JP2007032504A - Position adjusting method for internal structural component of steam turbine and measuring device to be used for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and simply perform highly precise position adjustment of an internal casing structure even with an upper half casing removed. <P>SOLUTION: This method is provided for aligning of the internal structural component of a steam turbine whose casing consists of the upper half casing 2 and a lower half casing 1. It comprises passing a dummy rotor 4 through the casing with the external of the casing as a supporting point, measuring the vertical and horizontal displacement of the internal structural component from the dummy rotor 4 with transition from the state of the lower half casing 1 from which the upper half casing 2 is removed into the state of assembling the upper half casing 2 thereon, and offset-adjusting the height of the supporting point of the internal structural component in the state of the upper half casing 2 being removed therefrom in accordance with the measured value. Thus, the internal structural component can be aligned to a predetermined position in the assembled state of the upper half casing 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for adjusting the position of a turbine casing and internal components during assembly of a steam turbine and during reassembly after disassembly, and a measuring device used in this method.

  The steam turbine casing contains a turbine rotor that is a rotating body and a large number of internal components (mainly nozzle diaphragms) that are stationary parts, and the position of the internal components can be adjusted so that the position of the internal components can be adjusted. The half casing has an upper and lower divided structure.

  A turbine rotor that is a rotating part has one or a plurality of wheels integrally formed with a shaft, and a moving blade is implanted in the wheel. In addition, a nozzle (static blade) for introducing steam to the turbine rotor blade is installed between the turbine rotor wheels in the stationary portion, and a sealing device is provided between the nozzle diaphragm and the rotating portion to reduce leaked steam in the radial direction. Is installed. Furthermore, seal parts that prevent the steam from leaking to the outside are installed in the penetrating portions at both ends of the turbine rotor and the casing.

  There is a very narrow gap (about 1mm) between these sealing devices and the rotating body. This gap is built from the center of the shaft when the rotor is assembled in the lower half casing and the upper and lower half casings are assembled. It is important that the entire circumference is equal in the radial direction as viewed. When this gap is not equal over the entire circumference in the radial direction, the rotating body comes into contact with the stationary part, causing damage and vibration to the turbine rotor.

  However, since the gap adjustment between the sealing device and the rotating body is performed with the upper half casing removed, the gap between the sealing device and the rotating body changes when the upper half casing is assembled to the lower half casing. If this occurs, there may be a case where the clearance margin cannot be secured after the upper half casing is assembled.

  As described above, the radial clearance adjustment between the internal components of the turbine and the turbine rotor is performed with the upper half casing removed, and the upper half casing is attached after the upper half casing is removed. It is necessary to assume in advance a change in the gap between the internal components and the turbine rotor when the state is set, and to assemble the change by offsetting the change before assembling the upper half casing.

  The cause of the change in the radial gap between the internal components and the turbine rotor is the change in the rigidity of the casing when the upper half casing of the turbine is removed and the upper half casing of the turbine is assembled. Casing deformation due to the weight of the half-casing, and in the aging machine, the aged deformation of the mating surface portion (hereinafter referred to as the horizontal joint portion) of the upper half casing and the lower half casing of the turbine casing, and the reaction from the pipe connected to the turbine Changes due to force can be considered.

  Therefore, when assembling the upper half casing into the lower half casing from the state where the upper half casing is removed, grasp how much the internal components change in the vertical and horizontal directions with respect to the turbine rotor, By offsetting in advance with the upper half casing removed, it is possible to ensure the clearance required in the assembled state of the upper half casing, that is, in the operating state. Become.

  Conventionally, as a method for measuring the gap change, there is a method called wiring. This measuring method by wiring is a method of measuring the amount by which a wire is stretched in the turbine axial direction in the casing and the position of the internal components changes from before the upper half casing is assembled to after the upper half casing is assembled.

Also, recently, with the upper casing of the steam turbine removed, the relative heights of the left and right support points of the part relative to the height of the lower casing are obtained, and the left and right support points of the part are determined based on this relative height. The position of the steam turbine component to improve the alignment of the component when the turbine upper casing is reinstalled by calculating the predicted offset value of the There is a matching method (see Patent Document 1).
Special table 2004-516415 gazette

  However, in the former wiring measurement method, it is necessary to measure by entering the inside of the turbine with the upper half casing assembled in the lower half casing. In addition, the measurement requires special skills, and the turbine installed outdoors has a problem that it is difficult to measure the wire deflection due to the environment.

