JP2010239862A - Turbine generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve a turbine generator, by overcoming the problem wherein a rotation shaft is required to have an overhang for attachment of a power generator for an alternating current exciter, so that the axial length increases, and the overhang causes shaft vibrations. <P>SOLUTION: The turbine generator has a rotor with a field winding, and includes, on a rotor shaft, a coupling that is integrally cut with the rotor shaft, an alternating current exciter that provides direct current to the field winding via a rectifying device, and a power generator for the alternating current exciter that provides direct current to the field winding of the alternating current exciter via a rectifier using a permanent magnet as a field generating source. The rotor rotates as a result of contact between a steam turbine or a gas turbine serving as a motor and the coupling. In the turbine power generator, an attaching position of the power generator for the alternating current exciter is set closer to the turbine side than a turbine generator stator. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a turbine generator having a brushless excitation type excitation device.

  As a conventional turbine generator having a brushless excitation type excitation device, as shown in Japanese Patent Publication No. 2003-515308 as a conventional technique, an AC exciter and a sub-exciter are provided at the shaft end opposite to the turbine. Attached is known.

Special table 2003-515308 gazette

  In the configuration according to the above-described conventional technology, the auxiliary exciter is attached with an overhang of the rotating shaft, which increases the shaft length. This overhang also causes shaft vibration.

  A feature of the present invention is that a turbine generator stator provided with an armature winding, a turbine generator rotor provided with a field winding, and a DC current are supplied to the field winding via a rotary rectifier. And an auxiliary exciter that supplies a direct current to a field winding of the AC exciter through a rectifier using a permanent magnet as a field generation source, and the turbine generator rotor is rotated by a turbine. In the turbine generator, the rotor of the auxiliary exciter is that the permanent magnet is disposed between the pole shoe and the rotating shaft.

  The present invention shortens the shaft end overhang of the turbine generator, which contributes to miniaturization of the turbine generator and suppression of shaft vibration.

1 is a diagram showing Embodiment 1 of the present invention. The figure which shows Embodiment 2 of this invention. The figure which shows Embodiment 3 of this invention. The figure which shows Embodiment 4 of this invention. The figure which looked at the site | part of FIG. 4 from the turbine side to the axial direction. The figure which shows Embodiment 5 of this invention. The figure which shows Embodiment 6 of this invention. Radial direction sectional drawing of FIG. The figure which shows the relationship between an air gap and permanent magnet temperature. The figure which shows the relationship between the distance of a pole shoe and a rotor axis | shaft, the ratio of an air gap, and an induced voltage. The figure which shows the relationship between the ratio of magnet thickness and an air gap, and an induced voltage. The figure which shows the turbine generator which has the conventional brushless excitation system excitation apparatus. The circuit block diagram which shows a brushless excitation system.

FIG. 11 shows an example of a turbine generator having a brushless excitation type excitation device of a comparative example for explaining the effect of the present invention. The turbine generator has an AC exciter 4 and a sub-exciter 5 in the overhang portion of the turbine generator rotor shaft end. The secondary exciter 5 has a permanent magnet 13 as a rotor magnetic pole. The permanent magnet 13 creates a field perpendicular to the armature winding 8 of the secondary exciter, which rotates as the rotary shaft 1 rotates. Then, an alternating current I _a1 is induced in the armature winding 8 by electromagnetic induction. The automatic voltage regulator 16 having a rectifying function detects the generator voltage, converts this alternating current I _a1 into a direct current I _d1 , and supplies it to the field winding 18 of the alternating current exciter. The armature winding 19 of the AC exciter is attached to the rotor 20 of the AC exciter, and an AC current I _a2 is induced in the armature winding 19 by the rotation of the rotating shaft 1. The alternating current I _a2 is converted into direct current through the rotary rectifier 17 and supplied to the turbine generator field winding 21. By the rotation of the rotating shaft, an alternating current is induced in the turbine generator armature winding 22, and power can be supplied to the outside. In FIG. 12, the example of the circuit block diagram which shows the brushless excitation system of a comparative example is shown.

  Hereinafter, embodiments of the present invention will be described based on examples.

  FIG. 1 shows Embodiment 1 of the present invention. The rotor shaft 1 is connected to the turbine by a coupling 3. The sub exciter 5 is attached to the turbine side from the stator 2, and the AC exciter 4 is attached to the shaft end opposite to the turbine.

  Thus, by attaching the sub exciter on the turbine side, the overhang required for the permanent magnet installation can be shortened.

