CH631663A5 - Switching device for vehicles which have priority, with a tone-sequence switching element - Google Patents

Description

The present invention relates to a switching device for vehicles with right of way with a tone sequence switching device for switching on the tone sequence of acoustic signal devices and with at least one optical signaling means, in particular a rotating beacon, and with at least one control lamp which is supplied with current when the optical signaling means is switched on.

Right of way vehicles, e.g. Police vehicles or fire engines are usually provided with a switching device which switches the well-known high-low tone sequence of two acoustic signal devices, which is generally referred to as a tone sequence switching device. Furthermore, such priority vehicles usually have an optical signaling means, e.g. a blue or yellow colored rotating beacon, which emits an optical signal in addition to the acoustic signals and thereby recognizes the approach of the vehicle authorized to drive in. Vehicles of this type are also usually provided with a control lamp which is supplied with power when the optical signaling means is switched on, as a result of which the vehicle driver can also recognize the working of the optical signaling means inside the vehicle. In the simplest case, it is a relay which is switched into the circuit of the optical signaling means, for example a rotating beacon, which picks up when the optical signaling means is switched on and the control lamp is switched on.

If the optical signaling device fails, the relay drops out and the indicator lamp goes out.

So far, the tone sequence switching device and the optical signaling means could be switched on separately and were often switched on separately or together, in some countries in the future the switching on of the tone sequence switching device should only be possible simultaneously with the switching on of the optical signaling means.

The aim of the invention is to meet this requirement by providing a switching device which ensures that the tone sequence switching device is blocked when either the optical signaling means is not switched on,

or if it has failed, e.g. due to a defect. The invention uses the control lamp for this purpose, which is supplied with current at the same time as the optical signaling means are switched on.

The switching device according to the invention is characterized in that a series resistor is connected in series with the control lamp, which is bridged by switching means actuated when the optical signaling means is switched on, and in that a transistor with its emitter-collector path is connected on one side to a pole of the vehicle electrical system voltage and on the other side the function of the tone sequence switching device blocking switching means is connected, while its emitter-base path is connected via a resistor to the same pole of the vehicle electrical system voltage and via a second resistor to a point between the control lamp and the series resistor.

In addition to the essential advantage of the comparatively simple construction due to the use of the control lamps for blocking the tone sequence switching device, the design according to the invention can further achieve that one and the same switching device can be used both with an optical signaling means, e.g. Rotating beacon, or alternatively can be used with two optical signaling devices without fear of blocking.

Two exemplary embodiments of the invention are described below with reference to the drawing.

Fig. 1 shows the circuit diagram of the first embodiment and

Fig. 2 shows the circuit diagram of the second embodiment.

In the first exemplary embodiment according to FIG. 1, a transistor 1 is connected with its emitter to the positive pole 70 of the vehicle electrical system. The entire tone sequence switching device is normally connected to the same pole 70. The collector of transistor 1 is provided with a connection A which controls a switching means which blocks the tone sequence switching device. In the simplest case, it can be a relay which picks up when the emitter-collector path becomes conductive and thereby opens a normally closed contact which interrupts the power supply to the entire tone sequence switching device. The base of transistor 1 is also connected to positive pole 70 via a resistor 2, and the base is also connected to two diodes 5 and 8 via a resistor 3. The e.g. as all-round

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beacons trained optical signaling means Bl and B2 and the control lamps Kl and K2 are connected in the usual way on the one hand to ground and thus to the negative pole of the electrical system; on the other hand, they are supplied with power via the busbar 78 when the switch S is closed. In the circuit from the positive busbar 78 2xi the control lamps K1 and K2 there is a resistor 4 and 7 respectively. The resistor 4 is connected to the diode 5 and the resistor 7 to the diode 8. The resistor 4 can be bridged by the relay contact 6, the resistor 7 by the relay contact 9. The relay coils 6a and 9a are each in the circuit of the optical signaling means B1 and B2. In the idle state, the transistor 1 is turned on, since the base B is connected to the negative pole of the motor vehicle electrical system via the resistor 3, the diode 5 and the control lamp K1 or via the resistor 3, the diode 8 and the control lamp K2. Via the controlled transistor 1, the positive potential thus reaches point A, from where a relay, a transistor or another switching means can be supplied with current, which interrupts the power supply to the tone sequence switching device or in another suitable manner in the sense of blocking it Tone sequence switching device engages. This can e.g. B. also happen that point A is connected to point A of the embodiment of the German patent application P 26 317 588, whereby the tone sequence switching device described there is held in the locked state.

