RU2217829C2 - Saturable reactor - Google Patents

Abstract

FIELD: electrical engineering that may be used in power lines for reactive power correction. SUBSTANCE: saturable reactor has magnetic system with intermediate legs, yokes, and two side yokes. Control windings disposed on intermediate legs are connected to regulated dc voltage supply. Power windings are disposed around two adjacent legs carrying control windings. Radially cut annular shunts are disposed between ends of windings and yokes. Each of them is wound on electric steel strips and has inserts of electric steel sheets whose width equals that of strip. Inserts are fitted between its layers. Annular shunts have their shape following that of cross-section of winding ends protruding beyond magnetic system outline. Ratio of minimal cross-sectional area of steel in each annular shunt to that of steel in each intermediate leg is between 1/8 and 1/4. Some portions of magnetic system yokes have different sectional areas of steel. Sectional area S of yoke parts disposed between adjacent legs enclosed by power winding and sectional area S_st of leg steel are interrelated by expression S:S_st = 1,5÷2. EFFECT: reduced current distortions by higher harmonics; reduced eddy-current losses. 2 cl, 3 dwg

Description

 The invention relates to the field of electrical engineering and can be used for magnetically controlled reactors installed, for example, in an electrical network to compensate for reactive power.

 Known electric reactor with magnetization [1], containing a magnetic system with middle rods, two yokes, with two side yokes. On the middle rods are placed control windings. On the middle rods there are also network windings covering the control windings. To increase reliability and increase speed between network windings of one phase, there are complex electrical reconnections. In addition to the complexity of the design, a drawback [1] is the increased consumption of basic materials - the conductive material of the network windings and the electrical steel of the magnetic system. In the analogue reactor [1] there are current distortions due to higher harmonics arising from the saturation of the sections with a jerk. In addition, large losses occur in the structural elements of the reactor due to eddy currents caused by the scattering field of the windings.

 Partially, the disadvantages [1] are eliminated in the known device [2], which is the closest in technical essence to the proposed invention. As in the analogue [1], in this prototype device there is a magnetic system with middle rods, two yokes, with two side yokes, control windings are placed on the rods. Unlike the analogue [1], there is not two, but one network winding, covering two adjacent rods with control windings, which allows to simplify the design and reduce material consumption. However, the device has distortion of the current due to higher harmonics arising from saturation of the sections with yarns, has increased eddy current losses arising in the structural elements due to the magnetic field of scattering.

 The aim of the invention is to reduce the distortion current by higher harmonics and to reduce eddy current losses arising in the structural elements due to the magnetic field of scattering due to the introduction of new structural elements - ring shunts of complex section, as well as due to the introduction of new size ratios between the sections of the core and the rods magnetic circuit.

This goal is achieved by the fact that in an electric reactor with magnetization, containing a magnetic system with middle rods, yokes, two side yokes, located on the middle rods of the control winding, connected to an adjustable constant voltage source, and network windings covering two adjacent rods with control windings included in the counter, characterized in that between the ends of the windings and yokes placed ring shunts with a radial cut, each of these ring shunts is wound of electrical steel tape and is equipped with inserts of electrical steel sheets, the width of which is equal to the width of the specified tape, the inserts are placed between its layers, and these 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 ratio of the minimum steel section of each annular shunt to the steel section of each middle rod is in the range from 1/8 to 1/4, the said yokes are made with sections of different steel sections, while the steel cross-sectional area S sections of the yoke located between adjacent rods covered by a network winding, and the area S _st section of the steel rods connected
S: S _st = 1.5 ÷ 2.

 Ring shunts can be made with axial cuts.

 The proposed electric reactor with magnetization is illustrated by drawings.

 In FIG. 1 shows the design of the magnetic system of the reactor with windings in section along the main axis, FIG. 2 shows a section of the reactor in plan view, and FIG. 3 shows a ring shunt in two projections.

 The magnetic system of the reactor contains rods 1, two yokes (horizontal) - upper 2 and lower 3, two side yokes 4. On all adjacent rods 1 there are control windings 5. In the reactor there are three (by the number of phases A, B and C) network windings 6, each network winding spans two adjacent terminals with control windings.

