Casing position adjustment device

Abstract

In a steam turbine including a rotor including a free side end fixed by a journal bearing in a radial direction and a fixed side end fixed by a thrust bearing in an axial direction, and a casing including a fixed side end fixed by the thrust bearing in the axial direction, a casing position adjustment device is configured to adjust an axial position of the casing with respect to the rotor due to thermal expansion. The casing position adjustment device includes: a low-pressure casing end plate, which is an end plate oriented to a free side in the axial direction in a low-pressure casing of the casing, and has a diaphragm deformable in the axial direction; and actuators, which are configured to deform the low-pressure casing end plate so that the low-pressure casing end plate extends toward the free side in the axial direction.

Claims

1. A casing position adjustment device in a steam turbine including a rotor including a free side end fixed by a journal bearing in a radial direction and a fixed side end fixed by a thrust bearing in an axial direction, and a casing including a fixed side end fixed by the thrust bearing in the axial direction, the casing position adjustment device configured to adjust an axial position of the casing with respect to the rotor due to thermal expansion, the casing position adjustment device comprising: a low-pressure casing end plate, which is an end plate oriented to a free side in the axial direction in a low-pressure casing of the casing, and has a diaphragm deformable in the axial direction; and actuators, which are configured to deform the low-pressure casing end plate such that the low-pressure casing end plate extends toward the free side in the axial direction.

2. The casing position adjustment device according to claim 1, wherein the casing is fixed by anchor bolts on a fixed side in the axial direction with respect to the low-pressure casing end plate.

3. The casing position adjustment device according to claim 2, wherein the actuators are respectively connected to both ends of the low-pressure end plate in the radial direction and a horizontal direction from the free side in the axial direction.

4. The casing position adjustment device according to claim 3, wherein the casing is fixed on a base through intermediation of a base plate; reaction force receivers are respectively arranged to both ends of the low-pressure casing end plate in the radial direction and the horizontal direction on the base on the free side; lower parts of the reaction force receivers extend toward the base plate, and are fixed; and the actuators are interposed between the reaction force receivers and the low-pressure casing end plate.

5. The casing position adjustment device according to claim 3, wherein: reaction force receivers are respectively fixed to both ends of the low-pressure casing end plate in the radial direction and the horizontal direction on a base on the free side; and the actuators are interposed between the reaction force receivers and the low-pressure casing end plate.

6. The casing position adjustment device according to claim 2, wherein: the journal bearing is fixed to the casing, and includes a bearing housing having arms respectively extending from both sides of the journal bearing in the radial direction and a horizontal direction; and the actuators are respectively connected to the arms from the fixed side in the axial direction.

7. The casing position adjustment device according to claim 2, further comprising: a first sensor for measuring a thermal expansion difference which is a difference of a displacement amount of the rotor and a displacement amount of the casing due to thermal expansion; and a controller for controlling the actuators based on a measured value obtained by the first sensor.

8. The casing position adjustment device according to claim 1, wherein the actuators are respectively connected to both ends of the low-pressure end plate in the radial direction and a horizontal direction from the free side in the axial direction.

9. The casing position adjustment device according to claim 8, wherein: the casing is fixed on a base through intermediation of a base plate; reaction force receivers are respectively arranged to both ends of the low-pressure casing end plate in the radial direction and the horizontal direction on the base on the free side; lower parts of the reaction force receivers extend toward the base plate, and are fixed; and the actuators are interposed between the reaction force receivers and the low-pressure casing end plate.

10. The casing position adjustment device according to claim 8, wherein: reaction force receivers are respectively fixed to both ends of the low-pressure casing end plate in the radial direction and the horizontal direction on a base on the free side; and the actuators are interposed between the reaction force receivers and the low-pressure casing end plate.

11. The casing position adjustment device according to claim 1, wherein: the journal bearing is fixed to the casing, and includes a bearing housing having arms respectively extending from both sides of the journal bearing in the radial direction and a horizontal direction; and the actuators are respectively connected to the arms from a fixed side in the axial direction.

