SU792473A1 - Device for earthing transformer neutral in electric networks - Google Patents

Description

The invention relates to electrical engineering, more precisely to devices for the protection of the insulation of debris. power transformer ditch.  Devices for protection against the overvoltage of the insulation of the y-neutral windings of power transformers 11О-22 are known. In power systems, for this purpose, grounding is not usually applied to a switch-over discharge.  The arrester is selected for the voltage level of the nominal voltage.  However, when the 11th overvoltages are possible in operation, the neutral armature triggers and the transformer's neutral turns out to be deafly grounded, and a significant magnitude that flows through the arrays accompanying the single-phase current circuit causes excessive overheating and destruction of the armature. .  A device for protection of a transformer neutral is known, which contains a saturation choke, which is provided with an additional biasing wiring connected to a constant power source through the relay contacts, the winding of which is connected to the bias winding circuit 11.  This device allows reducing the amount of switching overvoltages on the transformer windings.  The disadvantages of this device are the significant inertia of the device operation, due to the relatively large constant time when the control winding is turned on, the increased value of the single-phase short circuit to earth, as in the throttle saturation mode the neutral of the transformer turns out to be almost deafly grounded.  It is also known a device for earthing a transformer neutral, which in electric networks contains two grounded branches, in one of which a choke with a switching winding and a control winding connected to a source of direct current through a disconnecting device (shunt) and transformer. current, and in the other branch is included spark gap.  The use of this device solves the problem of switching overvoltages on the neutral of power transformers while at the same time improving speed and effective current termination With a single-phase short to ground.  The disadvantages of this device are that the spark gap of the device does not provide protection against overvoltages of lower values, leading to premature destruction of the insulation materials; The pre-saturated choke does not limit the single-phase short-circuit current and the magnitude of the dynamic effects on the electrical equipment due to the low inductive resistance of the operating winding. In transient saturation of throttles, ferro-resonance effects are possible with two-phase short-circuits; preliminary saturation of throttles before the onset of overvoltages of a dangerous magnitude leads to the need for an independent DC source.  According to the principle of operation and design, the device closest to the claimed solution is a device for grounding a transformer neutral in electric networks, which contains two grounded branches, the first of which is connected through a spark gap shunted by a switching device, a saturable choke, the working winding of which is included in series with the spark gap, and, the control winding is connected to the DC source via the break contact of the switching device, the transformer current and voltage transformer, the second is connected through a spark gap shunted by a switching device, two resistances, a non-linear ferromagnetic element connected in parallel to the first resistance from the spark-gap side, a current transformer and a voltage transformer, and the connection point of two revistors of the second circuit through The third resistor and the break contact of the switching device 34 is connected to the connection point of the spark gap and the throttle of the first circuit.  The use of these devices solves the problem of increasing the efficiency of limiting internal overvoltages, maintaining speed while limiting single-phase short-circuit currents and eliminating an independent DC source.  The prototype's shortcomings are: insufficient efficiency of shunting one of the resistances of the second branch by a nonlinear ferromagnetic element under rapidly changing modes in networks, as a result of which the voltage across the arc resistance of the specified branch, supplying the rectifier device, decreases with a corresponding decrease in the rectified current on the winding control, in the mode of joint inclusion of the contacts of both of the closed-loop circuits, the points in the latter can be commensurate in magnitude, which precludes the possibility of timely disconnecting the contacts of the second relay circuit from transfomers current or voltage ukazashyuy chain; the breakdown of the spark gap of the first circuit in the neutral of the power transformer with the minimum resistance value of the saturable droplet leads to dangerous dynamic effects in the neutral of the power transformer; (- the effectiveness of the increase in the resistance of the saturating droplet is sufficient in time until the disconnecting of the linear switches in case of occurrence of short-circuit currents of large quantities as a result of exposure to dangerous values of overvoltages; isolation of electrical equipment; simultaneous disconnection of device contacts. at the moment of occurrence of dangerous short circuit currents in the first branch with a saturated choke, it excludes its operation in a functional dependence on the values of the indicated currents.  The aim of the invention is to improve the effect of limiting internal overvoltages and short-circuit currents, completely eliminating dynamic effects in the neutral of a power transformer, eliminating the likelihood of overvoltage of hazardous quantities in transient conditions of increasing throttle and maintaining fast performance without an independent source of direct current.  