After switching on the switch S, the busbar 78 is connected to the positive pole, the rotating beacons Bl and B2 are supplied with current, as a result of which the relays 6, 6a, 9, 9a attract and the control lamps Kl and K2 are supplied with current. At the cathodes of the diodes 5 and 8 at the same time there is positive potential and they block, which has the result that positive potential reaches the base of the transistor 1 via the resistor 2, whereby it blocks. On the other hand, this disables the tone sequence switching device via point A and the switching means connected to it.

If, on the other hand, one of the optical signaling devices Bl or B2 or both is defective, the associated relay drops out and the associated control lamp goes out, since it is no longer supplied with current directly via the relay contact, but via the series resistor. However, this in turn brings negative potential to the base of the transistor 1 via the connection point between the series resistor 4 and the cathode of the diode 5 or between the series resistor 7 and the cathode of the diode 8, as a result of which the transistor 1 in turn becomes conductive and now due to the defect in the optical Signal means the tone sequence switching device blocks.

If only one optical signaling device and a control lamp are provided from the outset, the diodes 5 and 8 can be omitted, since such an OR combination is then not necessary. On the other hand, if the optical signaling means is doubled, e.g. Two rotating beacons are provided, the entire structure according to FIG. 1, namely with two control lamps, two series resistors and two relays and the two diodes, is installed. If one of the optical signaling devices is installed e.g. B2 omitted, since, for example, only a rotating beacon is required, the associated control lamp K2 is also omitted. This certainly leads to the fact that the cathode of the diode 8 is constantly connected to the positive pole via the resistor 7 during the switched-on state of the optical signaling means B1, so that the transistor 1 is then influenced exclusively in the sense of blocking the tone sequence switching device from the existing one optical signaling means Bl goes out.

FIG. 2 shows the second exemplary embodiment, in which a control using transistors is provided instead of being checked by relays. The optical signaling means B1 and B2 as well as the control lamps K1 and K2 have the same function as the parts with the same designation in the exemplary embodiment according to FIG. 1. Also positive pole 70, the switch S and the positive current bar 78 and the connection point A have the same function. The transistor 47 replaces the transistor 1 of the exemplary embodiment according to FIG. 1, the resistor 48 corresponds to the resistor 2, and the resistor 49 corresponds to the resistor 3 of the exemplary embodiment according to FIG. 1.

The blocking and turning on of the transistor 47 is effected like the turning off and turning on of the transistor 1 as a function of the control lamps K1 and K2 and the series resistors 51 and 63 in their circuit. A diode 52 and a diode 64 are connected to the series resistors 51 and 63 with their cathode, while their anodes are connected to the resistor 49. Both series resistors 51 and 63 are bridged by the emitter-collector path of a transistor 53 and 62, respectively. The base of the transistor 53 is connected to the collector of a transistor 56, which is simultaneously connected to the negative busbar 72 via a resistor 54. A resistor 55 is located in the circuit of the optical signaling device Bl. The emitter of the transistor 56 is connected to the connection point of the optical signaling device with the resistor 55. The base of transistor 56 is also continuously connected to negative busbar 72 via a further resistor 57. In the same way, the base of the transistor 62 bridging the series resistor 63 is connected to the minus busbar via a resistor 61 and also to the collector of a transistor 60, which also has its emitter connected to a resistor 59 in the circuit of the signaling means B2. The base of the transistor 60 is also connected to the negative busbar 72 via the resistor 57. Both the base of transistor 56 and the base of transistor 60 are also connected to positive busbar 78 via a diode. In the exemplary embodiment according to FIG. 2, the emitter-base path of a transistor 58, which e.g. is of the same type as transistors 56 and 60.