12. The casing position adjustment device according to claim 11, wherein: reaction force receivers are respectively fixed to fixed sides of the arms on a base; and the actuators are interposed between the reaction force receivers and the arms.

13. The casing position adjustment device according to claim 1, further comprising: a first sensor for measuring a thermal expansion difference which is a difference of a displacement amount of the rotor and a displacement amount of the casing due to thermal expansion; and a controller for controlling the actuators based on a measured value obtained by the first sensor.

14. The casing position adjustment device according to claim 13, further comprising a second sensor for measuring thrust force of the actuators, wherein the controller is configured to control the actuators such that a measured value obtained by the second sensor becomes equal to or less than a first predetermined value.

15. The casing position adjustment device according to claim 13, further comprising a third sensor for measuring a distortion force of the low-pressure casing end plate, wherein the controller is configured to control the actuators such that a measured value obtained by the third sensor becomes equal to or less than a second predetermined value.

16. The casing position adjustment device according to claim 13, further comprising a fourth sensor for measuring vibration of the low-pressure casing end plate, wherein the controller is configured to control the actuators such that a measured value obtained by the fourth sensor becomes equal to or less than a third predetermined value.

17. The casing position adjustment device according to claim 13, further comprising a fifth sensor for measuring a rotation torque of the rotor, wherein the controller is configured to control the actuators such that, based on a measured value obtained by the fifth sensor, a relative position between the casing and the rotor in the axial direction becomes a position enabling a maximum output of the steam turbine.

18. The casing position adjustment device according to claim 13, further comprising a sixth sensor for measuring temperature in the casing, wherein the controller is configured to control the actuators such that, based on a measured value obtained by the sixth sensor, a relative position between the casing and the rotor in the axial direction becomes a position enabling a maximum output of the steam turbine.

19. The casing position adjustment device according to claim 1, wherein the actuators are arranged in an outermost diameter of the low-pressure casing end plate in the radial direction.

20. The casing position adjustment device according to claim 1, wherein the low-pressure casing end plate is expanded in the radial direction, and has a shape in which a periphery of a radial outer circumference is inclined in the axial direction.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a cross-sectional view of a casing and a periphery of the casing of a steam turbine in a first embodiment of the present invention.

(2) FIGS. 2A and 2B are views for illustrating an example of a shape of the casing including a diaphragm portion. FIG. 2A is a cross-sectional view taken along line a-a of FIG. 1, and FIG. 2B is a perspective view of the casing.

(3) FIGS. 3A to 3C are schematic views of the casing and the periphery of the casing of the steam turbine in the first embodiment of the present invention. FIG. 3A is a partial top view. FIG. 3B is a side view. FIG. 3C is a partial front view.

(4) FIGS. 4A to 4C are schematic views for illustrating installation positions of actuators in the first embodiment of the present invention. FIG. 4A is a top view. FIG. 4B is a side view. FIG. 4C is a partially enlarged view of a portion surrounded by the dashed line of FIG. 4B.

(5) FIGS. 5A and 5B correspond to FIG. 2A, and are views for illustrating an example of pulling positions of the actuators and a result of a deformation analysis by the FEM. FIG. 5A is a view of a state before deformation, and FIG. 5B is a view of a state after deformation.

(6) FIG. 6 is a block diagram for illustrating a control system for the actuator in the first embodiment of the present invention.

(7) FIG. 7 is a circuit diagram for illustrating a structure of a hydraulic unit to be controlled by a controller in the first embodiment of the present invention.

(8) FIGS. 8A to 8C are schematic views for illustrating installation positions of actuators in a second embodiment of the present invention. FIG. 8A is a top view. FIG. 8B is a side view. FIG. 8C is a partially enlarged view of a portion surrounded by the dashed line of FIG. 8B.