This goal is achieved due to the fact that a device for earthing a transformer neutral in electric networks, containing two for the earth branches, in each of which current transformers, main voltage transformers and sparking gaps, connected by main, first and second switching devices, are installed, the contact blocks of each of which are connected to the contacts of the current transformer relay of the corresponding branch, and the contact blocks of the first main switching device of the first branch are connected to the mi-ko unit the relays of the voltage of the corresponding branch, in series with the spark gap of the first branch, are connected successively connected main resistors, one of which is shunted by a choke, the main transformer of the voltage of the first branch connected to the junction point of the arrester and the main resistor, and in the second branch the saturation throttle of the control winding of which is connected through the third main switching device to the two terminals of the constant source (Yann current, two Other Which is connected with two pins of the second resistor of the first branch, and the ungrounded output of saturation throttles is connected with the connection point of the resistors of the first branch and the fourth main switching equipment is installed in this circuit, equipped with additional resistors, additional switching devices and additional voltage transformers . The first and second additional resistors are connected in series to the second branch, between the point of their connection the main transformer and one of the main terminals are connected. switching device, parallel to the auxiliary resistor, the first additional switching device is connected, the block contacts of which are connected To the contact blocks of the relay of the additional voltage transformer of the second branch, the second additional switching device is connected by one output to the additionally inserted switch element of the throttle; connected to the output of the fourth power supply, the switching unit connected to the saturation throttle, the contact blocks of which oh connected to the contact block of the main voltage transformer of the second branch, to the output of the fourth base switchboard is connected the output of the third additional resistor, the second output of which is connected to the connection point of the main resistors of the first branch, and the third additional resistor is shunted by the third additional switching device, blocking the contacts of which are connected with relays-contacts of the voltage of the main transformer of the voltage of the second branch, the fourth additional A resistor is connected between the DC output and the connection point of the main resistors of the first branch, the fourth additional resistor is shunted by a fourth additional switching device, the contact blocks of which are connected to the contact blocks of the additional voltage transformer of the first branch connected between the connection point of the main resistors, A second additional voltage transformer is connected between the main connection point.  A second additional voltage transformer is connected between the connection point of the second additional resistor and saturation throttles, with the contacts of its relay being connected to the contacts of the third and fourth switching devices.  The drawing shows the electrical circuit of the device.  It contains a transformer 1 with a grounded neutral, a spark gap 2 of the first branch, resistors 3 and 4 installed in the first grounded branch, a current transformer 5 with a relay of the first branch, a switching device 6, a bypass spark gap, a choke 7, a bypass resistor 3, a spark gap S of the second branch, saturation inductor 9, current transformer U with the relay of the second branch, switching device 11 shunt the spark gap of the second branch, the third additional resistor 12 in the circuit connecting the first and second branches, switching unit 13 in the same chain, the source 14, the DC control winding 15 of the choke saturation, the switching device 16 associated with the control winding of the choke saturation main Transfrm. 77 matora 17 and 18 voltage with relay, up to additional transformer 19 for voltage with relay of first branch, fourth additional switching device 20, fourth additional resistor 21, additional transformer 22 of voltage of second branch, third additional switching device 23, second additional the switching device 24, the switching element 25 saturation drossel, the first additional reanstor 26, the first additional switching device 27 and the second additional resistor 28.  .  A branch is connected to the neutral point of anformator 1 through the izvrovoy interval between two; From the connected resistors 3 and 4, the other end of this branch is grounded to the current transformer 5.  Parallel to the spark gap 2, the switching device fe is turned on, the contact blocks of which are connected to the contact blocks of the voltage transformer 17 and the current transformer 5.  Parallel to the resistor 3, a linear ferromagnetic element is connected, in particular the Saturated choke 7.  Through the spark gap 8 to the neutral of the transformer 1, a branch of series-connected resistors 26 and 28 and a saturable droplet 9 is connected, the other end of this branch is grounded through the current transformer 10.  