  Further, in the latter component alignment method of the steam turbine, the offset value for the left and right support points of the component is predicted based on the relative height of the left and right support points of the component with respect to the height of the lower casing of the turbine. Since only the left and right support points of the part are adjusted based on the predicted value, it is difficult to adjust the position change of the part by the upper casing when the upper casing is actually attached.

  In order to solve the above-described problems, the present invention provides a position adjustment method for internal components of a steam turbine that can easily and easily adjust the position of the internal structure of the casing even when the upper half casing is removed. It aims at providing the measuring device used with a method.

  In order to achieve the above object, the present invention aligns internal components of a steam turbine by the following measuring method and measuring apparatus.

  The present invention relates to a lower half of a state in which a dummy rotor or a turbine rotor supported outside the casing is assembled in the casing to align the internal components of the steam turbine and the upper casing is removed. Measure the amount of vertical and horizontal displacement of the internal component relative to the dummy rotor or turbine rotor at a plurality of representative support points of the internal component when the upper half casing is in the assembled state from the state of the casing, Based on the measurement result of the displacement amount, the upper half casing is assembled in the assembled state by adjusting the support point height of the internal component by an amount corresponding to the displacement amount while the upper half casing is removed. Allows the component to be aligned in place.

  In addition, the present invention calculates the expected displacement amount from the displacement amount at the representative measurement point without performing the measurement of all the parts of the internal component parts, thereby changing the internal component parts installed other than the measurement points. A device for continuously measuring and recording the amount of displacement of the support point of the internal component relative to the dummy rotor or turbine rotor being measured is provided.

  According to the present invention, it is possible to adjust the vertical and horizontal positions of the internal components to the required positions while the upper half casing is assembled. In addition, it is possible to calculate the expected displacement amount from the displacement amount at the representative measurement point without performing measurement of all the parts of the internal component component, and obtain the change amount of the internal component component installed at other than the measurement point.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a perspective view schematically showing a first embodiment for explaining a position adjusting method for internal components of a steam turbine according to the present invention.

  In FIG. 1, 1 is a lower half casing, 2 is an upper half casing placed on the lower half casing 1 and assembled integrally with the lower half casing, and 3 is outside the casing at both axial ends of the casing. It is the installed casing external support point. Reference numeral 4 denotes a dummy rotor that penetrates the casing and is supported by the casing external support points 3 at both ends. The dummy rotor 4 is used when the turbine rotor is not on-site for maintenance, for example.

  In such a steam turbine, position adjustment of internal components (not shown) is performed by the following method.

  First, in a state where the upper half casing 2 is removed, the dummy rotor 4 is supported between the casing external support points 3 installed outside the casing at both ends in the axial direction of the lower half casing 1. The vertical and horizontal gaps between the part and the dummy rotor 4 are measured.

  Next, the upper half casing 2 is placed on the lower half casing 1, and the vertical and horizontal gaps between the internal components and the dummy rotor 4 are measured in a state where both casings are assembled together.

  Thereafter, the displacement obtained from the deviation between the measured value when the upper half casing 2 is not assembled and the measured value when the upper half casing 2 is assembled with the upper half casing 2 removed again. Based on the amount, the support point height of the internal component is offset adjusted.

  With such an internal component position adjustment method, when the upper half casing is assembled on the lower half casing, the internal component can be adjusted to a predetermined position that requires it.

  Therefore, even when the upper half casing is removed, the position adjustment of the casing internal structure can be easily and easily performed with high accuracy.

  2 and 3 are configuration diagrams for explaining a method of supporting the casing external support point 3 when the dummy rotor 4 is used in the embodiment.

  In the embodiment of FIG. 1 described above, there is a possibility that the horizontal level change of the casing external support point 3 may occur due to a load change when the upper half casing 2 is assembled or not. There is a possibility that the dummy rotor 4 is stretched and contracted by the generated heat source / cooling source.

