DE1816592A1 - Selective device for protection devices against earth currents - Google Patents

Description

Selective device for protective devices against earth currents The invention relates to a device for selecting protective devices against earth currents, and Although for such protective devices, namely contactors, fuses or the like. That one Acceptance device, an office energy storage device with one of the acceptance device fed rectifier and a capacitor fed by the rectifier as well one threshold switch fed by the capacitor and one from the switch fed execution device, namely a relay, a trigger or switch or the like.

According to the currently known state of the art, certain disturbances disengage several of the protective devices connected in series, which is responsible for the 3rd drive of the Network obviously has a serious and sometimes unacceptable disadvantage means.

Accordingly, the invention aims to eliminate this Disadvantage due to a selectivating device, which, if malfunctions occur on the Devices guarantees the desired staggering of their functions and thereby eliminating the snapshot shutdowns caused by the simultaneity The following is the state of the known Technology and its disadvantages described, A protective device against earth currents consists according to the basic circuit diagram of FIG. 1 from the combination of a removal device, which is generally formed by a differential transformer T, with a Energy storage device comprising a rectifier R (e.g., as shown in Bridge circuit) and a capacitor C with a response threshold sensor I, z, B, according to French patent specification 1 202 203 and French patent specification 1 509 070, and with an execution device D, z, B, the coil of a relay, a release or disconnector, etc. With such a protection device, changes the functional time t opposite to the fault current strength Id, like curve C of FIG. 2 shows: as the fault current Id increases, the functional time t initially shortens pretty fast and then slower and slower and sinking for all over a certain Value I1 lying currents not below a certain minimum t1.

An electrical distribution network typically uses a number such protective devices that are switched in groups in successive stages In the single-core circuit diagram of FIG. 3 one finds, for example, protective devices Al, each of which is immediately upstream of one or more consumers arranged and all for the same Protection level, i.e. for the same values of the residual current strength Id are provided. For each group of Protection devices Al is one protection device upstream of the respective group A2, which are all designed for the same level of protection, but higher lies as Id, after all, there is one protection device for each group of protection devices A2 A3 provided. So if a fault Z occurs in a consumer, it should actually only the associated protective device Al come into operation, but in fact certain Malfunctions also the associated device A2 comes into operation with shutdown of the local network, and sometimes even device A3, which switches off the entire network.

This deficiency is explained below with reference to FIG. 4 explains in which the curve Cl of the devices Al and the curve O2 of the devices A2 are shown.

In practice, the devices are designed to protect people against Effect of direct contact with a live conductor intended, from physiological Reasons and in accordance with those applicable to safety in the event of direct contact Norms and regulations remain the curve of these devices on the right this side of the point P1 (1000ms and 30 mA) and on the left this side of the point Ql (30 ms and 300mA), or at most it reaches these points. Otherwise, in practice it has use confirms the level of 300 mA for another level of protection, the indirect contact and fire hazards.

The curve C2 of the devices A2 goes through the point P2 (1000 ms and 300 with), the devices 111 and A2 only differ from one another in terms of technology their dimensioning, that is, by their pick-up devices: the curve C2 leads differs from the curve Ct by multiplying its ordinates by 10 t so If curve C2 passes through point Q2 (30 ms and 3000 mA), it should be noted that the ZindeStzeit t1 for both curves C1 and C2 is the same (30 ms), for each The value of the fault current Id above 3000 mA is the same for the devices A1 and A2 Response time and separate both without any selectivity, physically speaking your energy storage devices will be powered by this strong fault current with a loaded at such a speed that the difference in their response times is negligible is.

In the case of even stronger fault currents, here for example at 30 A, the three solve devices Al, A2 and A3 located upstream of the fault Z simultaneously and switch off the entire network instead of just switching off the only defective consumer.

The aim of the invention is to eliminate these serious drawbacks.

