RU2348998C1 - Controllable transformer-type reactor - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to electrical engineering and may be used as static capacitor of excessive reactor power in power grids. The reactor is provided with a closed core, central rod being within the closed core, control winding coiled on the central rod, network winding and control unit. The cylindrical rod is available in the reactor. It is situated concentrically with regard to the central rod and linked with the closed core. At least, one transverse clearance is available in the central rod. The network winding is coiled on the central rod. The length of the transverse clearance or total length of the transverse clearance satisfies the condition:

where L_cl - length of the transverse clearance or total length of the several clearances; µ_r - relative magnetic conductivity of the cylindrical rod material; µ₀=4π·10^-7 H/m (absolute magnetic conductivity of the transverse clearance) B_s - operating induction of the cylindrical rod material; L -cylindrical rod length; F - magnetomotive force of network winding.

EFFECT: increased reaction and efficiency factor, simplification of design, reduction of dimensions and amounts of conducting materials used.

3 cl, 3 dwg

Description

The invention relates to the field of electric power and electrical engineering and can be used as a static compensator for excess reactive power in electric networks.

Known controlled reactor containing a magnetic circuit, on the core of which there is a network winding, a control winding and a compensation winding, a control unit connected to the control winding (WO 00/25328, H01F 29/14, 21/08, published on 05/05/2000).

Regulating current control windings of the device are made of partially controlled semiconductor devices (thyristors). Higher harmonics arising during thyristor operation are suppressed by connecting higher harmonic filters to the compensation winding

The limitations of this technical solution are: complication and appreciation of the device due to the need to perform special compensation windings and filtering devices; increased consumption of conductive materials for the manufacture of the network winding due to the large distance between the network winding and the control winding; large dimensions and insufficient for the requirements during operation in electric networks response time of the reactor.

Known controlled shunt reactor-autotransformer containing a magnetic circuit with a main rod, yokes, two side yokes, a network winding located on the main rod, connected by an autotransformer circuit and consisting of a series winding and a common winding with a connection node output between them, a compensation winding, a control winding blocks controlling the current of the network winding, while the main rod is divided into two longitudinal parts: a rod without air gaps and a rod with air gaps, at ohm, a rod without air gaps is covered by a control winding and a sequential winding, and a compensation winding and a common winding are covered by a rod without air gaps with the mentioned windings and a rod with air gaps (Patent RU 2297062, H01F 29/14, G05F 1/10, publ. 10.09. 2006).

This device is asymmetric. The series winding covers the control winding, and the common winding is located on top of the compensation winding. The cross section of the rods without air gaps and with air gaps are in the form of circle segments, with compensation and common windings placed around the entire circumference, and sequential and control windings around the rod segment without air gaps. Between the ends of all windings and yokes placed ring shunts with a radial cut, and ring shunts are made in a shape corresponding to the cross-sectional shape of the ends of the windings protruding beyond the contours of the magnetic system. The output of the network winding and the output of the connection node between the serial and common windings are connected to the power transmission through switching devices.

The limitations of this technical solution are: the use of a rod with air gaps leads to an even larger increase in the diameter of the network winding compared to the previously described analogue, since both rods are used to enable the reactor to operate in autotransformer mode; the complexity of manufacturing the device, because the implementation of the rod, divided into two parts, the cross section of each of which is made in the form of a segment of a circle, is a difficult process; the complexity of the design and increased consumption of materials due to the use of the compensation winding and the specific connection of the control, serial, compensation and common windings, large dimensions.

The closest is a transformer-type controlled reactor containing a closed magnetic circuit, a central rod located inside the closed magnetic circuit and connected to it, a control winding located on the central rod, a network winding located coaxially outside relative to the control winding, and a control unit configured to control the current control windings and connected to it (Patent RU 2221297, H01F 38/02, H01F 29/02, publ. 31.10.2002).

In this technical solution, the reactor has a closed magnetic circuit without air gaps, a coaxially located network winding, a control winding and a compensation winding located between them, blocks controlling the current of the network winding, devices for limiting higher harmonics in the current of the network winding, in which the end parts of the windings are top and bottom they are covered by magnetic shunts, and the winding space between sector magnetic shunts, trapping the magnetic flux of scattering and guiding e on to the yokes of the magnetic circuit, and the total cross section of the magnetic yoke ΣR _I exceeds the cross section F _{of Article} rod core and is selected from the condition

,

,

where a ₁ is the thickness of the network winding;

a ₂ is the thickness of the control winding;

a ₁₂ is the thickness of the gap between the network winding and the control winding.

