HU192996B - Circuit arrangement for automatic overload protection of current transformers - Google Patents

Abstract

The circuit arrangement for automatic overload protection of current transformers, especially for preventing overvoltage and overload occurrences and their consequences when the secondary circuit is interrupted, contains, according to the invention, an electronic overvoltage sensor and short-circuit unit (5) which is connected in parallel with the load (4) that is connected to the secondary terminals (2, 3), is preferably constructed using thyristors (14, 17), diodes (15, 18) and zener diodes (16, 19) and, in the event of an unacceptable rise in the voltage which can be measured on the secondary terminals (2, 3) of the current transformer (1), automatically short-circuits the terminals (2, 3) and opens them again when the voltage drops. The circuit arrangement according to the invention operates fully automatically and requires no external operating energy. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for automatic overload protection of current transformers, in particular to prevent overvoltage and overload phenomena occurring in the event of a secondary circuit break and their consequences.

Current transformers commonly used in high-voltage electrical engineering are transformers in which the secondary coil turns are 1 to 5 orders of magnitude higher than the primary coil turns and the load impedance is much lower than the secondary coil impedance. Therefore, the secondary current is practically limited only by the primary current, and the output voltage measured at the secondary terminals is the product of the impedance of the secondary current and the load.

The normal operating state of a current transformer is a state in which the primary current is determined by the connection network and the load on the secondary terminals varies between the short circuit and the impedance corresponding to the permissible load. In this case, due to the roll-up of the two coils, the flux, the iron loss and the voltage at the secondary terminals of the current converter core are relatively small. If the load impedance of the load increases, the flux of the current converter core and the value of the iron loss will increase with the voltage at the secondary terminals. This becomes more pronounced when the secondary circuit is interrupted when the load impedance is infinitely high. In this case, the total primary excitation creates the flux of the ferrous core, so it will be many times the nominal value. As a result, the secondary terminals show an overvoltage to the equipment and the operator, while the iron core becomes very hot and may explode. Overloading therefore causes the risk of accidents and damage. The value of the damage is mainly due to the destructive damage caused by the explosion and the indirect damage caused by the accident breakdown, compared to the value of the damaged current transformer.

In order to avoid the described adverse effects, it is imperative to prevent the overload caused by the increase in the impedance of the secondary side of the current converter above the rated value. In the state of the art, long-term overload is prevented by proper operation, and overload due to secondary side interruption is prevented by short-circuiting the secondary terminals before mounting in secondary pathology.

The disadvantage of the known precautions is that its effectiveness, due to its predetermined human activity, does not prevent overload due to uninterrupted operation and technical failure. Therefore, technical measures are needed which automatically prevent overloading of the current transformer, regardless of human activity.

SUMMARY OF THE INVENTION The object of the present invention is to solve the automatic overload protection of current transformers, in particular to prevent overvoltage and overheating when the secondary circuit is interrupted, and their harmful consequences.

The invention is based on the recognition that

- on the one hand, the phenomenon of increased voltage at the secondary terminals of the goods exchange, which precedes the occurrence of an overload,

- on the other hand, overloading can be prevented by short-circuiting the secondary terminals of the current transformer.

In an embodiment of the present invention, an electronic overvoltage detector and short-circuit unit is connected in parallel with the load applied to the secondary terminals of the current transformer such that one corner of the load is connected to one electrode of the secondary terminal of the current converter and and is connected to the other common terminal of the other secondary terminal of the current transformer and the other electrode of the electronic surge detection and short-circuit unit.

Preferably, the electronic overvoltage detector and short-circuit unit is incorporated in the current converter molded housing such that one common terminal of one of the secondary terminals of the current converter and one of the electrodes of the secondary voltage transducer of the current converter is connected to the load. and a second common terminal to the other electrode of the short-circuit unit.

The electronic surge arrestor and short circuit assembly may be a suitably designed surge arrester.

In another preferred embodiment of the circuit arrangement according to the invention, the surge detection and short-circuit unit comprises a counter-circuit electronic circuit consisting of a first thyristor, a first diode and a first Zener diode, and a second thyristor, a second diode and a second Zener diode such that and the second point of the thyristor connected to one another forms one electrode of the electronic surge detection and short circuit unit, the interconnected point of the first thyristor cathode and the second thyristor anode forms the other electrode of the electronic surge detection and short circuit. However, the anode of the first diode is connected to the first thyristor anode cord, the cathode of the first diode is connected to the cathode of the first Zener diode, and the anode of the first Zener diode is coupled to the control electrode of the first thyristor. is connected to the anode of a thyristor, and finally the cathode of the second diode is connected to the cathode of the second Zener diode and the anode of the second Zener diode is connected to the control electrode of the second thyristor.