Parallel to the spark gap 8 and the resistor 26, the switching device 11 is turned on, the block-contact of which is connected to the contact blocks of the relay of the current transformer 10, and the resistor 28 is bridged by the switching device 27 whose block contacts are connected to the contact blocks of the relay of the transformer 22 wives  Between the resistors 3 and 4 of the second branch, as well as the resistor 2 and the working winding of the saturating throttle, an intermediate branch is included, consisting of series-connected resistor 12 and switching device 13, the contact blocks of which are connected to the contact blocks of the relay of the voltage transformer 2 and the resistor 12 is shunted by the switching device 23, the contacting motor blocks are connected to the contact terminals of the voltage transformer 18 relay.  Parallel to the resistor 4 through the resistor 21, shunt by the switching device 20, the contact blocks of which are connected to the contact blocks of the relay of the voltage transformer 19, connect 38 a direct current source 14 that supplies a direct current to the control winding through the contacts contacts of the switching device 16 associated with the contact blocks of the relay transformer 22napr.  The electrical connection of the switching element 25 of the working winding of the saturating throttle 9 by the intermediate branch is carried out through the switch contacts of the switching device 24 connected to the contact blocks of the relay of the voltage transformer 18.  Between the spark gap 2 and the resistor 3, the resistors 26 and 28, 3 and 4. transformer 17, 18, 19 and 22, respectively, are connected by a resistor 28 and a working winding of saturation droplets 9, respectively.  In the normal mode, the operation of the networks of the power transformer 1 is isolated due to the fact that the contacts of the switching devices 6 and 11 are open.  The contacts of switching devices 16 and 27 are in the on state, and the contacts of switching devices 20, 23k 24 are disconnected.  When an internal overvoltage occurs in the neutral values of the sparking gap 2, the neutral of the power transformer 1 is punched and grounded through the resistors 3 and 4, as well as the current transformer 5.  Internal overvoltages are limited in magnitude and the probability of their development decreases over time.  Selection of the breakdown voltage. Spark gap 2 is performed depending on the static estimate of the average overvoltage fluxes for different groups of substations as applied to specific ones. sets of the corresponding voltage.  When exposed / internal overvoltages above the minimum selected value, the contacts from the transformer 17 voltage relay are switched on and the spark gap 2 shunts. In the case of a spark gap 2 when exposed to internal overvoltages below the minimum selected value, but when high currents occur in the neutral of the power transformer the switching device 6 is switched on by the relay tans (| jrmator 5 current, while the voltage arising on the resistor 4 is applied to the source 14 constant Nogo current through the coil 15 and the control at p. The switched-on contacts of the switching device 16- 97 start flowing rectified current, which leads to the beginning of the 1st process of decreasing the destructive resistance of the working winding of saturation throttles 9 and ensuring a preliminary decrease in the resistance of the saturating throttling to occurrence. the need for its inclusion in the neutral power transformer to limit the internal overvoltage of a dangerous quantity.  Reducing the voltage on resistor 3 with a specially selected saturable choke 7 helps maintain voltage on resistor 4 despite shunting the latter with rectified control winding 15 and eliminates the likelihood of droplet saturation lower than the required value.  Such a solution eliminates the need for constant energization of the control winding 15 from a direct current source and an additional control winding.  By reducing the internal overvoltage-1 and currents in the neutral From the seam transformer 1 below the minimally selected squirrel contacts are opened and the device returns completely to its original position.  The current through the active resistor 12 and yet the reduced inductive resistance of the working winding of the throttle 9 saturation is very small compared to the current through the resistors 3 and 4, therefore, it does not significantly affect the operation of the device.  With unstable transient processes in networks, especially in the pre-emergency period. However, short-term reductions in overvoltage occur with a small accompanying current, the bypass efficiency of resistor 3 is nonlinear ferromagnetic, the element decreases, and the voltage across resistor 4 does not meet the requirements to provide the necessary rectified current. .  on the winding 15 control.  Therefore, when the voltage on the iiiDKe resistor 4 permissible value is reduced, the contacts of the switching device 20 are connected to the relay of the voltage transformer 19, the shunt resistor 21 is specially selected, which provides the necessary amount of rectified current on the control winding 15.  As the voltage across the resistor 4 rises to the corresponding value, the KOViMyTamtoHHoro contacts of the 2O device are disconnected from the transformer relay on April 19, providing the newly required supply current of the power supply 14.  If the internal voltage is higher than the permissible value when the contacts of the switching device 6 are turned on, the voltage in the neutral of the power transformer 1 decreases and the shunting efficiency of the resistor 3 increases by saturating the throttle 7, which in the complex leads to maintaining or, if necessary, increasing the current through the resistor 4, consequently, an increase in the voltage of the power supply of the direct current source 14 with a subsequent increase in the current in the winding 15 of the energies and a more intensive reduction in the resistance drossed whose winding saturable, and this in turn leads to an increase in current through resistor 12 protekayuschegos and increase the amount of voltage on the spark gap 8.  