  FIG. 2 shows a second embodiment of the present invention. By attaching the auxiliary exciter between the turbine side bearing 6 holding the rotating shaft 1 and the coupling 3, the overhang required for attaching the auxiliary exciter can be shortened.

  FIG. 3 shows a third embodiment of the present invention. When a sub-exciter having a ring-shaped rotor on the turbine side is attached by shrink fitting to the rotor shaft in a turbine generator having a coupling that is integrally cut from the rotor shaft, the rotor inner diameter of the sub-exciter is It must be larger than the coupling outer diameter. Therefore, as shown in FIG. 3, a pedestal portion having a diameter larger than that of the coupling 3 is cut out from the rotating shaft, so that the ring-shaped rotor can be shrink fitted.

  4 and 5 show Embodiment 4 of the present invention. Since the rotor of the secondary exciter is installed on the rotating shaft of the turbine generator that rotates at high speed, the increase in the outer diameter increases the centrifugal force.

  Therefore, as shown in FIGS. 4 and 5, if the stator 7 of the auxiliary exciter equipped with the armature winding 8 can be divided in the circumferential direction and the magnetic pole 23 is directly attached to the rotating shaft, the cup Attachment is possible even with a stator inner diameter smaller than the outer diameter of the ring 3. 4 is a diagram viewed from the radial direction, and FIG. 5 is a diagram viewed from the turbine side in the axial direction.

FIG. 6 shows a fifth embodiment of the present invention. FIG. 6 shows a half of the divided stator. The armature windings 8a and 8b of the sub exciter are wound around one tooth 10 of the stator core 9 of the sub exciter. Similarly, the armature windings housed in the other slots are concentratedly wound.
As a result, the stator 7 of the auxiliary exciter can be divided in the circumferential direction at any slot 11.

  7 and 8 show a sixth embodiment of the present invention. FIG. 7 shows an axial cross section of a sub-exciter magnetic pole provided in the turbine generator of the present invention. A permanent magnet 13 is attached between the rotary shaft 1 and the pole shoe 12, and the permanent magnet 13 is covered with a magnet cover 14 using a nonmagnetic material to prevent scattering. The magnet cover 14 is made non-magnetic to prevent a short path of magnetic flux from the pole shoe 12 to the rotating shaft 1.

In FIG. 7, the minimum gap between the stator 7 and the rotor of the sub-exciter is G _a (mm) is 5 mm or more, and heat generation due to eddy current loss on the surface of the pole shoe 12 is prevented. The distance G _p (mm) between the pole shoe 12 and the rotating shaft 1 and the thickness G _m (mm) of the permanent magnet 13 are both 0.9 <G _p / G _a and 0.9 <G _m / G. We are satisfied _a. Thereby, leakage of magnetic flux from the pole shoe 12 to the rotor shaft 1 is prevented.

FIG. 9 shows an analysis result representing the relationship between the gap G _a and the permanent magnet temperature T. T ₀
Indicates the irreversible demagnetization temperature of the permanent magnet, for example, about 90 ° C. to 220 ° C. for a neodymium magnet. According to this, the permanent magnet can be used without thermal demagnetization by setting the gap to 5 mm or more.

FIG. 10 shows an analysis result representing the relationship between the induced voltage V G _p / G _a and the sub-exciter. According to this, if G _p / G _a is smaller than 0.9, although the induced voltage by the magnetic flux leakage from the pole shoe to the rotor shaft is decreased, by 0.9 or more G _p / G _a In this case, it is possible to prevent the induced voltage from decreasing. Further, FIG. 11 shows an analysis result representing the relationship between the induced voltage V G _m / G _a and the sub-exciter. As shown in this figure, by setting the thickness of the magnet to satisfy 0.9 <G _m / Ga, _a magnetic gap is not formed around the magnet, and a decrease in induced voltage can be prevented.

  FIG. 8 shows a radial cross section of a sub-exciter magnetic pole provided in the turbine generator of the present invention. The pole shoe 12 is longer in the axial direction than the permanent magnet 13, and a bolt hole is provided in the axially extending portion and is tightened by a nonmagnetic bolt 15. By making the hole position for bolt attachment an axially extended portion, it is possible to perform attachment using a bolt without providing a hole in the magnet and without disturbing the main magnetic flux in the pole shoe. Further, by using a non-magnetic bolt, a short path of magnetic flux from the pole shoe to the rotor shaft is prevented.