In a further preferred embodiment of the inventive inventive arrangement, the electronic surge detection and short circuit unit comprises an electronic circuit consisting of a first and second thyristor and a first and second Zener diode such that the anode of the first thyristor and the cathode of the second thyristor forming one electrode of the electronic surge detector and shorting unit, the interconnected point of the first thyristor cathode and the second thyristor anode forming another electrode of the electronic surge detector and short circuit, whereas the first Zener diode cathode of the first thyristor anode, and the anode is connected to the control electrode of the first thyristor, the cathode of the second Zener diode to the anode of the second thyristor, the second Zener diode Fee is connected to the control electrode of the second thyristor.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in detail with reference to the drawings, in which: FIGS. Figures 1 to 5 show exemplary embodiments.

On the drawing;

Figure 1 is a conceptual sketch,

Figure 2 is a schematic diagram of a surge arrestor and short-circuit installed in the molded housing of the current transformer,

Figure 3 sketch with surge arrester,

Figure 4 is a sketch with a diode and Zener diode voltage detector and a thyristor short circuit,

Figure 5 Sketch with Zener diode overexposedBe sensor and thyristor short circuit.

In the schematic diagram shown in Fig. 1, an electronic surge sensor 5 and a short-circuit unit 5 are connected in parallel with a load 4 applied to the secondary terminals 2, 3 of the current transformer. One corner 6 of the load 4 is connected to a common terminal 8 of one of the secondary terminals 2 of the current transformer 1 and one of the electrodes 7 of the electronic surge detection and short-circuit unit 5. The other corner 9 of the load 4 is connected to the other common terminal 11 of the other secondary terminal 3 of the current transformer 1 and the other electrode 10 of the electronic surge detector and short-circuit unit 5. Thus, when the current converter 1 is overloaded, the electronic overvoltage detector and short-circuit unit 5 causes the secondary terminals 2, 3 to be short-circuited as a result of the overvoltage appearing on the secondary terminals 2, 3, thus automatically relieving the current converter 1.

In order to increase the efficiency of the overload protection, it is advisable to ensure that the electronic overvoltage detector and short circuit 5 is the secondary current transformer 1.

It should not be accidentally detached from its terminals 2, 3, and intentionally only by gross damage. This condition is met in the embodiment of the schematic diagram of Fig. 2, wherein the electronic surge detection and short-circuit unit 5 is incorporated in the molded housing 12 of the current transformer 1. To connect the load 4, one common terminal 8 of one of the secondary terminals 2 of the current converter 1 and one of the electrodes 7 of the electronic surge detection and short-circuit unit 5 and another common terminal 11 of the other electrode 10 of the electronic overvoltage detector 5. is designed.

One device can provide the overvoltage detection and short-circuit function of overload protection. One such solution is the

The embodiment of Fig. 3, wherein the electronic surge detection and short-circuit unit 5 is a suitably formed surge arrester 13, e.g. a surge arrester of semiconductor material, a suitably assembled selenium cell line, or other arrestor of voltage according to the state of the art, which acts as a short to voltage over the rated voltage.

The actuation voltage of the electronic overvoltage detector 5 and short circuit unit 5 can be more precisely adjusted and the dissipated power reduced by the embodiments shown in Figures 4 and 5.

In the circuit arrangement of FIG. 4, the electronic surge detection and short-circuit unit 5 comprises a counter-circuit consisting of a first thyristor 14, a first 15 diode and a first Zener diode 16, and a second thyristor 17, a second 18 diode and a second Zener diode 19. . The junction point of the anode 20 of the first thyristor 14 and the cathode 21 of the second thyristor 17 forms one of the electrodes 7 of the electronic surge sensor 5 and the junction point of the cathode 22 of the first thyristor 14 and the anode 23 of the second thyristor 17 forming 10 other electrodes of the short-circuit unit. The two thyristors 14, 17 short circuit the secondary terminals 2, 3 of the current transformer 1, and the function of the overvoltage detection and the ignition of the thyristors 14, J7 are performed by the diodes 15, 1K and the Zener diodes 18, 19. To this, the anode 24 of the first diode 15 is connected to the anode 20 of the first thyristor 14, the cathode 25 of the first diode 15 is connected to the cathode 28 of the first Zener diode 18, and the anode 27 of the first Zener diode 16 is connected to the control electrode 28 . Similarly, the anode 29 of the second diode 18 is connected to the anode 23 of the second thyristor 17, the cathode 30 of the second diode 19 is connected to the cathode 31 of the second Zener diode 19 and the anode 32 of the second Zener diode 19 is connected to the control electrode 33 . Thus, if the voltage at the secondary terminals 2, 3 of the current converter 1 reaches the value of the Zener voltage in any direction, the corresponding thyristor control current is supplied and ignited, thus short-circuiting the secondary terminals 2 to prevent overloading of the current transformer 1. The ignited thyristor will turn off after half a period, so that the overload protection short circuit will automatically disappear.

