JP2019041441A - Generator overexcitation monitoring device, generator and generator operating method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily prevent a generator from being overexcited. An overexcitation monitoring device for a generator according to an embodiment is disposed on a back surface of a stator core of a generator or at a position away from the back surface by a magnetic flux that leaks to an outer diameter side of the stator core. And a measuring device 10 for measuring the output voltage of the search coil 6, the measuring device 10 being measured during load operation of the generator. And a means for outputting a predetermined signal when the output voltage of 6 is equal to or higher than a predetermined threshold. [Selection] Figure 1

Description

  Embodiments described herein relate generally to a generator overexcitation monitoring device, a generator, and a method for operating the generator.

  When the synchronous generator is overexcited, the amount of magnetic flux increases and the saturation of the magnetic circuit becomes significant.

  When magnetic saturation in the stator core becomes significant, magnetic flux leaks to the outer diameter side of the stator core due to magnetic saturation of the stator core. When the leaked magnetic flux enters a nearby structure, local overheating due to eddy current may occur. This local overheating can cause significant damage to the stator core and armature windings of the synchronous generator. Therefore, it is important to monitor the overexcitation state.

  Conventionally, a method for detecting an overexcitation state of a synchronous generator by monitoring a ratio between a terminal voltage and a frequency of the synchronous generator is known. This technique uses the relationship that the amount of magnetic flux of each pole increases when the terminal voltage becomes higher than the rated voltage or when the frequency becomes lower than the rated frequency. However, since this method does not monitor the leakage magnetic flux of the stator core itself, it is not known whether the stator core is actually magnetically saturated and the magnetic flux leaks to the outer diameter side of the stator core.

  On the other hand, a magnetic flux detector (such as a search coil) that detects leakage magnetic flux is provided at a predetermined position in the stator core back space of the generator, and the leakage magnetic flux density obtained by calculating from the output signal of this magnetic flux detector is calculated. A technique for detecting the overexcitation state of the generator by doing so is known.

JP-A-5-316800 JP 2004-350353 A

  In the method for detecting the overexcitation state of the generator by calculating the leakage magnetic flux density described above, a circuit for calculating the leakage magnetic flux density and a circuit for determining the overexcitation state from the calculated leakage magnetic flux density are newly added. Therefore, it takes time to manufacture the overexcitation monitoring device, which increases the cost. Moreover, since the distribution characteristics of the leakage magnetic flux density are different for each generator, it is not easy to appropriately set the threshold value of the leakage magnetic flux density that is a criterion for overexcitation for the target generator.

  The problem to be solved by the invention is to provide an overexcitation monitoring device, a generator, and a method for operating the generator, which can easily prevent the generator from being overexcited.

  The generator overexcitation monitoring device according to the embodiment is arranged at the back surface of the stator core of the generator or at a position away from the back surface by a certain distance, and the voltage according to the magnetic flux leaking to the outer diameter side of the stator core And a measuring device for measuring the output voltage of the search coil, wherein the measuring device has an output voltage of the search coil measured during a load operation of the generator equal to or higher than a predetermined threshold value. Means for outputting a predetermined signal when

  Further, the generator operating method according to the embodiment is such that the stator core is operated during load operation of the generator by a search coil arranged at a back face of the stator core of the generator or at a position away from the back face by a search coil. Outputs a voltage according to the magnetic flux leaking to the outer diameter side, and the voltage output by the search coil is acquired in the range where the terminal voltage of the generator exceeds the rated value during the no-load saturation characteristic test of the generator. Outputting a predetermined signal when a predetermined threshold value or more based on the output voltage of the search coil is reached.

  According to the present invention, the generator can be prevented from being overexcited.