Therefore, this Damirota order to avoid the measurement error caused by deformation of 4, using a square Damirota 4 ₁ consisting of H-type steel as Damirota as shown in FIG. 2 (a) ~ (d) , the support of the Damirota 5 The U-shaped dummy rotor supporting steel material 7 intersects the both ends of the point side and is disposed with the U-shaped concave portion facing upward, and bolts are inserted toward the casing external support point 3 at both ends of each dummy rotor supporting steel material 7. and, Damirota 4 ₁ stretch movably lightly tightened when with the casing of the fastening and the lower surface of the Damirota supporting steel 7 is intended to support by installing a round bar 8.

By thus supporting the square Damirota 5 outside the casing support points 3, deformation by elongation and contraction and the load change in the square Damirota 4 ₁ occurs it can absorb them.

Further, by using the cylindrical Damirota 4 ₂ as Damirota in FIG 3 (a) ~ (c) , and crossed the Damirota supporting steel 7 ₂ C-shaped at both ends of the cylindrical Damirota 4 _second supporting point side with arranging the U-recess upward, the notch V-shaped in a portion cylindrical Damirota 4 ₂ this Damirota supporting steel 7 ₂ is supported is provided, supporting a cylindrical Damirota 4 ₂ in this notch It is something to be made.

By thus supporting the cylindrical Damirota 4 ₂ notch of V-shaped provided Damirota supporting steel 7 _2, deformation by elongation and contraction and the load change in the square Damirota 4 ₁ occurs These can be absorbed.

  FIG. 4 is a perspective view for explaining a method of measuring a change in the position of the dummy rotor 4 at the dummy rotor support portion with a displacement meter in the same embodiment.

  In the above-described embodiment, when a position change occurs in the support portion of the dummy rotor 4 when adjusting the position of the internal components, the state where the upper half casing 2 is detached from the lower half casing 1 is assembled. The displacement amount includes a change in the position of the support portion of the dummy rotor 4.

  Therefore, as shown in FIG. 4, the displacement amount (AX, AY) at one support point of the dummy rotor 4 and the displacement amount (BX, BY) at the other support point are measured by a displacement meter (not shown), and the measured value Based on the above, the corrected displacement amount (L1X, L1Y) at L1 is calculated from the support point span L by proportional calculation, and the upper half casing 2 is removed from the state in which the upper half casing 2 is removed by this corrected displacement amount. By correcting the measured value of the amount of displacement at the support point of the dummy rotor 4 in the assembled state, it is possible to improve the position adjustment accuracy of the internal components.

Next, a second embodiment for explaining the position adjusting method of the internal components of the steam turbine according to the present invention will be described with reference to FIG. In FIG. 1, 3 is the same as the above except that the external support point of the casing is a bearing portion, and 4 ₃ is the above-described dummy rotor is a turbine rotor.

  In the first embodiment described above, the method of adjusting the position of internal components when the turbine rotor is not on-site for maintenance, for example, is used. However, in the second embodiment, the turbine rotor is incorporated in the casing. A method for adjusting the position of the internal components will be described.

  First, after assembling the turbine rotor 4 supported by the bearing portions 3 at both ends in the axial direction of the casing, the upper half casing 2 is removed, and the vertical and horizontal directions between the internal components and the turbine rotor 4 are removed. Measure the gap.

  Next, with the upper half casing 2 placed on the lower half casing 1 and the two assembled together, the vertical and horizontal gaps between the internal components and the turbine rotor 4 are measured.

  Thereafter, in a state where the upper half casing 2 is removed again, a displacement amount obtained from a deviation between a measured value when the upper half casing 2 is not assembled and a measured value when the upper half casing 2 is assembled. To adjust the offset of the support point height of the internal component.

  With such a method for adjusting the position of the internal component, it is possible to adjust the internal component to a predetermined position when the upper half casing is assembled.

  Therefore, even when the upper half casing is removed, the position adjustment of the casing internal structure can be easily and easily performed with high accuracy.

  In the first and second embodiments described above, it is obtained from the deviation between the measured value when the upper half casing 2 is detached and the measured value when the upper half casing 2 is assembled. Although the height of the support point of the internal component is offset adjusted based on the amount of displacement, the measured value when the upper half casing 2 is removed and the measurement when the upper half casing 2 is assembled. The amount of displacement obtained from the deviation from the value and the amount of displacement obtained from the deviation between the measured value when the upper half casing 2 is assembled and the measured value when the upper half casing 2 is removed If the offset of the support point height of the internal component is adjusted based on the average value, the position of the casing internal structure can be adjusted with higher accuracy.