Accordingly, the object of the invention is to provide a device to create, attached to a protective device described above, its response time extended to fault currents that are relatively high for the dimensioning of the device, This device should be simple and therefore economical and, moreover, immediately be attachable and interchangeable, the invention makes this in principle achieved that the selective device is constructed as a quadrupole, which between the rectifier R and the capacitor C of the energy storage device switched on and in the event of a relatively strong fault current, the charging current of this capacitor C reduced, the invention is characterized in that the Selekttviervorrichtung has a quadrupole and that one input is fed by the rectifier its this Input assigned output the capacitor feeds and its other input and output with each other and with the return lines of the rectifier, the capacitor and the execution device are connected and that there is also a resistor between the input fed by the rectifier and the output feeding the capacitor is switched on and a component with Response threshold between the capacitor. feeding output and each other connected inputs and outputs is switched on, whereby the response threshold of the Component is selected higher than the response threshold of the switch. It is about So both invention around a quadrupole with at least one (ohmic) resistor in a length branch and a component with a response threshold in a cross branch, wherein this quadrupole is fed on the input side by the rectifier and on the output side by the Capacitor is connected in parallel, according to one embodiment of the invention the selection device with one between the resistor and the component Response threshold common point on the one hand and the terminal on the other hand switched on Resistance on. It is aleo in the length branch of the quadrupole next to the one already mentioned (ohmic) resistance another (ohmic) resistance, and the component with response threshold is connected to the connection point of the two resistors as a shunt branch.

In a further embodiment of the invention, the selection device a capacitor connected between the inputs of the quadrupole. It can Furthermore, an (ohmic) resistor is switched on between the inputs of the quadrupole be.

According to one embodiment of the invention, the selection device is in the form of a pluggable, with four or three plugs, against a null component executed with direct connections exchangeable building block, here can also Pluggable sub-modules are added, each by using a or several of the above features an immediate adaptation of a single one Embodiment of the selectivating device for all respective operating conditions enable.

An embodiment is based on the further figure drawing The figures show: FIG. 5 a circuit diagram of a device according to the invention, which works with a known protective device already described above, Fig. 6 is a diagram which, in addition to the curve of the known device, the course n St shows the device provided with the device according to the invention, and FIG. 7 shows a circuit diagram a device according to the invention with wide features, in Fig. 5 can be found the parts of the protective device already described with the same reference numerals again: differential transformer T, rectifier R (in bridge circuit), capacitor C, Anspreohschwellenschwellenschalter I and executor D, according to the invention is between the Rectifier R and capacitor C a four-pole arrangement 1, 2, 3, 4 switched on, a resistor connected between an input 1 and an output 3 5 and an output 4 connected between output 3 and input 2 has switched component 6 with response threshold that is slightly higher than the response of the switch I, In this way it is achieved that on the one hand in the case of relatively weak fault currents, the component 6 does not intervene, on the other hand but with relatively strong fault currents of component 6, the peaks of the rectifier R dissipates outgoing current. The charging of the capacitor o is slowed down so that and its charging speed is limited to a value below a maximum value, so that there is a change in the characteristic described below, Fig, 6 shows the curve C1 of the device A1 and, in dashed lines, the curve C2 of the conventional one Device A2. The addition of the device according to the invention according to FIG. 5 to the device A2 changes its characteristic, which takes the shape of curve C2 '.

In the case of relatively weak fault currents (point P2), this change is insignificant, but it becomes noticeable rather brusquely when the response threshold of the component 6 is reached, even with a short tip (point .t), and the curve C2 'is bounded on the left by an asymptote t2 which is perpendicular to the abscissa and which is larger as tl, the curve C2 lies clearly in its entirety on the other side of the curve C1 As a result, no matter how large the leakage current generated by a disturbance Z becomes Id is the conventional device A1 associated with this disorder before the device according to the invention modified device A2 come into function, and since that made by the device Al Shutdown turns off the fault, the device A2 does not function, which is the sequence corresponds to the desired sequence, This sequence occurs even with very strong fault currents because t2 is greater than t1.

It is clear that the invention can be applied to device A3 would also give this a modified characteristic 03 '(minimum time t3) and thus not giving him the time to work with the associated device A2 at the same time to come into function.

For the person skilled in the art it is obvious that by an inventive modified associated device A2 in a selective manner also the required protection against several disturbances Z and against one occurring upstream from the device Al Disturbance is guaranteed. The device A3 also provides protection against a upstream of the device A2 occurring disturbance guaranteed.

Thus, the invention enables simultaneous triggering of the Suppress protective devices connected in series by selectively only tripping of the device immediately upstream of the fault.