The figure which shows the one part schematic structure of the synchronous generator to which the overexcitation monitoring apparatus which concerns on one Embodiment is applied. The figure which shows a mode that the structure containing the search coil 6 was seen horizontally from the direction orthogonal to the axial direction of the stator core 1 in the example of the 1st installation of the search coil 6. FIG. The figure which shows a mode that the structure containing the search coil 6 was seen horizontally from the axial direction of the stator core 1 in the example of the 1st installation of the search coil 6. FIG. The figure which shows a mode that the structure containing the top member 9 to which a search coil is attached was seen from the outer diameter side of the stator core 1 in the example of the 2nd installation of the search coil 6. FIG. In the example of the second installation of the search coil 6, a state in which the top member 9 disposed on the back surface of the stator core 1 and the search coil 6 disposed thereon are viewed horizontally from the axial direction of the stator core 1. FIG. The figure which shows a mode that the search coil 6 was seen from the outer diameter side of the stator core 1 in the example of the 3rd installation of the search coil 6. FIG. The figure which shows a mode that the search coil 6 arrange | positioned in the back surface of the stator core 1 was seen horizontally from the axial direction of the stator core 1 in the example of the 3rd installation of the search coil 6. FIG. The figure which shows the structure containing the overexcitation monitoring apparatus and related apparatus group which concern on this embodiment. The figure which shows the function structure of the measuring device. The figure for demonstrating the example of the setting of the threshold value used as the determination criterion of overexcitation.

  Hereinafter, embodiments will be described with reference to the drawings.

(Overall configuration)
FIG. 1 is a diagram illustrating a partial schematic configuration of a synchronous generator (hereinafter, referred to as “generator”) to which an overexcitation monitoring apparatus according to an embodiment is applied. FIG. 1 shows a state in which a part of the generator is viewed horizontally from a direction orthogonal to the axial direction of the stator core 1.

  As shown in FIG. 1, the generator has a stator core 1. The stator core 1 is provided with a structure 3 that supports the stator core 1 in the axial direction, and various frame structures 4 are provided on the outer diameter side of the stator core 1. Yes.

  The stator iron core 1 has iron plates that are arranged in a plurality of stages in the axial direction. Between the adjacent iron plates and the iron plate, and between the outermost iron plate and the structure 3, a duct 5 for ventilation is provided. Exists.

  In the present embodiment, a search coil 6 for measuring leakage magnetic flux is provided inside the generator, and a measuring device 10 is provided outside the generator. The overexcitation monitoring device according to the present embodiment includes at least the search coil 6 and the measurement device 10.

  The search coil 6 and the measuring device 10 may be installed at the time of manufacture of the generator, but may be installed at the time of periodic inspection after the generator is installed at the power plant (including during the no-load saturation characteristic test). Also good. At that time, a cable (not shown) electrically connected from the search coil 6 to the measuring device 10 is also arranged so that the output voltage of the search coil 6 in the machine can be measured outside the generator. The search coil 6 and the measuring device 10 are used during a no-load saturation characteristic test, and are also constantly used during normal load operation.

  The search coil 6 includes a coil made of a conductor, and outputs a current / voltage corresponding to the magnetic flux leaking to the outer diameter side of the stator core 1. The search coil 6 may be configured, for example, by providing a coil on or in a base made of a nonmagnetic insulating material.

  The measuring device 10 has a function of measuring the relationship between the terminal voltage of the generator and the field current during the no-load saturation characteristic test, and also measures the output voltage of the search coil 6 during the measurement. It has a function. The measuring device 10 also has a function of setting a threshold value (alarm value or the like) based on the value of the output voltage of the search coil 6 as a criterion for overexcitation based on those measurement results, or during load operation of the generator. A function for measuring the output voltage of the search coil 6, a signal indicating an alarm when the output voltage of the search coil 6 exceeds the threshold value during load operation of the generator, and / or the output voltage of the search coil 6 and the generator And a function of outputting a signal indicating the terminal voltage to the outside.

  The search coil 6 is provided in a space 2 on the outer diameter side of the stator core 1 (hereinafter referred to as “stator core outer diameter side space 2”), and specifically, the back surface of the stator core 1 or the back surface thereof. It is provided at a position away from a certain distance. In order to detect the leakage magnetic flux with the highest possible sensitivity, as shown in the example of FIG. 1, the outermost end of the stator core 1 (the iron plate closest to the structure 3 side) where the leakage magnetic flux tends to concentrate is provided. It is desirable to install the search coil 6 on the back surface. However, it is not limited to this example.

  Some examples of installation of the search coil 6 are given below.