Vacuum circuit breakers are used as control keys of the control unit in this device, therefore, the controlled reactor operates only with two current values in the network winding: minimum - with the vacuum switch open and maximum (rated current) - with the vacuum switch closed.

Since the distinguishing feature of transformer-type reactors is that the nominal mode is the short circuit mode of the control winding, the set value of the rated current of the network winding (reactor power) in this device is set by increasing the distance between the network winding and the control winding in comparison with a transformer of the same power.

The limitations of this technical solution are: a large response time of the reactor to a change in current or network voltage due to the ability to work only with two values of reactor inductance: maximum - with an open vacuum circuit breaker and a minimum - closed vacuum circuit breaker; increased consumption of conductive materials for the manufacture of compensation and network windings of large diameter; the complexity of the device due to the use of a compensation winding and magnetic shunts; large dimensions.

The problem solved by the invention is the improvement of technical and operational characteristics.

The technical result that can be obtained by carrying out the invention is an increase in speed and efficiency, simplification of the design, reduction of dimensions and used conductor materials.

To solve the problem with achieving the specified technical result in a known controlled transformer type reactor containing a closed magnetic circuit, a central rod located inside the closed magnetic circuit and connected to it, a control winding located on the central rod, a network winding located coaxially outside relative to the control winding, and a control unit configured to control the current of the control winding and connected to it, according to the invention It is led cylindrical rod disposed concentrically about the core rod and connected with a closed magnetic circuit is formed in a cylindrical rod, at least one transverse gap, and the network coil is located on the cylindrical rod, where the length of the cross gap or total length of the transverse gaps formed satisfying the following condition:

where L _from - the length of the transverse clearance or the total length of several transverse gaps;

µ _r is the relative magnetic permeability of the material of the cylindrical rod;

- абсолютная магнитная проницаемость поперечного зазора;

- absolute magnetic permeability of the transverse clearance;

B _S - working induction of the material of the cylindrical rod;

L is the length of the cylindrical rod;

F is the magnetomotive force of the network winding.

Additional embodiments of the device are possible, in which it is advisable that:

- the width of the closed core magnetic core was made equal to the outer diameter of the cylindrical rod;

- the control unit was made on the basis of high voltage transistors.

These advantages, as well as features of the present invention are illustrated by the best option for its implementation with reference to the accompanying drawings.

Figure 1 depicts a circuit diagram of the claimed reactor;

figure 2 - schematically the location of the windings on the rods, front view;

figure 3 is the same as figure 2, a horizontal view.

The circuit diagram of the claimed controlled transformer type reactor (Fig. 1) corresponds to the equivalent control circuit of a shunt reactor using vacuum switches of the closest analogue, where 1 is the control winding, 2 is the network winding, 3 is the control unit. The control unit 3, however, in the claimed technical solution is made without the use of vacuum circuit breakers, but, for example, on high-voltage IGBT transistors.

The controlled reactor of the transformer type (figure 2, 3) contains a closed magnetic circuit 4, a central rod 5 located inside the closed magnetic circuit 4 and associated with it. The control winding 1 is located on the central rod 5. The network winding 2 is located coaxially outside relative to the control winding 1. The control unit 3 (not shown in FIGS. 2, 3) is configured to control the current of the control winding 1 and is connected to it (FIG. 1).

A cylindrical rod 6 is introduced, which is concentric with respect to the central rod 5 and connected at its ends with a closed magnetic circuit 4. At least one transverse gap 7 is made in the cylindrical rod 6, and the network winding 2 is located on the cylindrical rod 6. The length of the transverse gap or the total the length of the transverse clearances is made satisfying the condition:

where L _from - the length of the transverse clearance or the total length of several transverse gaps;

µ _r is the relative magnetic permeability of the material of the cylindrical rod;

- абсолютная магнитная проницаемость поперечного зазора;

- absolute magnetic permeability of the transverse clearance;

B _S - working induction of the material of the cylindrical rod;

L is the length of the cylindrical rod;

F is the magnetomotive force of the network winding.