In addition, the selection of the value of the resistor 12 depending on the electrical parameters of the entire device contributes to adjusting the current in the control winding 15 depending on the decrease in resistance in the working winding of the throttle 9.  Upon reaching overvoltages or currents in the neutral of the power transformer of hazardous quantities, the total voltage across the resistors 3 and 12 reaches the breakdown value of the spark gap 8, which penetrates through the contacts of the switching device 11 as a result of the relay operating from the current transformer 10.  Briefly, finding the contacts of switching devices 6 and 13 in a simultaneously closed state helps to effectively reduce the internal overvoltages of a dangerous magnitude in the neutral of the power transformer 1 at the initial moment. their action in connection with maintaining the required voltage on the source 14 as a result of bypassing the saturable choke 7 not only of the resistor 3, but also in parallel with the connected resistor 12.  Further, the shunting of the second branch by the reduced resistance of the working winding of the chokes 9 causes the contacts of the switching device 6 to open in connection with a decrease in the voltage and current below the nominal permissible values in the specified branch with the simultaneous disappearance of the effect of shunt1 of the resistor 12 by saturating throttle 7.  117 CttHaiKO B joint switching on mode of switching devices. 6 and 11 of both grounding circuits, with the intermediate circuit connected through the contacts of the switching device 13 with a resistor of 12 currents, detected by the current transformers 5 and 10, can be commensurate in magnitude, which eliminates the possibility of modern switching contact disconnection.  Para 6 from a relay of a current transformer 5 or a voltage transformer 17.  Therefore, when the voltage rises on a saturable choke 9 of a higher value, the contacts of the switching device 23 from the relay of the transformer 22 of the voltage and resistor ia 12 are bypassed, and if necessary the contacts of the switching device 24 from the relay of the specified voltage converter 22 are switched on. ; venno or after a certain time delay.  This provides the necessary reduction in the second voltage and current branch below the minimum allowable values and reliable disconnection of the contacts of the switching device 6.  Further, in the process of increasing the resistance of the working winding 9 in order to limit the short circuit current, before the linear switch is turned off, a resistor 12 connected in series with the resistor 4 limits the current and, consequently, and. supply voltage of power supply source 14, up to the Minimum value, which excludes the operation of the protection of the second branch to turn on the contacts of the switching device 6, and prevents the occurrence of an effective current value in the control winding 15.  When the current in the working winding 9 of the saturating throttle decreases below the nominal permissible value, the contacts of the switching device 11 are disconnected from the relay of the current transformer ip and the device rotates into its original position.  However, as a result of the effect of internal overvoltages: a dangerous quantity, subsequent damage to the insulation of electrical equipment and power lines with the occurrence of single-phase short-circuit currents even with the switching device contacts 11, is possible.  To eliminate the impact of shock current in the neutral of the power transformer 1, which occurs during the breakdown of the spark gap 8 through the first circuit, shunt the second and intermediate circuits with resistors 3, 4 and 12, as a result of the small value of the resistance of saturated droplets 9, successively.  with a spark gap 8, a resistor 26 is connected, which prior to contact closure of the switch. Irn-device 11 completely eliminates the dynamic effects on electrical equipment.  After the contacts of the switching device 11 are closed, a large single-phase short circuit current, -: in the neutral of the power transformer 1, passes through the protective resistance of the working winding of the chokes 9, although the previously saturated droselsel, however, triggers the relay from the voltage transformer 18 and then disconnects the switching device contacts 16 automatic field quenching in the circuit of the control winding 15 and the contacts of the switching device 13 in the series of series-connected resistors 4 and 12.  Next, the relay is activated by the current transformer 1O and the contacts of the switching device 11 are turned off with the subsequent switching on of the contacts of the switching devices.  16 and 13 when the relay from the transformer 22 voltage is triggered.  The device returns to its original position.  When high-value short-circuit currents occur as a result of the preliminary effects of dangerous overvoltages of increasing the resistance of the saturating droplet 9 until the disconnecting of the linear switches may not be sufficient in time: and the connection with the previously switched contacts of the switching device 23, bypassing the intermediate branch resistor 12 and causing an increase in the voltage on the resistor 4 and an increase in the rectified current, on the bomb 15 times a voltage.  - Switching off the coil of the switching device 27 from the voltage relay of the transformer 22 followed by the introduction of resistor 28 into the first circuit reduces the magnitude of the short-circuit currents, as shown by transient studies, the process is almost beanatrically inductive resistance of the working winding 9 of the saturable droplets increases many times due to the fact that limiting the value of a single-phase short-circuit current before it is turned off by a linear switch.