(Example of first installation)
2 and 3 are diagrams showing an example of the first installation of the search coil 6. FIG. FIG. 2 shows a state in which the configuration including the search coil 6 is viewed horizontally from a direction orthogonal to the axial direction of the stator core 1. FIG. 3 shows a state in which the configuration including the search coil 6 is viewed horizontally from the axial direction of the stator core 1. In addition, the same code | symbol is attached | subjected to the element which is common in FIG.

  The first installation example is based on the premise that the structure 4 a exists on the outer diameter side of the stator core 1.

  In the example of this first installation, in the stator core outer diameter side space 2 around the stator core 1, the back surface of the stator core 1 and the structure 4a on the outer diameter side of the stator core 1 The member 7a, the search coil 6, and the wedge 7b are respectively inserted in the axial direction of the stator core 1 from the axial center portion side of the stator core 1 toward the structure 3 side, and the structure 4a. The search coil 6 is fixed using the reaction force of.

  Specifically, a member 7a for filling the gap is inserted between the back surface of the stator core 1 and the structure 4a on the outer diameter side of the stator core 1, and the member 7a and the stator core 1 are The search coil 6 is inserted between the back surface and a wedge 7b is inserted between the search coil 6 and the member 7a in the axial direction of the stator core 1 so that the search coil 6 is fixed. Yes.

  A stepped portion 7c is provided on the upper portion of the member 7a. Further, a stepped portion similar to the stepped portion 7c on the member 7a side is provided in a part of the structure 4a. Therefore, when the member 7a is inserted in the axial direction of the stator core 1 between the back surface of the stator core 1 and the structure 4a, the stepped portion 7c on the member 7a side corresponds to the structure 4a side. It abuts on the stepped portion and stops in a state where the member 7a is inserted to an appropriate place without the member 7a proceeding too far. Therefore, the worker can easily insert the member 7a to an appropriate position without being particularly aware of how far the member 7a should be inserted.

  Also, a stepped portion is provided at the lower portion of the member 7a. Therefore, when the search coil 6 is inserted in the axial direction of the stator core 1 between the member 7a and the back surface of the stator core 1, a stepped portion in which the end of the search coil 6 is located below the member 7a. The search coil 6 does not advance too far and stops with the search coil 6 inserted to an appropriate position. Therefore, the worker can easily insert the search coil 6 to an appropriate position without being particularly aware of how much the search coil 6 should be inserted.

  Further, since there is a space according to the shape and size of the wedge 7b between the inserted member 7a and the search coil 6, an operator can insert the wedge 7b without damaging the search coil 6. Can do.

  The insertion depth of the wedge 7b can be adjusted, whereby the search coil 6 can be pressed against the back surface of the stator core 1 with an appropriate force.

  For example, in the case where the target generator is already installed in the power plant, it may be difficult to obtain accurate dimensional information such as the distance between the back surface of the stator core 1 and the structure 4a. Although a dimensional error may occur more or less when the 7a and the search coil 6 are inserted, loosening due to the dimensional error is eliminated by adjusting the insertion depth of the wedge 7b, and the search coil 6 is It can be pressed against the back surface of the stator core 1 with an appropriate force.

  Note that one or a plurality of search coils 6 may be installed. Further, the number of members 7a and wedges 7b to be installed may be one or plural.

  In the example of FIG. 3, a set of a plurality of members 7 a and wedges 7 b is used for one search coil 6. By using a set of a plurality of members 7a and wedges 7b, the entire search coil 6 can be pressed evenly against the back surface of the stator core 1 while being curved along the back surface of the stator core 1. The detection accuracy of the leakage magnetic flux can be improved.

  The distance from the back surface of the stator core 1 to the structure 4 a is not necessarily uniform in the circumferential direction of the stator core 1. In this example, even if the distance from the back surface of the stator core 1 to the structure 4a is not uniform in the circumferential direction of the stator core 1, by adjusting the insertion depth of each of the plurality of wedges 7b individually, The entire search coil 6 can be evenly pressed against the back surface of the stator core 1 with an appropriate force.