The mode of operation of the switching device according to FIG. 2 is the same with respect to the blocking of the tone sequence switching device as that of the exemplary embodiment according to FIG. 1. In the idle state, i.e. if switch S is not closed, negative potential passes from the ground connection of the two control lamps K1 and K2 via diodes 52 and 64 and resistor 49 to the base of transistor 47. The transistor 47 is turned on, and the potential of the positive busbar 70 reaches the point A and thus the switching means blocking the tone sequence switching device. The tone sequence switching device cannot therefore be put into operation as long as the optical signaling means B1 and B2 are not switched on. If the switch S is closed, the optical signaling means B1 and B2 are supplied with current via the resistors 55 and 59. The transistors 56 and 60 are blocked since the respective base via the diode 58 is at a higher positive potential than the associated emitter. As a result, the transistors 53 and 62 become conductive, as a result of which the resistors 51 and 63 are bridged and the control lamps K1 and K2 light up. However, this also brings positive potential to the cathodes of the diodes 52 and 64, as a result of which the transistor 47 is switched to the non-conductive state. The tone sequence

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switching device can come into operation. However, if one of the optical signaling means, e.g. B 1 defective, the associated transistor 56 becomes conductive and the subsequent transistor 53 blocks. The control lamp K goes out and negative potential reaches the cathode of the diode 52 and thus the base of the transistor 47 from the ground of this control lamp. The transistor 47 therefore becomes conductive and blocks the tone sequence switching device. Here too, if only one optical signaling device is used, the control lamp is also removed with the second optical signaling device, as a result of which no signal influencing the tone sequence switching device can be produced from there.

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Claims (5)

631663 PATENT CLAIMS 1. Switching device for vehicles with right of way with a tone sequence switching device for switching on the tone sequence of acoustic signal devices and with at least one optical signaling means (Bl, B2) and with at least one control lamp (Kl, K2), which is supplied with current when the optical signaling means is switched on, characterized that there is a series resistor (4, 7 or 51, 63) in series with the control lamp (K1, K2), which is switched on by switching means (6, B2) actuated when the optical signaling means (B1, B2) is switched on (at 78, S) 9 or 53, 62) is bridged and that a transistor (1 or 47) with its emitter-collector path (EC) on the one hand to a pole (70) of the vehicle electrical system voltage and on the other hand (at A) to a switching means blocking the function of the tone sequence switching device is connected, while its emitter base section (EB) via a resistor (2 or 48) to the same pole (70) of the vehicle electrical system voltage and via a second resistor (3 or 49) to a point z wipe control lamp (Kl, K2) and series resistor (4.7 or 51, 63) is connected. 2. Switching device according to claim 1, characterized in that two optical signal means (B1, B2) are provided and that between the second resistor (3 or 49) and the series resistors (4, 7 or 51, 63) of the control lamps (Kl , K2) a diode (5, 8 or 52,64) are arranged. 3. Switching device according to claim 1, characterized in that the coil (6a, 9a) of a relay is located in series with the optical signaling means (B1, B2), the contact (6,9) of which, when the relay is excited, the series resistor (4, 7) the control lamp (Kl, K2) bridges. 4. Switching device according to claim 1, characterized in that in series with the optical signal means (B1, B2) is a third resistor (55, 59), the voltage drop of which is used to control a second transistor (53, 62), the emitter-collector path the series resistor (51, 63) of the control lamp (Kl, K2) is connected in parallel. 5. Switching device according to claim 4, characterized in that a diode (58) is connected in the forward direction between the positive terminal (78) of the optical signaling means (B1, B2) and the base of a third transistor (56, 60) which is the second Drives transistor (53,62), and that the emitter of the third transistor (56,60) is connected between the optical signal means (B1, B2) and the third resistor (55, 59).