DE323529C - Device to prevent the connection of excessively loaded circuits at feed points - Google Patents

Description

ISSUE JULY 29, 1920

The invention relates to a device for preventing the connection of circuits to networks, feed points or others Power sources in the event that the circuits to be connected are short-circuited or do not include any load which at the moment of switching on an excessive Could prevent stress on the network, etc. The invention is that the

ίο Connection of the relevant circuit takes place via two consecutive switches, one of which is operated by the operator can be inserted, while the second by a resistor of the appropriate size is bridged and only occurs automatically after inserting the first switch if the current in the resistor does not exceed a predetermined level, while with larger Current in the resistor connected in parallel, the second switch is not closed and possibly the first switch automatically is switched off again.

It is already known to have two in a trunk line connected to a busbar to lay one behind the other switch and parallel to one of these a resistor to arrange. However, this known arrangement only has the purpose after switching on Switch off overloads occurring in the pipeline as safely as possible. However, if there is a short circuit ο. like in the

• If the switching circuit is already present at the moment of connection, the known device fails because the oil resistance in the long-distance line is only switched on after some time, and the entire line is switched off again for a corresponding period of time if the current intensity is not correspondingly due to the switched-on resistor is depressed. Accordingly, the two relays are in the known case to switch off the associated switch in the main line, while, is the subject matter of the invention of that relay, which is to erhindern the switching on of the main switch \ ^r useful in S'tromzweige of resistance, so that on the one hand occurring overloads exactly set and on the other hand the response currents "for the two relays can also be designed differently.

The invention will be explained using an exemplary embodiment, which represents the case in which a transformer is to be connected to a busbar.

It is s a busbar, t a transformer, r a disconnector in the line from the busbar to the primary winding of the transformer; a, b are the two switches in series, g is a direct current source, d, e are the switch-on solenoids for switches α and b, c is a control lever for switching on the as. Auxiliary switch acting switches a, f and h, the opening solenoids for the auxiliary switch α and the main switch h. The switch-on magnet e for the main switch b is dependent on the auxiliary switch et such that it is only excited.

can when the auxiliary switch α is engaged; it is also dependent on an auxiliary relay i in such a way that the circuit from the direct current source g after inserting the auxiliary switch α to the closing magnet c can only come about when the auxiliary relay i is in the position shown in which it is at ι makes contact.

A resistor w is connected in parallel with the main switch b , in whose current path there is a current transformer k ; its secondary coil feeds the coil of relay i which, when sufficient current flows through resistor w, pulls core I of relay i against the force of a spring and thereby rotates the contact piece of relay i counterclockwise so that the contact is made opened at ι and the one at 2 is closed.

The switching process in the device according to the invention takes place in the following way. By moving the lever c into its "on" position, the switch- on magnet d of the auxiliary switch α is connected to the direct current source g and the switch a is brought into its closed position against the force of a spring (not shown) and locked by the bolt ζ. During the closing movement, the switch p is thrown to the contacts q and the switch-on magnet d is thereby switched off again from the direct current source. The transformer t, which belongs to the circuit to be connected, is now connected to the busbars s via the resistor 1. If the resistance w is not flowed through by the current or if this current does not have a size exceeding a predetermined amount, the coil of the relay i cannot attract the core I and the contact of the relay i remains in the position shown, in which the switch-on magnet e of the main switch b receives current from the direct current source g via the line m and the contact at 1, -which flows via the switch n, the return line 0, the now closed contacts q of the switch p and the line u back to the direct current source g . The main switch b is closed and locked by the bolt. When it closes, it switches off the switch-on magnet e by opening the switch η .

Switching off takes place in the case described, in which no dangerous load is applied to the busbars, in such a way that switch c is brought to the "off" position. As a result, the magnetic coil Λ is first placed on the direct current source, pulls its latch ν and thereby releases the main switch b , which is now opened by spring force. The core ν of the switch-off magnet h closes the switch x during its movement, whereby the switch-off magnet f of the auxiliary switch α to the. DC power source g is placed, its core ζ draws in and the locking of the auxiliary ■; switch α cancels, so that the latter is also opened by spring force.

This arrangement ensures that the deactivation takes place in the reverse order the movement of the two switches takes place as when switching on.

If a current of such strength flowed through the resistor w when the auxiliary switch α was inserted that the coil of the relay i was able to attract its core I , the contact at 1 for the switch-on magnet e of the main switch b is immediately interrupted and the contact at 2 is closed . As a result, the main switch b cannot respond and in this way remains electrically locked as long as the current in the resistor w exceeds the permissible level. In the exemplary embodiment, the contact at 2 · closes a circuit from the direct current source g via the line ni and contact 2 to the coil of the switch-off magnet h , whose core ν is attracted and brings the contact χ into its closed position. This also applies voltage to the switch-off magnet f go for the auxiliary switch a , pulls in its core ζ and releases the auxiliary switch α , which is now opened again by spring force.

As such, a display device could also be activated by the auxiliary relay i , or it could be sufficient for the safety of the system if the main switch b remains locked in the open position during the duration of the impermissible state in the circuit to be connected. That the current load through the circuit to be switched on is the cause of the stay open. of the main switch could also be recognized by a current pointer A connected in the circuit of the relay i or at another suitable point between the busbar and the transformer.

The resistor w can be designed as an ohmic, inductive or capacitive resistor.

The main switch b and the auxiliary switch α can also be combined into a single switch in the manner of a pre-contact switch. Between the pre-contact and the main contact there is then a resistor of a corresponding type and size, as is connected in parallel to the main switch b in the exemplary embodiment described. In analogous transmission, the only iao switch blade is then controlled in such a way that when the operator switches on only the

Pre-contact is closed and the further movement of the switch blade to the main contact is automatically effected as soon as the current in the resistance between the fore and Main contact does not exceed the predetermined level. However, if he exceeds this Measure, the switch can be opened again automatically or it is in the pre-contact position locked and a display device comes into action. The movement the switch can be activated by two separate solenoids, one after the other get, or by a single magnet that is used for the two positions of the Switch is excited differently and accordingly different spring forces has to overcome. In the latter case, a single spring can be provided, which experiences different expansions in the two positions of the switch blade and therefore exerts various opposing forces.

Instead of the automatic switching described, manually operated switches are provided, the movement of which according to the specification of correspondingly arranged measuring instruments 25 ments takes place.

Claims (1)

Patent claim: Device to prevent the connection of heavily loaded or short-circuited circuits to networks or feed points, characterized in that two switches in series and a resistor (w) are arranged in parallel 2u the one (main switch b) between the network and the circuit in a manner known per se that | but the latter switch (main switch V) can only be closed after closing the other switch (auxiliary switch α) if the current flowing through the resistor (w) does not have an impermissible value. 1 sheet of drawings.