(Example of second installation)
4 and 5 are diagrams showing an example of the second installation of the search coil 6. FIG. FIG. 4 shows a state in which the structure including the top member 9 to which a search coil (not shown) is attached is viewed from the outer diameter side of the stator core 1. FIG. 5 shows a state in which the top member 9 disposed on the back surface of the stator core 1 and the search coil 6 disposed thereon are viewed horizontally from the axial direction of the stator core 1. In addition, the same code | symbol is attached | subjected to the element which is common in FIG.

  On the back surface of the stator core 1, groove-shaped dovetail portions 8 exist at regular intervals in the circumferential direction of the stator core 1. The dovetail portion 8 is provided to attach the rib (key bar) 3a that supports the stator core 1, but the rib 3a is not attached to all the dovetail portions 8. The ribs 3a are attached to the dovetail portion 8 at regular intervals in the circumferential direction of the stator core 1, but there are also unused dovetail portions 8 to which the rib 3a is not attached.

  In this example, the top member 9 on which the search coil 6 is placed is detachably attached to at least one of the unused dovetail portions 8. The search coil 6 is placed on the top member 9 in such a manner that the search coil 6 is curved along the back surface of the stator core 1 using, for example, an adhesive or an adhesive tape. This is realized. The search coil 6 may be placed on the top member 9 after the top member 9 is attached to the dovetail portion 8 or before the top member 9 is attached to the dovetail portion 8.

  The top member 9 is attached to the dovetail part 8 located at the endmost part (iron plate closest to the structure 3 side) of the stator core 1, for example. The top member 9 has a portion that fits with the dovetail portion 8 in accordance with the shape of the dovetail portion 8, and is inserted into the dovetail portion 8 through a space such as the duct 5, or is pulled out from the dovetail portion 8. be able to.

  A plurality of the piece members 9 may be arranged in series. In that case, a single search coil 6 may be placed on the piece members 9 arranged in a plurality, or a plurality of search coils 6 may be placed.

  The height at which the search coil 6 is disposed (the position in the outer diameter direction of the stator core 1) is preferably as close as possible to the height of the back surface of the stator core 1, and for that purpose, the height of the piece member 9 is set. It is desirable that (the length from the back surface of the stator core 1 to the surface on which the search coil 6 is disposed) be as small as possible.

  Since the top member 9 to which the search coil 6 is attached is detachable from the dovetail portion 8, the search coil 6 can be easily inspected and replaced, and high maintainability can be realized. Can do. Further, since the top member 9 to which the search coil 6 is attached can be easily disposed at an appropriate position simply by being fitted into the dovetail portion 8, workability at the time of installing the search coil 6 can be improved.

(Example of third installation)
FIGS. 6 and 7 are diagrams showing a third installation example of the search coil 6. FIG. 6 shows the search coil 6 as viewed from the outer diameter side of the stator core 1. FIG. 7 shows a state in which the search coil 6 disposed on the back surface of the stator core 1 is viewed horizontally from the axial direction of the stator core 1. In addition, the same code | symbol is attached | subjected to the element which is common in FIG.

  The search coil 6 is realized in a form equivalent to, for example, a film-like printed wiring board, and has a layer in which a coil pattern 6b made of a conductor such as copper is formed on or in a base 6a made of an insulator. The said layer may be comprised only by one layer, and may be comprised by the multilayer. A plurality of such search coils 6 may be installed.

  The search coil 6 is installed by, for example, attaching the search coil 6 to the back surface of the stator core 1 in a state where the search coil 6 is curved along the back surface of the stator core 1 using an adhesive or an adhesive tape. Is done.

  Since the search coil 6 can be easily disposed at an appropriate position simply by being directly attached to the back surface of the stator core 1, workability when the search coil 6 is installed can be improved. In addition, the search coil 6 does not need to be designed and manufactured for each generator and is easily mass-produced. Further, the number of members and tools required for installing the search coil 6 can be reduced, and the cost and labor can be reduced.

(Configuration of overexcitation monitoring device and related devices)
FIG. 8 is a diagram showing a configuration including the overexcitation monitoring device and the related device group according to the present embodiment.

  The overexcitation monitoring device according to the present embodiment includes at least the search coil 6 and the measurement device 10 as described above.