The device according to the invention can be promoted by further features will. In Fig. 7 there are again the quadrupole 1, 2, 3, 4 and the resistor 5. Here, the component 6 with the response threshold is a Zener diode, for example there with a response threshold of 8 V for switch I, the choice of a Zener voltage of 10 V for component 6 of abscissa t2 the asymptote of curve G2 '(Fig, 6) A value of 60 ms, which is completely sufficient.

Another feature is it (Fig. 7), a resistor 7 between the point common to the resistor 5 and the Zener diode 6 on the one hand and the output terminal 3 on the other hand.

This resistor 7 has the effect of reducing the charging time of the energy storage capacitor C to extend.

Another feature of the invention is to have a capacitor 8 to keep the input terminals 1 and 2 in parallel, this capacitor plays the role an integration capacitor and acts in particular on the peak waveforms, which can be supplied by the take-off transformer X in saturated area, and Above all, it standardizes the function times t2 (and t3) despite the spread in the production of the differential transformers X, the sometimes toric cores made of mu-metal exhibiting the remarkable fluctuations in magnetic properties Furthermore, a resistor 9 can be connected in parallel to the input terminals 1 and 2 be, which enables the dimensioning of the device in a very simple way to modify and for example in particular from the time t2 of the devices A2 to the Time t3 of devices A3 to pass.

The invention also relates to the implementation of the four-pole arrangement in the form of a plug-in module that can be used immediately and through four plugs 1, 2, 3, 4 can be connected, which are inserted into the four sockets of the protective device be inserted against disturbances, A first type of this building block, the null building block, has only direct connections between plugs 1 and 3 and between connectors 2 and 4.

With it, the device has the well-known functionality (characteristic curve such as the Curve Cl of Fig. 6). The other types of these building blocks correspond to the simplest Circuit diagram according to FIG. 5 or this circuit diagram with all or part of the features according to Fig. 7. The same device then results in one of the functions described, in particular with regard to the choice of the characteristic curve C2 'or C3' of FIG. 6, noteworthy is the adaptability achieved, industrially the invention enables series production a protective device in a single design, which can then be replaced by plugging in Modules selectively based on the local needs of the company concerned There are possible modifications in addition to the embodiment described. The module only needs to have three Steoker, since the input connector 2 and the output connector 4 are always connected to each other.

The module can also be booked for sub-modules be provided according to one of the described AusfUhrungeformen, what together with the zero component enables any adaptation of a device on the spot to make according to the invention to local needs.

Claims (6)

Claims 1. Selective device for protective devices against exhaust currents; Which Devices have an acceptance device, an energy storage device with one of the take-off device fed rectifier and one fed by the rectifier Capacitor and a response threshold switch fed by the capacitor and have an execution device fed by the switch, characterized in that that it has a quadrupole (1,2,3,4) and that its one input (1) through the rectifier (K) is fed, the output of which is assigned to this input (1) (3) feeds the capacitor (C) and its other input and output (2.43 with each other and with the return lines of the rectifier (R), the capacitor (c) and the execution device (D) are connected and that a resistor (5) between the input (1) fed by the rectifier and that of the capacitor (A) feeding output (3) is switched on and a component (6) with response threshold between the output (3) feeding the capacitor (o) and the interconnected Inputs (2) and outputs (4) is switched on, with the response threshold of the component (6) is selected higher than the response threshold of switch (I) (Fig. 5). 2. Apparatus according to claim 1, characterized in that it has a common between the resistor (5) and the component (6) with response threshold Point on the one hand and the terminal (D) on the other hand has switched-on resistor (7) (Fig. 7). 3. Apparatus according to claim 1 or 2, characterized in that they have a capacitor connected between the inputs (1,2) of the quadrupole (8) (Fig. 7). 4. Device according to one of the preceding claims, characterized in that that they have a resistor connected between the inputs (1,2) of the quadrupole (9) (Fig. 7). 5. Device according to one of the preceding claims., Dadurdh characterized in that it is in the form of a plug-in, with four or three plugs (1,3, and 2 - 4) provided against a null component with direct connections (i - 3 and 2 - 4) replaceable module. 6. Apparatus according to claim 5, characterized by pluggable sub-modules. Blank page