  FIG. 5 is a block diagram showing an internal component position measuring apparatus for carrying out the method described in the first embodiment as a third embodiment of the present invention.

As shown in FIG. 5, the square Damirota 4 ₁ consisting of H-type steel in the lower half of the casing 1, the internal components 13 is incorporated is provided by penetrating in the axial direction, both ends of the Damirota 4 are not shown It is supported by a casing external support point.

A dummy rotor measurement structure 9 is attached to _one side of a mating surface (hereinafter referred to as a horizontal joint surface) of the half-mounted internal component 13 incorporated in the lower half casing 1 so as to protrude horizontally to the dummy rotor 41 side. , its upper surface of the projecting portion fitted with a mobile adjustable displacement sensor mounting jig 11a in the vertical direction, installing a displacement sensor 12a for measuring the vertical position of Damirota 4 ₁ to the displacement sensor mounting jig 11a. The mounting movement adjustable displacement sensor mounting jig 11b in the lateral direction on the other horizontal joint surfaces of the internal components 13, mounting the displacement sensor 12b for measuring the horizontal position of Damirota 4 ₁ to the displacement sensor mounting jig 11b .

  The outputs of the displacement sensors 12 a and 12 b are input to the data logger 14 and the offset amount calculation device 15.

  With the internal component position measuring apparatus having such a configuration, the measured values measured by the method described in the first embodiment are input to the data logger 14 and the offset amount calculating apparatus 15, respectively. Based on the displacement obtained from the deviation between the measured value when the casing 2 is removed and the measured value when the upper half casing 2 is assembled, the offset amount of the internal component can be automatically calculated and output.

  In addition, it is possible to constantly monitor and store data, and continuously monitor and store the amount of displacement of the internal component 13 in the assembled state from the state in which the upper half casing 4 is removed, so that measurement data can be stored. There is an advantage that the reliability can be improved and the time point of occurrence of displacement can be clarified.

  Next, a method for adjusting the support point height of the internal component 13 based on the offset amount calculated by the offset amount calculation device 15 will be described.

  Now, assume that the amount of change of the internal component 13 is Xmm upward and Ymm to the left when the upper half casing 2 is in the assembled state from the state where the upper half casing 2 is not assembled. If the internal component 13 when the upper half casing 2 is removed at this time is adjusted to the position of Xmm below and Ymm to the right with respect to the requested center line, it is required in the assembled state of the upper half casing. It becomes the position of the made internal component.

  Therefore, the position of the internal component 13 can be adjusted to the required position by adjusting the height of the support point of the internal component 13 without assembling the upper half casing 2.

  A plurality of nozzle diaphragms or steam seal parts are installed in the lower half casing 1 and the upper half casing 2 in the axial direction. Instead of installing on the horizontal joint surface of the internal component 13, multiple locations are installed inside the lower half casing 1, and the amount of displacement of the internal component 13 at an arbitrary position between the measurement points is measured at both adjacent portions. May be obtained by proportional calculation in accordance with the axial distance, and the support point height of the internal component may be offset adjusted based on this calculated value.

  FIG. 6 is a block diagram showing an internal component position measuring apparatus for carrying out the method described in the second embodiment as the fourth embodiment of the present invention.

As shown in FIG. 6, in the lower half casing 1 internal component 13 is integrated rotor 4 ₃ is provided by penetrating in the axial direction, both end portions of the rotor 4 ₃ is supported by a bearing (not shown) .

Mounting the rotor 4 rotor for measuring structure 10 in which the surface covering the halves are formed in a horizontal plane on the ₃ horizontal joint surface of the internal components 13 embedded in the lower half casing 1, the rotor for measuring structures 10 upper horizontal surface of the mounting movement adjustable displacement sensor mounting jig 11a in the vertical direction, installing a displacement sensor 12a for measuring the vertical position of the rotor 4 ₃ this displacement sensor mounting jig 11a. The mounting one moving adjustable displacement sensor mounting jig 11b in the lateral direction on the upper end face of the internal components 13, mounting the displacement sensor 12b for measuring the horizontal position of the rotor 4 ₃ this displacement sensor mounting jig 11b.