 At the ends of all windings, close to yokes 2 and 3, ring shunts 7, wound from electrical steel tape, have a radial cut 8. In FIG. 2 and 3 it can be seen that these 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 (these contours are lines with a hole 2 and 3 in the plan in Fig. 3 shown by dashed lines). In order to perform circular shunts of complex shape, when they are wound from electrical steel tape, inserts 9 of steel sheets of different lengths and with a width having a tape width are laid between the turns of the tape.

 Ring shunts can be made with axial cuts 10.

 For ease of execution and installation, for better cooling, the ring shunts can be solid or composite of two parts, in the latter case there is a channel 11 between these parts, which is shown in dashed lines in Figs. 1,2 and 3.

 The yokes 2 and 3 have sections 12 located between adjacent rods 1 covered by a network winding 6. These sections 12, in comparison with other sections of the yoke 2 and 3 and side yokes 4, have an enlarged steel section.

 The control windings, by means of which the reactor power is controlled by magnetizing the rods, are connected to an adjustable constant voltage source, and various options for connecting the control windings are possible. For example, each pair of control windings 5, covered by its network winding 6, can be connected in series in the opposite direction, and all 3 pairs of control windings of the three phases of the reactor can be connected in parallel.

 Network windings 6 of three phases can be connected to a star with zero (or to another three-phase circuit) and connected to a three-phase AC voltage network.

 An electric magnetization reactor, made in accordance with the claims of the invention, operates as follows.

When the windings 6 are connected to an alternating current electric network and the regulated constant current source is switched off, two adjacent rods 1 have the same magnitude and direction of alternating magnetic fluxes with amplitude Ф _m , closing through yokes 2 and 3 and side rods 4 of the magnetic system. The amplitude of the fluxes Ф _{m is} approximately equal to the saturation flux of the rods Ф _s (this corresponds to the most rational use of steel rods), and there is no constant magnetic flux. In all sections of the magnetic system (rods and all yokes), the total flux does not exceed the saturation flux Ф _s (equal to the saturation induction of steel multiplied by the steel cross-section); therefore, the reactor current is almost very small. This mode of operation of the reactor is called idle.

Reactor power is controlled by connecting an adjustable constant voltage source, such as an adjustable converter (rectifier) to the magnetizing control windings. When the rectifier is connected to the control windings, a current arises in them, which leads to the appearance and increase of the bias flux Φ ₀ (constant component in the flow curve). In neighboring rods, this flow Φ _{0 is} directed in different directions (due to the on-off switching of the control windings), therefore, it closes mainly along the shortest path through sections of the yoke 12 located between the rods 1 of one phase. Since a variable flux Ф _{s is} superimposed on the magnetization flux Ф ₀ , the resulting flux begins to shift to the steel saturation region, i.e. the rods are saturated for some part of the period. In turn, the saturation of the rods leads to the appearance and increase of current in the network winding 6. With an increase in the constant voltage on the control winding 5, the bias flux increases, the time intervals inside each period when the rod is in a saturated state increase (i.e., when the rod flux more saturation flux Ф _s ), in accordance with this, the mains current also increases. There is a special intermediate mode in which the magnetization flux Ф ₀ becomes equal to the amplitude of the variable magnetic flux Ф _m . This mode is characterized by the fact that the saturated state time of the rods is the same and equal to half the sinusoid period, and due to the different directions of the variable flux Ф _m and the constant flux Ф ₀ in the rods covered by the network winding, one half of the period is saturated with one rod and the other with the other. This mode is called the half-period saturation mode. In this mode, higher harmonics are practically absent in the reactor current, and the current has a purely sinusoidal shape, so the magnetization controlled reactor is designed so that its nominal mode is close to the half-period saturation mode.

After reaching such a state when the magnetic flux of the rod for the entire period is equal to or greater than the saturation flux, the mains current reaches the maximum possible value and does not increase any further, because differential magnetic permeability of saturated steel becomes close to vacuum permeability. In this mode, called the full-cycle saturation mode, the reactor becomes a linear inductance, there are almost no higher harmonics in the current. However, this mode is characterized by a large current in the control windings, i.e., large losses in these windings. Therefore, this mode is used as a short-term power boost mode. In this full-period saturation mode, the magnetic flux in the portion of the yoke 12 between the rods 1 of each phase becomes very large, since the magnetization flux Φ ₀ increases to the amplitude of the variable magnetic flux Φ _m . However, these sections 12 have an increased cross-sectional area, so they are not saturated, and the reactor current remains not distorted, purely sinusoidal. Such distortions would occur if the yokes did not have sections of an enlarged section (as in the prototype). Additional calculations showed that the increase in cross-section should be at least 1.5-fold with respect to the cross-sectional area of the steel of rod 1, because with a smaller area, the distortions in the network current of the reactor become more than acceptable. An increase of more than 2 times is also not rational, since the magnetic flux in these areas does not exceed the double flux Φ _m .