The first and second diodes 15, 18, respectively, reduce the downstream stress on the control circuits of the first and second thyristors 14, 17. If the voltage generated at the secondary terminals 2, 3 is less than the permissible closing voltage of the control circuit of the thyristors 14, 17, then diode 15, 18 may be omitted. This embodiment is illustrated in Figure 5, wherein the electronic surge detector 5 and the short-circuit breaker 5 comprise an electronic circuit comprising a first and second thyristors 14, 17 and a first and second Zener diode 16, 19. In the coupling, the anode 20 of the anterior thyristor 14 and the cathode 21 of the second thyristor 17 form one electrode 7 of the electronic surge detector 5, whereas the anode 23 of the first thyristor 14 and the anode 23 of the second thyristor 17 forms 10 other electrodes of the overvoltage detector and short circuit. For ignition of the thyristors, the cathode 26 of the first Zener diode 16 is connected to the anode 20 of the first thyristor 14 and the anode 27 of the first Zener diode 16 is connected to the control electrode 28 of the first thyristor 14. Similarly, the cathode 31 of the second Zener diode 19 is connected to the anode 23 of the second thyristor 17 and the anode 32 of the second Zener diode 19 is connected to the control electrode 33 of the second thyristor 17.

Detailed Description of the Embodiments It will be appreciated by those skilled in the art that the circuit arrangement of the present invention is in accordance with the object, since by automatically limiting the voltage between the secondary terminals 2 and 3 of the current converter 1 it prevents overloading of the current converter 1. An advantage of the circuit arrangement according to the invention is that the overload protection starts and stops functioning independently of human activity and only acts when it is required to function. A further advantage is that no auxiliary power source is required to operate the circuit arrangement according to the invention, therefore the system reliability is very high.

Claims (7)

PATENT CLAIMS Circuit arrangement for automatic overload protection of current transformers, in particular to prevent overvoltage and overheating during secondary circuit breakage and their consequences, characterized in that an electronic overvoltage detector (4) connected to the secondary terminals (2, 3) of the current transformer (1) and 5) is connected in parallel such that one corner (6) of the load (4) is connected to a common terminal (8) of one of the secondary terminals (2) of the current transformer (1) and one of the electrodes (7) of the electronic surge detection and short-circuit unit ), and the other corner (9) of the load (4) is connected to the other common terminal (11) of the second secondary terminal (3) of the current transformer (1) and the other electrode (10) of the electronic surge detection and short-circuit unit. Circuit arrangement according to Claim 1, characterized in that the electronic overvoltage detection and short-circuit unit (5) is integrated in the molded housing (12) of the current transformer (1) such that the current (1) is connected to the load (4). ) at one of the secondary terminals (2) and one common terminal (8) of one of the electrodes (7) of the electronic overvoltage detection and short-circuit unit (5), and at the other secondary terminal (3) of the current transformer (1) ) is provided with another common terminal (11) of another electrode (10). Circuit arrangement according to claim 1 or 2, characterized in that the electronic overvoltage detector and short-circuit unit (5) is a surge arrester (13). Circuit arrangement according to claim 1 or 2, characterized in that the electronic surge detection and short-circuit unit (5) comprises a first thyristor (14), a first diode (15) and a first Zener diode (16) and a second thyristor (16). 17), a second diode (18) and a second Zener diode (19) comprising a parallel circuit electronic circuit such that the anode (20) of the first thyristor (14) and the cathode (21) of the second thyristor (17) are interconnected. forming one of the electrodes (7) of the electronic surge detection and short-circuit unit (5), the common point of the anode (23) of the first thyristor (14) and the anode (23) of the second thyristor (17) form the electronic surge detector and short-circuit (5) another electrode (10) at the same time. the anode (24) of the first diode (15) is connected to the anode (20) of the first thyristor (14), the cathode (25) of the first diode (15) is connected to the cathode (26) of the first Zener diode (16), and the anode (27) of the first Zener diode (16) is connected to the control electrode (28) of the first thyristor (14), while the anode (29) of the second diode (18) is connected to the anode (23) of the second thyristor (17). the cathode (30) of the second diode (18) is connected to the cathode (31) of the second Zener diode (19) and the anode (32) of the second Zener diode (19) is connected to the control electrode (33) of the second thyristor (17). connected. Circuit arrangement according to claim 1 or 2, characterized in that the electronic surge detection and short-circuit unit (5) consists of a first and a second thyristor (14, 17) and a first edge of a second Zener diode (16, 19). comprising a parallel-connected electronics circuit such that a common point on the anode (20) of the first thyristor (14) and the cathode (21) of the second thyristor (17) forms an electrode (7) of the electronic surge detection and short-circuit unit (5); The cathode (22) of the first thyristor (14) and the anode (23) of the second thyristor (17), on the other hand, form the electrode (10) of the electronic voltage sensing and short-circuit blocking unit (5) 10 cathodes (26) of the first Zener diode (16) connected to the anode (20) of the first thyristor (14) and anode (27) of the first Zeier diode (16) connected to the control electrode (28) of the first thyristor (14), a cathode (31) of a second Zener diode (19) a 15 are connected to the anode (23) of the second thyristor (17) and the anode (32) of the second Zener diode (19) is connected to the control electrode (33) of the second thyristor (17).