  The outputs of the displacement sensors 12 a and 12 b are input to the data logger 14 and the offset amount calculation device 15.

  In the internal component position measuring apparatus having such a configuration, the measurement values measured by the method described in the second embodiment are input to the data logger 14 and the offset amount calculation apparatus 15, respectively. The same effect as that of the third embodiment can be obtained.

  FIG. 7 shows a position measuring device for an internal component for carrying out the method described in the second embodiment as a fifth embodiment of the present invention, (a) is a view seen from the shaft end side, (B) is a top view.

As shown in FIG. 7, the rotor 4 ₃ in the lower half of the casing 1, the internal components 13 of the half-loading state is incorporated is provided by penetrating in the axial direction, both end portions of the rotor 4 ₃ the bearing (not shown) It is supported.

In this case, the internal component 13 is disposed between the rotor wheel section 16 one another having to exist an appropriate interval in the rotor 4 _3.

The rotor wheel section 16 mutually between the rotor 4 ₃ in parallel with the rotor for measuring structure 17 is fixed, also in the vertical direction on the mating surfaces of the internal components 13 of the half-loading state corresponding to the inter-rotor wheel part 16 mutually A displacement sensor mounting jig 11a capable of movement adjustment is mounted, and a displacement sensor 12a for measuring the vertical position of the rotor measurement structure 17 is mounted on the displacement sensor mounting jig 11a. Similarly, a displacement sensor mounting jig 11b that can be moved and adjusted in the left-right direction is mounted on the mating surface of the internal component 13, and a displacement sensor 12b that measures the horizontal position of the rotor measurement structure 17 is mounted on the displacement sensor mounting jig 11b. I will.

  The outputs of the displacement sensors 12 a and 12 b are input to the data logger 14 and the offset amount calculation device 15.

  With the internal component position measuring apparatus having such a configuration, the relative displacement between the rotor measurement structure 17 and the internal component 13 is measured by the method described in the second embodiment, and the measurement is performed. By inputting the values to the data logger 14 and the offset amount calculation device 15, it is possible to obtain the same operational effects as those of the third embodiment described above.

  In the third to fifth embodiments, the displacement data measured by the displacement sensors 12a and 12b, the correction data obtained by measuring the position change of the rotor support portion with a displacement meter, and the measurement points Even when the upper half casing is removed by inputting the predicted displacement amount and the specifications of the internal component into the offset amount calculation device 15 and automatically calculating and outputting the offset amount of the internal component. The position adjustment of the casing internal structure can be easily and easily performed with high accuracy.

The perspective view which shows typically the basic composition of the steam turbine of the 2 division structure for demonstrating 1st and 2nd embodiment to which the position adjustment method of the internal component by this invention is applied. In the same embodiment, it is for demonstrating the support method of the casing external support point at the time of using a dummy rotor, (a) is a top view, (b) is a front view, (c) is a side view, (d) (C) is an enlarged view of a broken line part. In the embodiment, it is for demonstrating the support method of the casing external support point at the time of using a cylindrical dummy rotor, (a) is a top view, (b) is a front view, (c) is a side view. The perspective view for demonstrating the method to measure the position change of the dummy rotor in a dummy rotor support part with the displacement meter in the embodiment. The block diagram which shows the position adjustment apparatus of the internal component for enforcing the method demonstrated in 1st Embodiment as the 3rd Embodiment of this invention. The block diagram which shows the position adjustment apparatus of the internal structure for enforcing the method demonstrated in 2nd Embodiment as the 4th Embodiment of this invention. As a fifth embodiment of the present invention, an internal component position adjustment device for carrying out the method described in the second embodiment is shown, (a) is a view seen from the shaft end side, (b) is Plan view.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Lower half casing, 2 ... Upper half casing, 3 ... Casing external support point or bearing, 4, 4 ₁ , 4 ₂ ... Square dummy rotor, 4 ₃ ... Rotor, 7 ... Steel material for supporting dummy rotor, 8 ... Round Rod, 9 ... Measurement structure for dummy rotor, 10 ... Measurement structure for rotor, 11a, 11b ... Displacement sensor mounting jig, 12a, 12b ... Displacement sensor, 13 ... Internal components, 14 ... Data logger, 15 ... Offset amount Calculation device, 16 ... rotor wheel section, 17 ... measuring structure for rotor