In transient saturation modes of drossels, the occurrence of resonant voltage or current and ferroresonance overvoltages of dangerous quantities is possible.

Regimes of series connection of resistors 3, 12 or 28, and parallel connection of resistors 4 and 12 with respect to saturating choke 9 completely exclude the likelihood of resonant overvoltage, and the presence of switching element 25 provides an instantaneous decrease in resistance of saturable throttle 9 to a set value after switching on the contacts of the switching device 24 from the relay of the voltage transformer 18, this ensures the limitation of ferroresonant overvoltages to safe values.

Simultaneous disconnection of the contacts of switching devices 6, 13 and 16 at the time of the emergence of short circuit currents of large quantities in a saturated choke 9 prevents their operation in a functional manner depending on the magnitude of the indicated currents.

But the presence of the contacts of the switching device 20, shunting the resistor 21 if necessary and increasing the supply current of the source 14, is bridged by the contacts of the switching device 23 of the resistor 12 and, if necessary, closing the contacts of the switching device 24 to instantly decrease the resistance of the saturated throttle 9 using the switching element 25, as well as the disconnection of the contacts of the switching device 27 for the introduction of resistance, fully ensures the operation of the device in a functional manner. awn from the network operation mode in terms of overvoltages and short-circuit currents.

The technical and economic efficiency of the invention is determined by the fact that it is used in networks of any voltage class, regardless of the neutral grounding mode, significantly increases the reliability of electrical equipment in the power industry.

In systems with insulated neutral, the proposed device reduces the overvoltage when a moving arc occurs

full-phase modes and ferroresonance phenomena with current preserved within regulated limits. In systems with deaf grounding

The proposed device contributes to the effective reduction of single-phase short-circuit currents, being included in the neutral of high-power transformers, limiting the increase

voltage on the insulation of the neutral to the permissible value ..

An important advantage of the proposed device is the complex limitation of internal overvoltages.

and short-circuit currents while maintaining positive speed factors in connection with the preliminary initiation of throttles before the appearance of emergency modes.

The device can be used not only in high voltage power systems, but also in various non-electrical devices for effective limitation; internal overvoltages and single-phase short-circuit currents.

Claims (3)

1. USSR Author's Certificate No. 478387. Cl. H 02 And 1/04, 1973. 2. Author's svidete.hstvo USSR N9 55O713, class. H O2 II 1 / 1G, 1974. 3. Author's certificate of the USSR in the application for 245О627 / 24-О7, and О2 М 7 / О 07.02.77. X,