To further reduce dimensions, the width S of the yoke of the closed magnetic circuit 4 can be made equal to the outer diameter D of the cylindrical rod 6 (Fig.3).

As noted earlier, to further improve performance, the control unit 3 is made on the basis of high-voltage transistors (Fig. 1).

A controlled transformer type reactor (Figs. 1-3) operates as follows.

When using the high-voltage transistor of the control unit 3 as the current control winding 1 controlling the current, the current in the control winding 1 and, accordingly, in the network winding 2 is almost instantaneous by changing the control signal of the transistor. When the control signal is zero, the current in the network winding 2 is minimal, while the reactor inductance is maximum. As the control signal increases, the current increases. When the transistor of control unit 3 is fully turned on, the current of network winding 2 is maximum (rated mode). In this case, the inductance of the reactor is minimal. The practical sinusoidality of the current in the control winding 1 reduces the appearance of higher harmonic components in the current of the network winding 2. Since the switching losses when the transistor of the control unit 3 is turned on are significantly less than that of a vacuum circuit breaker or thyristor, the power losses in the reactor are reduced.

From the general theory of transformers it is known that the inherent inductance of the reactor in nominal mode is determined by the magnitude of the magnetic flux in the region between the network winding 2 and the control winding 1. The magnitude of this flow is set by the magnetomotive force of the network winding 2, determined by the set reactor power, and the magnetic resistance of the gap between the network winding 2 and the control winding 1.

With the location of the control winding 1 and the network winding 2 on a solid central rod 5 (closest analogue design), the magnetic resistance R _{M of the} gap between the network winding 2 and the control winding 1 is defined as

where L * is the length of the central rod;

d _cf is the diameter of the circle dividing the gap between the network winding 2 and the control winding 1 in half;

α is the width of the gap between the network winding 2 and the control winding 1;

µ ₀ = 4π · 10 ^-7 GN / m (absolute magnetic permeability of the gap);

π = 3.14.

To ensure that the reactor can operate in nominal mode, R _M should be small enough, which is achieved in the closest analogue by increasing α. An increase in α leads to an increase in the internal diameter of the network winding 2 to a value significantly greater than that necessary for the dielectric strength between the network winding 2 and the control winding 1, and, accordingly, to an increase in the outer diameter of the network winding 2 and the dimensions of the device as a whole.

Due to the large distance of the network winding 2 from the yoke, the main part of the magnetic flux of the network winding 2 is sent to various structural elements of the controlled reactor, for example, tie rods with a jerk, the cover and walls of the transformer tank, and others. To direct this flow into yokes, ring magnetic shunts are used in the closest analogue, which complicate the design of the reactor.

In the present invention, the reduction of the magnetic resistance R _M is due to the fact that a cylindrical rod 6 is inserted, which is concentric with respect to the central rod 5 and connected with the closed magnetic core 4. At least one transverse gap 7 is made in the cylindrical rod 6, and the network winding 2 is located on a cylindrical rod. At the same time, there is no need to use a compensation winding and magnetic shunts. The transverse gap 7 can be made air or filled with a dielectric.

With this arrangement of the windings, the magnetic resistance of the gap (gap) between the control winding 1 and the network winding 2 is mainly determined by the magnetic resistance R ' _{M of the} cylindrical rod 6, which has the form:

,

,

where L is the length of the cylindrical rod 6;

L _from - the length of the transverse clearance or the total length of several transverse gaps;

d ' _cp is the diameter of the circle dividing the gap between the network winding 2 and the control winding 1 in half;

α 'is the width of the cylindrical rod;

µ _r is the relative magnetic permeability;

μ ₀ = 4π · 10 ^-7 GN / m (absolute magnetic permeability of the transverse gap).

Since μ _r > 1 for modern electrotechnical steels, the equality R _M = R ' _M is fulfilled for α'<α, which leads to a decrease in the diameter of the network winding 2 and, accordingly, to a decrease in the consumption of conductor material for its manufacture and to a decrease in power losses in the network winding 2 reactors.

Experimental studies have shown that in order to achieve the above results with sufficient accuracy for practical purposes the length _{of the} gap L chosen from the condition:

where L _from - the length of the transverse clearance or the total length of several transverse gaps 7;

µ _r is the relative magnetic permeability of the material of the cylindrical rod 6;

µ ₀ = 4π · 10 ^-7 GN / m (absolute magnetic permeability of the gap);

B _S - working induction of the material of the cylindrical rod 6;

L is the length of the cylindrical rod 6;

F - magnetomotive force of the network winding 2.