  The basic function of the search coil 6 is as described above.

  The measuring device 10 measures the output voltage of the search coil 6 in the range where the terminal voltage of the generator exceeds the rated value during the no-load saturation characteristic test of the generator and records the measurement result. When the output voltage of the search coil 6 measured during the load operation exceeds a predetermined threshold based on the measurement result, a signal indicating an alarm and / or the output voltage of the search coil 6 and the terminal voltage of the generator Or output a signal indicating.

  The excitation device 20 is a device that excites the generator by passing a current through the field winding of the generator.

  In response to a signal output from the measurement device 10 when the measurement device 10 observes that the output voltage of the search coil 6 during the load operation of the generator exceeds a threshold value, the control device 30 It is a device that controls the excitation device 20 to perform processing such as excitation stop or suppression.

(Functional configuration of the measuring device 10)
FIG. 9 is a diagram illustrating a functional configuration of the measurement apparatus 10.

  The measurement apparatus 10 includes various functions such as a data acquisition unit 11, a data storage unit 12, a threshold setting unit 13, an overexcitation monitoring unit 14, and an information output unit 15.

  During the no-load saturation characteristic test, the data acquisition unit 11 acquires data indicating the output voltage of the search coil 6 in addition to acquiring data indicating the terminal voltage of the generator and data indicating the field current. Or at least data indicating the output voltage of the search coil 6 during load operation of the generator.

  The data storage unit 12 has a function of recording various data acquired by the data acquisition unit 11 on a predetermined recording medium and reading various data from the recording medium.

  The threshold setting unit 13 is a function for setting a threshold (such as an alarm value) based on the value of the output voltage of the search coil 6 as a criterion for overexcitation. For example, the threshold value setting unit 13 uses various data acquired by the data acquisition unit 11 to search when the terminal voltage of the generator is at a voltage value of a predetermined percentage (eg, 110%) exceeding 100% of the rated value. The value of the output voltage of the coil 6 is set as the threshold value.

  The overexcitation monitoring unit 14 is a function for monitoring whether the output voltage of the search coil 6 during load operation of the generator is equal to or higher than the threshold value.

  The information output unit 15 indicates a signal indicating an alarm when the output voltage of the search coil 6 during the load operation of the generator is equal to or higher than the threshold, and / or the output voltage of the search coil 6 and the terminal voltage of the generator. This function outputs the signal to the outside.

(Processing procedure for overexcitation monitoring)
The search coil 6 and the measuring device 10 are installed at predetermined locations during the production of the generator or during periodic inspection after the generator is installed at the power plant (including the no-load saturation characteristic test). Is done.

  Here, it is assumed that the generator is already installed in the power plant, and the search coil 6 and the measuring device 10 are installed during the no-load saturation characteristic test. At that time, a cable (not shown) electrically connected from the search coil 6 to the measuring device 10 is also arranged so that the output voltage of the search coil 6 in the machine can be measured outside the generator.

  During the no-load saturation characteristic test of the generator, a change in the field current of the generator and a change in the terminal voltage (induced voltage) accompanying this are measured in order to confirm the no-load saturation characteristic of the generator.

  Specifically, the terminal voltage is increased by gradually increasing the field current from 0, the terminal voltage is increased to, for example, about 120% of the rated voltage, and then the field current is gradually increased. By decreasing the voltage, the terminal voltage is lowered to zero. During this time, the measuring device 10 measures changes in the field current of the generator and changes in the terminal voltage, and data indicating the relationship between the changing field current and the terminal voltage is recorded on a predetermined recording medium. In addition, what is necessary is just to set suitably how much a terminal voltage is raised with respect to a rated voltage previously based on a specification, the specification of a generator, etc.

  In the present embodiment, the change in the output voltage of the search coil 6 is also measured simultaneously with the change in the terminal voltage during the no-load saturation characteristic test, and the changed terminal voltage and the output voltage of the search coil 6 The data indicating the relationship is recorded on a predetermined recording medium.

  Next, processing for setting a determination criterion for overexcitation is performed by the measurement device 10.