Claims (10)

  A method for aligning internal components of a steam turbine in which a turbine casing is constituted by an upper half casing and a lower half casing, the dummy rotor penetrating through the casing with the outside of the turbine casing as a supporting point, When the upper half casing is removed from the state of the lower half casing with the upper half casing removed, the amount of displacement of the vertical and lateral support points with respect to the internal components relative to the dummy rotor is measured. Then, by adjusting the offset of the supporting point height of the internal component in a state where the upper half casing is removed based on the measured value, the internal component in the assembled state of the upper half casing. A method for adjusting the position of internal components of a steam turbine, characterized in that it can be adjusted to a predetermined position.   A turbine casing is constituted by an upper half casing and a lower half casing, and a turbine rotor supported by a bearing outside the turbine casing is a method for aligning internal components of a steam turbine incorporated in the casing. Displacement of vertical and lateral support points of the internal components relative to the turbine rotor when the upper half casing is assembled from the state of the lower half casing with the upper half casing removed By measuring the amount and offset adjusting the support point height of the internal component with the upper half casing removed based on the measured value, the upper half casing is assembled in the assembled state. A position adjusting method for internal components of a steam turbine, characterized in that the components can be adjusted to a predetermined position.   When a dummy rotor made of a cylindrical or square steel material is used as a dummy rotor penetrating the turbine casing, the dummy rotor is slidable with respect to a support point to absorb deformation due to thermal expansion and contraction of the dummy rotor, and the dummy rotor The method of adjusting the position of the internal components of the steam turbine according to claim 1, wherein generation of a measurement error due to deformation of the steam turbine is avoided.   The change in position at the support point of the dummy rotor is measured by a displacement meter, and the measured value of the displacement amount of the support point in the vertical and horizontal directions of the internal component relative to the dummy rotor is corrected to avoid the occurrence of a measurement error. The position adjusting method for the internal components of the steam turbine according to claim 1.   Measure the amount of displacement when the upper half casing is removed from the upper half casing assembled state and the amount of displacement when the upper half casing is removed from the assembled state. The position adjustment method for the internal components of the steam turbine according to claim 1 or 2, wherein the height of the support point is adjusted by offset adjustment.   Multiple measurement structures are provided in the axial direction to measure the amount of displacement when the upper half casing is removed and when the upper half casing is assembled or when the upper half casing is detached and measured. The amount of displacement at an arbitrary position between structural structures is calculated according to the distance in the axial direction from the amount of displacement obtained by measurement, and the support point height of the internal component is offset adjusted based on this calculated value. The position adjustment method of the internal components of the steam turbine according to claim 1 or 2, characterized by the above-mentioned.   The dummy rotor measurement structure is placed at the horizontal joint on the lower half of the internal component, and the displacement sensor is placed on the dummy rotor measurement structure so that the upper half casing is removed and assembled. 2. The position adjustment method for the internal components of a steam turbine according to claim 1, wherein the displacement of the support components in the vertical and horizontal directions of the internal components relative to the dummy rotor is measured. Measuring device.   From the state where the rotor measurement structure is placed at the horizontal joint of the lower half of the internal components, the displacement sensor is mounted in the horizontal and vertical directions of the rotor measurement structure, and the upper half casing is removed The internal component of a steam turbine according to claim 2, wherein a displacement amount of a support point in the vertical and horizontal directions of the internal component relative to the turbine rotor when assembled is measured. Measuring device used in the position adjustment method.   9. The apparatus according to claim 7, further comprising means for recording a displacement amount of a support point in the vertical and horizontal directions of the internal components relative to the dummy rotor or the turbine rotor continuously measured by the displacement sensor. Measuring device.   The offset amount calculating means for calculating the offset amount from the displacement amount of the vertical and horizontal support points of the internal components relative to the dummy rotor or the turbine rotor continuously measured by the displacement sensor is provided. Item 9. The measuring device according to Item 8.

Images