(9) FIG. 9 is a partially enlarged view corresponding to FIG. 4C, for illustrating installation positions of actuators in a third embodiment of the present invention.

DESCRIPTION OF EMBODIMENTS

(10) Now, detail description is made of a casing position adjustment device according to embodiments of the present invention with reference to the drawings.

First Embodiment

(11) FIG. 1 is a schematic cross-sectional view of a casing and a periphery of the casing of a steam turbine. A left side of the drawing sheet is a free side, and a right side of the drawing sheet is a fixed side. In FIG. 1, a journal bearing for supporting a free side of a rotor 12 and a thrust bearing for supporting a fixed side of the rotor 12 are omitted. However, an axial position of “thrust bearing installation position” is indicated by the dashed line. Further, the white solid arrow having a starting point from the dashed line indicating the thrust bearing installation position indicates that the rotor 12 is thermally expanded from the starting point. The orientation of the arrow indicates the direction of the thermal expansion of the rotor 12.

(12) The casing position adjustment device according to this embodiment is configured to perform positioning control on the casing side in the axial direction. Further, in this embodiment, unlike Patent Document 1 described above, an entire casing 11 is not set in a completely free state. Instead, the casing 11 is fixed by anchor bolts at an axial position of “casing anchor point” indicated by the dashed line in FIG. 1. Note that, the white solid arrow extending from the dashed line of the casing anchor point indicates the thermal expansion of the casing 11. Further, the white solid arrow having a starting point from the dashed line of the casing anchor point indicates that the casing 11 is thermally expanded from the starting point. The orientation of the arrow indicates a direction of the thermal expansion of the casing 11.

(13) Further, a plate (low-pressure casing end plate) 11a (indicated by the dashed line frame) on an end surface of a low-pressure casing 11A, which is oriented to the free side in the axial direction, has a flexible structure in a diaphragm shape. On an outer surface of the low-pressure casing 11A, a rib 11B is provided. Specifically, a strength design is provided in the following manner: the low-pressure casing end plate 11a capable of suppressing influence of pressure deformation is reduced in thickness to enable deformation of a thermal expansion difference adjustment margin of ±2 mm by a portion reduced in thickness. Further, the low-pressure casing end plate 11a is deformed by an actuator. Note that, the low-pressure casing end plate 11a is expanded in a substantially semi-circular shape in a radial direction and has a shape in which a periphery of a radial outer circumference is inclined in the axial direction as illustrated in FIG. 1.

(14) That is, a thrust load is received by the anchor bolts, and a part of the casing 11 (the low-pressure casing end plate 11a) is deformed into a diaphragm shape so that a blade ring inside is subjected to positioning adjustment.

(15) Even when the casing 11 is set in a completely free state, it is required that all the thrust loads applied to the casing 11 (loads generated due to a pressure difference, thermal expansion, earthquake acceleration, or other factors) be supported by the actuator. Thus, there arise problems such as a blade contact due to, for example, the thrust force loss of the actuator and increase in size of the actuator. Therefore, in this embodiment, the thrust load is received by the anchor bolts, and the part of the casing 11 (the low-pressure casing end plate 11a) is deformed into a diaphragm shape, to thereby perform positioning adjustment. In this manner, fail-safe in an emergency is enabled, and the actuator can be reduced in size.

(16) FIGS. 2A and 2B are views for illustrating an example of a shape of the casing including a diaphragm portion. FIG. 2A is a cross-sectional view taken along line a-a of FIG. 1, and FIG. 2B is a perspective view of the casing.

(17) The low-pressure casing end plate 11a having a diaphragm shape is deflected when a rigid portion (high-pressure casing) 11b is moved and adjusted to the free side in the axial direction. In this manner, only the rigid portion (high-pressure casing) 11b is moved and adjusted by ±2 mm while the casing 11 is fixed by the anchor.