Specifically, based on the data indicating the relationship between the generator terminal voltage and the output voltage of the search coil 6 measured during the no-load saturation characteristic test, the terminal voltage exceeds a predetermined value of 100% of the rated value. The value of the output voltage of the search coil 6 when the voltage value is at is set as the threshold value. Here, it is assumed that the state when the terminal voltage is 110% of the rated terminal voltage corresponds to the state immediately before the generator during load operation is overexcited, as shown in FIG. The value “V _110% ” of the output voltage of the search coil 6 when the terminal voltage is 110% of the rated value is set as a threshold value. This threshold value “V _110% ” is higher than the output voltage value “V _100% ” of the search coil 6 when the terminal voltage of the generator is at the rated value.

  This setting process may be performed during measurement of the terminal voltage and the output voltage of the search coil 6, or may be performed after measuring the terminal voltage and the output voltage of the search coil 6.

  After the above setting process is completed, the search coil 6 and the measuring device 10 are constantly used even during normal load operation.

  Specifically, the measuring device 10 constantly monitors whether the output voltage of the search coil 6 during load operation of the generator is equal to or higher than the threshold value. If the output voltage of the search coil 6 exceeds a threshold value, a signal indicating an alarm and / or a signal indicating the terminal voltage of the generator or the output voltage of the search coil 6 is transmitted to the control device 30.

  Thereby, when the signal from the measuring device 10 is transmitted to the control device 30, the control device 30 recognizes that the generator is in a state immediately before being overexcited, and for example, stops or suppresses the excitation of the generator. The excitation device 20 is controlled to perform the processing.

  As described in detail above, according to the present embodiment, it is possible to easily prevent the generator from being overexcited.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Stator iron core, 2 ... Stator core outer diameter side space, 3 ... Structure, 3a ... Rib (key bar), 4 ... Frame structure, 4a ... Structure, 5 ... Duct, 6 ... Search coil, 7a ... Member 7b ... Wedge 7c Stepped portion 8 Dovetail portion 9 Piece member 6a Base body 6b Coil pattern 10 Measurement device 11 Data acquisition unit 12 Data storage unit 13 Threshold setting unit, 14 ... overexcitation monitoring unit, 15 ... information output unit, 20 ... excitation device, 30 ... control device.

Claims (8)

A search coil that is arranged at a position away from the back surface of the stator core of the generator or a predetermined distance from the back surface, and outputs a voltage according to magnetic flux leaking to the outer diameter side of the stator core;
A measuring device for measuring the output voltage of the search coil,
The measuring device is a generator overexcitation monitoring device comprising means for outputting a predetermined signal when an output voltage of the search coil measured during a load operation of the generator becomes a predetermined threshold value or more.   The threshold is preliminarily determined based on the value of the output voltage of the search coil when the terminal voltage of the generator is at a predetermined voltage value exceeding 100% of the rated value during the no-load saturation characteristic test of the generator. The overexcitation monitoring device for a generator according to claim 1, which is defined.   The measurement device outputs a signal indicating an output voltage of the search coil or a terminal voltage of the generator when an output voltage of the search coil during load operation of the generator is equal to or higher than the threshold. The generator overexcitation monitoring apparatus according to 1 or 2.   4. The overexcitation monitoring device for a generator according to claim 1, wherein the search coil is formed by forming a conductor pattern on a film substrate.   5. The search coil according to claim 1, wherein the search coil is fixed together with a wedge between a back surface of the stator core and a frame structure on an outer diameter side of the stator core. 6. Generator over-excitation monitoring device.   5. The generator overexcitation monitoring device according to claim 1, wherein the search coil is disposed on a predetermined member disposed in a dovetail portion of the stator core. 6. A stator core,
The overexcitation monitoring device according to any one of claims 1 to 6,
A generator comprising: A voltage corresponding to the magnetic flux leaking to the outer diameter side of the stator core during the load operation of the generator is generated by a search coil arranged at a position behind the stator core of the generator or at a certain distance from the back surface. Output,
The voltage output by the search coil is equal to or higher than a predetermined threshold based on the output voltage of the search coil acquired in a range in which the terminal voltage of the generator exceeds a rated value during a no-load saturation characteristic test of the generator. A method of operating a generator, including outputting a predetermined signal when