The values of µ _r and B _{S are} determined based on the magnetic properties of the material selected for the manufacture of the cylindrical rod, L is the specified voltage at the input of the network winding of the reactor, F is the specified nominal power of the reactor.

The length of the transverse clearance L _of is the main value that determines the implementation of a given nominal power of the reactor. The limits of variation of L _from obtained from the mathematical expression [1] are determined by the accuracy of the mathematical model underlying the calculation of the reactor.

Experimental studies have shown that when L changes _from in the range obtained from the mathematical expression [1], the rated power of the reactor changes by no more than 5%, which is permissible under operating conditions in power systems.

If the value obtained from the mathematical expression [1] is less than 0.8, then there is a rapid decrease in the rated power of the reactor. If this value is greater than 1.2, then the nominal power of the reactor increases too rapidly.

Structurally, the transverse gap 7 can be made air, or in the form of a dielectric washer (with one transverse gap 7), or in the form of a group of dielectric washers (with several transverse clearances 7) installed in the transverse planes of the cylindrical rod 6.

For the manufacture of a cylindrical rod 6 can be used, for example, composite soft magnetic powder material KMM-5 (the main magnetic properties of which are given in "Electrical Engineering", 1994, No. 8, p. 54), which has a high resistivity. Using this material, it is possible to obtain a transverse gap 7 in the form of uniformly distributed air gaps, which allows you to obtain the necessary air gaps without violating the geometric integrity of the cylinder of the rod 6. At the same time, a large value of the specific resistance of this material allows you to choose the distance between the network winding 2 and winding 1 control is very insignificant, as for a transformer of the same voltage class.

An example of a specific implementation of the invention.

For example, for a reactor (the main parameters of which are given in “Electricity”, No. 6, p. 20, 2005), the voltage of the network winding is 300 kV with a power of one phase P = 33.3 MW, the distance between the network winding 2 and winding 1 control is 0.391 m, while the outer diameter of the network winding 2 D ₀ = 2,37 m

The implementation of the reactor at the same voltage and power in accordance with the claimed technical solution allows to reduce the distance between the network winding 2 and the control winding 1 to 0.1 m, and the outer diameter of the network winding 2 to 1.5 m. The weight of the network winding 2 is reduced from 24.2 tons to 16.8 tons. Accordingly, the length of the middle turn of the network winding 2 decreases by a factor of 1.44, which leads to a decrease in its active resistance and an increase in efficiency. the reactor. The cylindrical rod 6 is made of electrical steel grade 3413 with a thickness of 0.35 mm, for which the working induction B _S = 1.5 T, the relative magnetic permeability µ _r = 1.3 · 10 ³ .

The height of the cylindrical rod 6 L = 2.34 m, the magnetomotive force of the network winding 2 F = 2.69 · 10 ³ A. Under these specified conditions, the value L _{from the} transverse clearance should be 0.176 m ≤ L _from ≤ 0.264 m.

The most successfully declared transformer type controlled reactor is industrially applicable in the field of electric power.

Claims (3)

1. Transformer-type controlled reactor containing a closed magnetic circuit, a central rod located inside the closed magnetic circuit and connected with it, a control winding located on the central rod, a network winding located coaxially outside relative to the control winding, and a control unit configured to control the winding current control and connected to it, characterized in that the entered cylindrical rod located concentrically relative to the Central rod and associated with a closed magnetic circuit is formed in a cylindrical rod, at least one transverse gap, and the network coil is located on the cylindrical rod, where the length of the cross gap or total length of the transverse gaps formed satisfying the following condition:

where L _from - the length of the transverse clearance or the total length of several transverse gaps;
µ _to - the relative magnetic permeability of the material of the cylindrical rod;
µ ₀ is the absolute magnetic permeability of the transverse gap;
B _S - working induction of the material of the cylindrical rod;
L is the length of the cylindrical rod;
F is the magnetomotive force of the network winding. 2. The reactor according to claim 1, characterized in that the width of the closed core magnetic core is made equal to the outer diameter of the cylindrical rod. 3. The reactor according to claim 1, characterized in that the control unit is based on high voltage transistors.

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