DE519742C - Protection device for relay - Google Patents

Description

The current and bushing transformers connected relays should as a rule at a maximum or differential current switch off. So you are only briefly loaded with the highest current. Should However, such relays work on signaling, so they can under certain circumstances be permanent are traversed by a current that is far above the permissible limit.

It is known that one avoids the overloading of such relays by that one saturates the transformer core so that with a higher current, almost the entire primary ampere

'Windings are used for iron saturation so that the secondary current does not exceed the permissible limit. At this However, the relay is often set up because of the impermissible voltage stress, in particular through tensions of threefold fre-

ao sequence that occur as a result of iron saturation.

A converter that has a special tertiary winding T as shown in Fig. 1 to which a capacitance C is connected, which supplies the magnetizing current of the converter, works much better. The capacitance is adjusted so that it just supplies the magnetizing current of the converter and relay in the vicinity of the response current strength of the relay R.

At. A higher current intensity then leads to a significant detuning which, in addition to the high iron saturation, causes a reduction in the secondary current. So you can use a very sensitive relay for such systems, which in itself does not tolerate a large overload, without having to fear that it will perish in the event of long-term overloading of the protection system due to voltage peaks or current overload. Despite the fact that the iron saturation limits the secondary current, the primary amperage of the relay can be set differently in a certain initial range of the primary ampere turns by connecting an ohmic regulating resistor W upstream. In Fig. 2, the secondary current intensity J _{2 is} entered as a function of the primary ampere turns AW for such protection. The curve shapes allow the invention to be further exploited. You can, for example, set the relay so that the relay armature at a maximum, z. B. Point a, the curve for 20 ^ F is tightened, but drops again between points α and b. It is thus achieved that the relay responds at a certain current strength and then drops again when the current strength is exceeded. If the current increases further, the relay responds again. Such arrangements can ßo for the different

* ' The patent seeker stated as the inventor:

Dr. Walter Bütoiv in Frankfurt a. M.

The most diverse purposes, for example for signaling certain currents, are used will.

The peculiarity of the curve shape, which is shown in Fig. 2 for 20 μ F by changing the capacitance, can also be achieved with the capacitance remaining the same, e.g. B. 6 μ, Τ, can be achieved by changing the secondary number of turns. For example, Fig. 3 shows how the curve shape changes with the same capacitance and different numbers of turns. The curves for 15 or 23 turns can be used for the relay setting mentioned above.

To protect the capacitor and for the purpose of further reducing the load on the relay, it is advisable to place glow lamps Q1 in parallel with the capacitor in each case.

Claims (3)

Patent claims: i. Protection device for relays connected to current transformers of such iron saturation are connected that the majority of the ampere-turns required to respond to the relay are beyond further primary amp turns to magnetize the converter core serves, characterized in that for better limitation of the secondary current strength at the same time increasing the sensitivity to a special tertiary development connected to the current transformer a capacitor of such capacity is that on the one hand near the response primary amp turns of protecting the magnetizing current of the converter from the capacitor is supplied, on the other hand, a significant detuning occurs at higher currents. 2. Protection device according to claim 1, characterized in that the capacitor capacitance is chosen so that the secondary current strength with a slow increase of the primary amp turns rises sharply and then falls to to slowly increase again after the drop, so that the relay set to a maximum of the curve with further increase the primary current drops again shortly after the response. 3. Protection device according to claim i, characterized in that when firmly selected Capacitance, the secondary number of turns is chosen so that the secondary current strength initially rises sharply when the primary ampere turns increase, then falls again by to rise again, and that the relay connected to the secondary winding either is set so that it responds shortly before the maximum of the curve, with a further increase in the primary current strength falls again, to then with steady Raise the ampere-turns again to address, or that the setting of the relay is made so that the current in the relay is not increases significantly when the primary current is significantly higher than the response current is increased. 1 sheet of drawings Berlin. GbbRÜcKT in the