from that in FIG Fig. I illustrated arrangement that the AC terminals of the rectifier bridge 12 is not connected in parallel with the flashing lamp 16, but with the choke coils are. This does not change anything in the way the arrangement works.

In the arrangements according to FIGS. I and 2, the inductors each had a winding for the magnetizing direct current that does the self-magnetization the choke coils, as well as for the direct current that this self-magnetization counteracts. The arrangement according to FIG. 3 differs from these arrangements in that the two mentioned direct currents have the same winding of the choke coil flow through. Here, therefore, each inductor has only two windings 5, 7 and 4, 6.

In the arrangement according to FIG. 3, the parts 4, 5, io to 12, 16 to 18, 21, 22 and 24 are connected in the same manner as in Fig. i. The same is true also with respect to the left end of the windings 6 and 7. The right ends of the windings are connected to two diagonal points of a switching bridge 26 consisting of four branches, with the other two diagonal points the DC terminals of the rectifier bridge 12 are connected. The switching bridge 26 contains, in addition to the delay coil 13 and the adjustable resistors 14 and ig yet another delay coil 23. The positive DC terminal of the rectifier bridge 12 is at the connection point connected between the coil 23 and the resistor ig, while the negative DC terminal of the rectifier bridge with the connection point of the coil 13 and the resistor 14 is in communication. The windings 6 and 7 are with the two other diagonal points of the switching bridge connected. The arrangement works in the same way like that according to FIGS. i and 2. This is readily apparent from a Investigation of the manner in which the energy from the rectifier bridge 12 is distributed resulting direct current in the switching bridge 26. The one from the positive direct current terminal The current coming from the rectifier bridge is divided into two in the switching bridge Parts of which the one over the coil 23, over the windings 6 and 7 and over the coil 13 flows, d. H. in a circle that is just like that Coil 13 containing circuit of the arrangement according to FIG. The other substream flows through the resistor ig, the windings 6 and 7 and through the resistor 14, d. H. in a circle that is just like that of the resistors 14 and ig containing circuit of the arrangement according to FIG. The first-mentioned substream supports the self-excitation of the choke coils 2, 3 during the latter Partial flow counteracts this self-excitation.

In the arrangement according to FIG. 4, the alternating current connection 17 is over the line 24 is connected to one AC terminal of the rectifier bridge 12, whose other AC terminal to the left end of the inductor windings 4 and 5 communicates. The right end of these windings is via line 21 as well as via the flashing lamp 16 and via the line 22 to the alternating current connection 18 connected. The rectifier bridge is connected to the two DC terminals Resistance 14, the inductor winding 6 and 7 and the resistance ig containing Connected circuit to which the delay coil 13 is connected in parallel is.

The alternating current supplied to the arrangement via the connection 17 is rectified by the rectifier bridge 12, flows through the two in parallel switched circuits 13 or 14, 6, 7, ig, is then in the rectifier bridge converted back into alternating current and flows through the windings 4 as such and 5 as well as the flashing lamp 16. At the beginning of the current passage, the magnetizes through the windings 6, 7 flowing direct current to the iron core of the reactors, leading to The consequence is that the alternating current resistance of the choke coils and the lamp 16 lights up as a result. The current flowing through the coil 13 increases during this time slowly increases, then decreases again and increases again, etc. During the increase of this current, the current flowing through windings 6 and 7 decreases, whereby- the AC resistance of the choke coils is increased so that the lamp goes out. This game then repeats itself continuously, so that the lamp lights up alternately and goes out, whereby the relationship between the light and dark periods by the Sliding contacts 2o and 25 can be set.

The circuit arrangements shown in the drawing can also be modified in such a way that with the series connection each one rectifier and a resistor connected in parallel Delay coils. be used. It can also be advantageous when controlling flashing lights be to connect two such arrangements so that they are mutually exclusive control, as it was already with the previous with direct current bias Choke coils working, contactless flashing signal devices is known.

Claims (3)

PATENT CLAIMS: i. Contactless circuit arrangement for turn signal devices, especially in railway signaling, where the blinking causes periodic repetitive electrical impulses by means of one or more direct current premagnetized Choke coils are generated, each of which has at least two windings, one of which is a winding with variable reactance that flows through the flashing lamp Current controls, characterized in that the direct current bias of the Choke coil (i) directly influenced by the current conditions in two circuits the first of which contains a resistor (i9), creating this circuit Current and voltage are in phase, and the second circuit is another inductor (13), which makes the current in this circuit with respect to the voltage is delayed, and that a voltage controlled by the choke coil (i) after rectification is fed to the two circuits. 2. Circuit arrangement according to claim i, characterized in that the two circuits counteract the Influence the DC bias of the reactor (i). 3. Circuit arrangement according to claim 2, characterized in that the further choke coil (13) and a similar choke coil (23) form two opposite branches of a bridge (26) consisting of four branches, while one of the other two branches has a rectifier (15) resistor (14) connected in parallel and the second containing the preferably adjustable resistor (i9), two diagonal points of the bridge being connected to one of the windings (6,7) of the controlling choke coils (q., 5) and the other two Diagonal points are connected to the DC terminals of the rectifier bridge (i2). q .. Circuit arrangement according to claim i with a Graetzsche Gl.eichrichterbrücke which is connected in series on the AC side with the windings of the direct current biased choke coils controlling the flasher lamp current, characterized in that the further choke coil (13) is connected between the direct current terminals of the rectifier bridge (12) . 5. Circuit arrangement according to one of the preceding claims, characterized in that it is connected to a similar second arrangement and the two arrangements control each other. Documents considered: German: Patent No. 643 586; Danish patent specification No. 64,450; "F-TZ", 1937, pp. 99o to 993; "Electrical World", 1932, pp. 1098, 1099; "ASEA Journal", 1947, p. 131. Earlier rights cited: German Patent No. 9i2 o65.