Configurations that can be considered as embodiments of the present invention are listed below.
(1) A rotor having a field winding, a coupling integrally cut with the rotor shaft, an AC exciter that supplies a DC current to the field winding via a rotary rectifier, Steam that serves as a prime mover is provided on the rotor shaft with a secondary exciter that supplies a direct current to the field winding of the AC exciter via an automatic voltage regulator having a rectifying function using a permanent magnet as a field generating source. A turbine generator in which a rotor rotates by coupling with a turbine or a gas turbine, wherein the attachment position of the sub-exciter is attached to the turbine side from the turbine generator stator.
(2) The turbine generator according to (1), wherein the attachment position of the sub-exciter is between the coupling and the turbine-side bearing.
(3) In the turbine generator of (1) or (2), the stator of the auxiliary exciter can be divided in the circumferential direction, and the stator inner diameter of the auxiliary exciter is made smaller than the outer diameter of the coupling A turbine generator characterized by that.
(4) The turbine generator according to (1) or (2), wherein the armature winding of the auxiliary exciter is concentrated winding.
(5) The turbine generator according to (1) or (2), wherein a permanent magnet that is a field generation source of the sub-exciter is a rare earth permanent magnet.
(6) The turbine generator according to (1) or (2), wherein the permanent magnet of the auxiliary exciter is directly attached to the turbine generator rotor shaft.
(7) The turbine generator according to (6), wherein the permanent magnet of the auxiliary exciter is attached between a pole shoe and a turbine generator rotor shaft.
(8) The turbine generator according to (6), wherein the permanent magnet of the auxiliary exciter is a magnetized permanent magnet.
(9) The turbine generator according to (6), wherein a cover using a nonmagnetic material is attached to the permanent magnet of the auxiliary exciter.
(10) The turbine generator according to (7), wherein a pole shoe of the auxiliary exciter is fastened and attached with a non-magnetic bolt.
(11) In the turbine generator according to (10), the length of the auxiliary exciter in the pole shoe axial direction is longer than the length in the permanent magnet axial direction, and a bolt hole is provided in the extended portion. .
(12) In the turbine generator of (7), the minimum gap between the auxiliary exciter stator and the rotor is 5 mm or more.
(13) In the turbine generator of (7), when the minimum gap between the auxiliary exciter stator and the rotor is G _a (mm) and the distance between the pole shoe and the rotor shaft is G _p (mm) , 0.9 <G _p / G _a is satisfied.
(14) In the turbine generator of (7), when the minimum gap between the auxiliary exciter stator and the rotor is G _a (mm) and the thickness of the permanent magnet is G _m (mm), 0.9 < turbine generator, characterized by satisfying the G _m / G _a.

  DESCRIPTION OF SYMBOLS 1 ... Rotary shaft, 2 ... Stator, 3 ... Coupling, 4 ... AC exciter, 5 ... Sub exciter, 6 ... Bearing, 7 ... Stator of sub exciter, 8 ... Armature winding of sub exciter 8a ... Armature winding a of the secondary exciter, 8b ... Armature winding b of the secondary exciter, 9 ... Rotor of the secondary exciter, 10 ... Teeth, 11 ... Slot, 12 ... Pole shoe, 13 ... Permanent Magnets 14 ... Magnet covers 15 ... Non-magnetic bolts 16 ... Automatic voltage regulators 17 ... Rotary rectifiers 18 ... Field windings of AC exciters 19 ... Armature windings of AC exciters 20 ... AC exciter rotor, 21 ... generator armature winding, 22 ... generator field winding, 23 ... sub-exciter magnetic pole.

Claims (5)

A turbine generator stator having an armature winding, a turbine generator rotor having a field winding, an AC exciter for supplying a DC current to the field winding via a rotary rectifier, A turbine generator in which a permanent magnet is used as a field generation source and a sub-exciter that supplies a direct current to a field winding of the AC exciter through a rectifier, and the turbine generator rotor is rotated by a turbine. ,
The rotor of the sub-exciter is a turbine generator in which the permanent magnet is disposed between a pole shoe and a rotating shaft. The turbine generator according to claim 1, wherein
The said permanent magnet is covered with the magnet cover which consists of nonmagnetic materials, The turbine generator characterized by the above-mentioned. The turbine generator according to claim 1 or 2,
The pole shoe has an extension portion longer than the axial length of the permanent magnet, a bolt hole is provided in the extension portion, and the pole shoe is fixed to the rotating shaft by a bolt passed through the bolt hole. Turbine generator characterized by The turbine generator according to claim 1, wherein
A turbine generator having a minimum gap of 5 mm or more between a stator and a rotor of the sub-exciter. The turbine generator according to claim 1, wherein
The minimum gap G _a of the stator and the rotor of the sub-exciter, when the thickness of the permanent magnet and the G _m, a turbine generator being characterized in that a 0.9 <G _m / G _a.

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