(18) FIGS. 3A to 3C are schematic views of the casing 11 and the periphery of the casing 11 of the steam turbine. FIG. 3A is a partial top view. FIG. 3B is a side view. FIG. 3C is a partial front view. Further, in FIG. 3B, a thrust bearing 16 is illustrated. Further, in FIGS. 3A and 3B, the dashed line indicating the axial position of the casing anchor point is illustrated. Similarly to FIG. 1, the white solid arrow has the starting point from the dashed line. Further, similarly to the white solid arrow having the starting point from the thrust bearing installation position in FIG. 1, the white solid arrow has a starting point from the thrust bearing 16.

(19) As illustrated in FIGS. 3A, 3B, and 3C, the casing 11, a bearing housing 13 of the journal bearing 19, and the thrust bearing 16 are placed on a base 14. As illustrated in FIG. 3A, the casing 11 is fixed to the base 14 at both ends in the rotor radial direction and a horizontal direction of the casing 11 by anchor bolts 15 arranged on the fixed side in the rotor axial direction with respect to the low-pressure casing end plate 11a. As indicated by the white solid arrow in FIG. 3B, the casing 11 is thermally expanded from the anchor bolts 15 in the rotor axial direction.

(20) The bearing housing 13 is fixed to the casing 11 by a rod (not illustrated). Further, the rotor 12 is movable with respect to the bearing housing 13 in the rotor axial direction. Therefore, the bearing housing 13 is moved in the rotor axial direction due to the thermal expansion of the casing 11. Note that, as indicated by the white solid arrow, the rotor 12 (omitted in FIG. 3) is thermally expanded from the thrust bearing 16 to the free side.

(21) FIGS. 4A to 4C are schematic views for illustrating installation positions of actuators 17 in this embodiment. FIG. 4A is a top view. FIG. 4B is a side view. FIG. 4C is a partially enlarged view of a portion surrounded by the dashed line of FIG. 4B. Note that, in FIGS. 4A and 4B, illustration of the thrust bearing is omitted.

(22) As illustrated in FIG. 4C, the anchor bolts 15 are arranged to pass through the casing 11, a base plate 14a, and the base 14. In this manner, the casing 11 is fixed to the base 14 through intermediation of the base plate 14a.

(23) Further, reaction force receivers 18 are respectively arranged to both ends of the low-pressure casing end plate 11a in the rotor radial direction and the horizontal direction on the base 14 on the free side. Further, lower parts of the reaction force receivers 18 extend toward the base plate 14a, and the extending parts of the reaction force receivers 18 and the base plate 14a are fixed to each other by welding, a bolt, or the like. Further, the actuators 17 are interposed and fixed between the reaction force receivers 18 and the low-pressure casing end plate 11a. That is, the actuators 17 are respectively connected to both the ends of the low-pressure casing end plate 11a in the rotor radial direction and the horizontal direction.

(24) In the casing position adjustment device according to this embodiment, when the thermal expansion difference is caused, the actuators 17 pull the low-pressure casing end plate 11a toward the free side (thermal expansion direction). With this action, as indicated by the dashed lines in FIGS. 4A and 4B, the low-pressure casing end plate 11a is deformed to extend in the rotor thermal expansion direction (to the free side in the rotor radial direction). Then, the casing 11 and the bearing housing 13 fixed to the casing 11 are displaced in the thermal expansion direction of the rotor (to the free side in the rotor radial direction). Thus, the thermal expansion difference can be canceled.

(25) Reaction forces generated when the actuators 17 pull the low-pressure casing end plate 11a are received by the anchor bolts 15. Further, for example, a pressure type is employed for the actuators 17. Particularly, for example, it is preferred to employ a hydraulic jack to be used also for replacing work for heavy load of several hundred tons such as in-furnace structures.

