NO120565B - - Google Patents

Description

Device at remote control or block systems to secure railway operations.

In the case of railways, it is known from a

station or central to control other stations. In any case, one often settles for conveying two or three commands which must be acknowledged with a corresponding feedback. Furthermore, it is known to use command current circuits and feedback current circuits,

each consisting of two wires to which two relays in series are connected at the receiving location, and of which at any time only one or the other can be affected by the occurring current with a specific current direction or type of current. So far have

the command current circuit and the associated feedback current circuit have an analog structure, i.e. a current-carrying state in the command current circuit corresponds to a corresponding state in the feedback current circuit, while in the case of a current-free command current circuit there is also a current-free state

in the feedback current circuit. The simultaneous de-energized state in both current circuits in a certain operating state has the disadvantage that wire breaks or contacts cannot be immediately ascertained. Therefore, with these facilities it is not possible to also use the de-energized state of the command current circuit for a specific command, so in the case of three commands either an additional current circuit or an additional type of current is required.

According to the invention, it is possible with a maximum of four wires and with two types of current per wire pairs as well as with two and two relays that react to the same type of current, to transmit three different commands resp. messages. This happens by the fact that the command-receiving relay that reacts to one current direction or type of current in the command current circuit, with the help of its contacts, closes the current circuit for one feedback relay, and that the command-receiving relay that reacts to the other current direction or type of current in the command the command current circuit, by means of its contacts, breaks the feedback current circuit, while the power for the other feedback relay in the de-energized state of the command current circuit is supplied via contacts which are closed in the tripped position of both relays. Thanks to the partially non-analog state of the command circuit and the feedback circuit, it is possible to fulfill the requirements for safety at railway facilities, despite the fact that in this case one also uses the de-energized state of the associated wire pair for a command and a feedback.

The invention is illustrated by way of example in the drawing.

Fig. 1 shows the circuit for communication

of commands, and

Fig. 2 the feedback circuit. Over the two lines LI and L2, when repolarizing or disconnecting a power source, three different commands can be sent to a station. Command-reception relays R 10 and R20, which are in series, are connected to these wires LI and L2 in the station. These relays can either be polarized relays or be normal relays with corresponding parallel-connected blocking cells 10 and 20. In the present case, blocking cells 11 and 21 are also connected in series with the relays for even in the event of destruction (breaking) of the parallel

blocking cell to prevent the relay from responding

the flow direction to be excluded.

At the first command, contact is

tene K 11—K 12 closed after an undisplayed command relay has reacted. The switching state that thereby appears in the command current circuit and in the feedback current circuit is shown in the figures according to

show 1 and 2. By arrows next to the relays or their contacts, it is indicated which connection state the individual relays are in. A downward-pointing arrow shows that the relay has tripped, while an upward-pointing arrow shows that the relay has energized. A current flows from the plus pole Bl on the battery across the con-

the beat Kli and a number of further dependency contacts, e.g. the contacts K2

and K3, as well as over the line LI and blocking

the cell 20 to the command-receiving relay R 10 and back over the wire L2 and con-,

the bar K 12 to the battery's minus pole B 2. Re-

relay R 10 attracts its armature, while the armature of relay R 20 remains tripped.

If there now for the second command

a closing of contacts K21 and and K 22 instead of contacts K 11 and K 12 occurs,

then a current flows in the opposite direction from positive pole B 3 across wire L2, blocking

cell 10, command-receiving relay R 20

and wire LI to minus pole B4. Appeal-

right on relay R 10 remains tripped, while relay R 20 attracts its armature.

If in the command circuit the contacts Kil and/or K 12, resp. K21 and/

or K 22 or one of the addiction contact

tene, e.g. contact K3 is open, the armatures of both relays R 10 and R20 are tripped, where-

at the third command is transmitted.

The command receiving relays R 10 and

R 20 controls, via corresponding contacts at the receiving location, further devices that are not shown here, and which, when the command is executed, closes the corresponding con-

beats, e.g. contact K4 or K5, in the feedback circuit. back flour-

The execution of the command takes place over the wires L3 and L4 by means of the feedback relays R 30 and R 40, which are also in series, and which are connected in parallel with blocking cells 30 and 40 respectively.

Is the command receive relay R 10

been magnetized at the first command,

then the feedback relay R 30 is magneti-

serted across the receiving relay's contacts Ril and R 12 and the dependency contact K4. Is the command receiving relay R 20 magne-

tized by the second command, both feedback relays are de-energized, as contact R 21 is now open. If the third command is given, the feedback relay is R 40

magnetized across the now closed contacts R 13 and R 14, R 21, K4 and K5.

Thanks to the partially non-analog states of the command and feedback circuit, greater security is achieved

accuracy of the transmission of commands,

respectively messages, as well as an automatic disturbance message in the event of wire breakage or contact, because in each operating state

if there is a current in at least one of the wiring pa-

pure L1/L2 resp. L3/L4. While both pairs of wires flow through the current in the first case, in the second

trap a current in the wire pair L1/L2 and in the third case a current in the wire pair L3/L4. If, as a result of a break in a wire, there was no current at all,

then there would be no agreement

message between the communicated command,

i.e. the corresponding positions of the controlled contacts on the command relays in the signal current circuits, and the opposite feedback, i.e. the position of the controlled contacts on the relays R 30 and R 40, and the disturbance would thus be announced. Likewise, a current that flows in one of the wire pairs, and whose polarity does not swa-

to the given command, be noted as a disturbance, as the position of the controlled command relay contacts would in any case no longer correspond to the pre-

long position of the associated feedback relay contacts. Without these not ana-

logical states of the command and feedback circuit, a break in a wire run would already lead to one of the three operating cases. The same could occur in the event of uncontrollable wire contact or the influence of extraneous currents.

The connections shown in fig. 1 and 2,

can, by using currents with different frequencies, also be operated in a similar way with series-connected frequency-dependent relays.

Claims (1)

Device for remote control or block systems to secure railway operations, where the command current circuit and the feedback current circuit each consist of two wires to which two relays in series are connected in the receiving location, and of which at any time only one or the other can be affected by the occurring current with a specific current direction or type of current, characterized in that the command receiving relay (R 10) which reacts to the one current direction or type of current in the command current circuit, by means of its contacts (Ril and R12), closes the current circuit for the one feedback relay (R 30), and that the command receiving relay (R 20) which reacts to the other current direction or type of current in the command current circuit, with the help of its contacts (R 21) breaks the feedback current circuit, while power is supplied to the second feedback relay (R 40) in the de-energized state of the command current circuit across contacts (R 13, R 14, R 21) which are closed in tripped position by both command receiving relays (R 10, R20).