 When the reactor is operating, the current of the windings outside the steel (in the region of the windings) creates a scattering magnetic field. This scattering field has a maximum induction in the middle of the height of the windings, and it closes outside the windings, passing mainly through the ends of the windings. If the scattering field is not “directed” by certain structural measures, then it “breaking out” will induce eddy currents in all metal components of the structure (pressing beams, yokes, tank walls, etc.). These eddy currents will lead to a significant increase in power losses in the reactor, to dangerous local heating. For powerful reactors, they threaten their complete inoperability. Ring shunts mounted on the ends of the windings concentrate the scattering field. The scattering field enters the annular shunt, passes along sheets of steel (along sheets of tape) and passes into the yoke through the gap under the yoke. Ring shunts have a complex shape in order to "overlap" the ends of the windings protruding beyond the contour of the magnetic system (contour with a jerk). The magnetic flux scattered in the ring shunt is maximal in the shunt section at the level of the yoke line, because up to this line, the magnetic flux of scattering only accumulates, and beyond this line it begins to turn into a yoke. In the same region, the cross section of the steel ring shunt is minimal. Additional calculations showed that, depending on the ratio of the geometric dimensions of the windings and the magnetic system, the concentrated magnetic flux is 1/8 - 1/4 of the magnetic flux of the middle rod, therefore, the minimum cross-sectional area of the steel ring shunt relative to the cross-sectional area of the steel of the middle rod same range. If the cross-sectional area is less than the minimum, then the shunt steel is saturated, leading to an unfavorable redistribution of the magnetic flux between the layers, an increase in losses and heating. An increase in the cross section above the upper boundary is irrational due to an excess increase in the mass of steel shunts.

 The scattering magnetic field in the radial direction is not uniform, therefore, there are magnetic field flows between the layers of the ring shunt. In this case, due to the magnetic flux, eddy currents appear across the steel strip, leading to large losses and heating. In order to reduce losses and heat ring shunts, they are performed with axial cuts. A radial section of the ring shunt is necessary so that there is no short-circuited circuit covering the main magnetic flux of the network winding.

 In addition to the three-phase version, a single-phase version of the design is possible, while all the structural elements of the three-phase reactor are saved, but the number of rods and windings is accordingly reduced.

 The performance of the proposed bias-controlled electric reactor and its high technical and economic indicators are confirmed by calculations and physical modeling. Compared with the analogue and prototype, the present invention has a clear advantage - improving the shape of the current curve, reducing losses, as well as the consumption of materials.

Literature
1. An electric reactor with magnetization. RF patent 1762322, H 01 F 29/14. Bulletin of inventions 34 1992

 2. Core for electrical apparatus. Paul A. Vanse. U.S. Patent 2,287,382. Application Juli 23, 1940, Serial No. 346,904. Patendet Dec. 23, 1941.

Claims (2)

1. An electric magnetization reactor containing a magnetic system with middle rods, yokes, two side yokes, located on the middle rods of the control winding, connected to an adjustable constant voltage source, and network windings spanning two adjacent rods with control windings turned on, different the fact that between the ends of the windings and yokes placed ring shunts with a radial cut, while each of these ring shunts is wound from tape of electrical steel and sleep wives are inserts from sheets of electrical steel, the width of which is equal to the width of the specified tape, the inserts are placed between its layers, and these 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 ratio of the minimum steel section of each ring shunt to the steel section each middle rod is in the range from 1/8 to 1/4, the mentioned yokes are made with sections of different steel sections, while the section area S of the steel sections of the yoke located between the these rods covered by the network winding, and the area S _CT-section steel rods connected by the relation S: S _v = 1,5 ÷ 2. 2. The electric reactor with magnetization according to claim 1, characterized in that the ring shunts have axial sections.

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