(26) Specifically, in the steam turbine including the rotor 12 and the casing 11, the casing position adjustment device according to this embodiment is configured to adjust axial position of the casing 11 that is thermally expanded with respect to the rotor 12. The rotor 12 includes a free side end fixed by the journal bearing 19 in the radial direction and a fixed side end fixed by the thrust bearing 16 in the axial direction. The casing 11 includes a fixed side end fixed by the thrust bearing 16 in the axial direction (rotor axial direction). The casing position adjustment device includes the low-pressure casing end plate 11a and the actuators 17. The low-pressure casing end plate 11a is an end plate oriented to the free side in the axial direction in the low-pressure casing of the casing 11, and has a deformable diaphragm shape. The actuators 17 deform the low-pressure casing end plate 11a so that the low-pressure casing end plate 11a extends toward the free side in the axial direction.

(27) Further, the casing 11 is fixed by the anchor bolts 15 on the fixed side in the axial direction with respect to the low-pressure casing end plate 11a. Further, the actuators 17 are respectively connected to both the ends of the low-pressure casing end plate 11a in the radial direction and the horizontal direction from the free side in the axial direction.

(28) Further, the casing 11 is fixed on the base 14 through intermediation of the base plate 14a. The reaction force receivers 18 are respectively arranged to both the ends of the low-pressure casing end plate 11a in the radial direction and the horizontal direction on the base 14 on the free side. The lower parts of the reaction force receivers 18 extend toward the base plate 14a, and are fixed. The actuators 17 are interposed between the reaction force receivers 18 and the rib 11a.

(29) FIGS. 5A and 5B correspond to FIG. 2A, and are views for illustrating an example of pulling positions of the actuators and a result of a deformation analysis by the FEM. FIG. 5A is a view of a state before deformation, and FIG. 5B is a view of a state after deformation.

(30) When the low-pressure casing end plate 11a is pulled at actuator pulling positions (outermost diameter positions of the low-pressure casing end plate 11a) b illustrated in FIG. 5B, that is, under the worst condition, the low-pressure casing end plate 11a is deformed the most, maximum stress is increased, and a moving amount of the end of the rigid portion (high-pressure casing) 11b on the free side is maximum. As a result of the analysis under the condition, stress of the low-pressure casing end plate 11a is maximum at a welding portion, which is 151.9 MPa, and satisfies allowable stress equal to or less than 199.9 MPa (1.5 σa). The end of the rigid portion (high-pressure casing) 11b on the free side is moved by 2.2 mm under the minimum condition, and hence it is understood that a required thermal expansion difference moving amount can be secured. Therefore, when the actuators are arranged within the outermost diameter of the low-pressure casing end plate 11a in the radial direction and perform pulling, it is conceived that the thermal expansion difference adjustment can be performed.

(31) Particularly, when the actuators are arranged at the rigid portions (high-pressure casing) 11b and perform pulling, the thermal expansion difference adjustment is facilitated in terms of stress and control accuracy.

(32) FIG. 6 is a block diagram for illustrating a control system for the actuator 17 in this embodiment. Note that, description is made of the actuator 17 as a hydraulic cylinder. However, this embodiment is not limited thereto.

(33) In addition to the structure described above, as illustrated in FIG. 6, the casing position adjustment device according to this embodiment includes a sensor 21, a controller 22, and a hydraulic unit 23 in order to control the actuator 17.

(34) As the sensor 21, first, there is used a thermal expansion difference meter (or bearing housing displacement meter) for detecting a detection value for feedback. The thermal expansion difference meter is fixed in the bearing housing 13, and detects a position of the rotor 12 so as to measure a thermal difference between the casing 11 and the rotor 12. Note that, the bearing housing displacement meter is for measuring a displacement amount of the bearing housing 13.

(35) Further, for improvement in reliability, as the sensor 21, it is desired that other sensors be used together with the thermal expansion difference meter (or bearing housing displacement meter). As the other sensors, there may be used a management sensor for monitoring and tripping (shutdown), which performs monitoring, control, or even tripping (shutdown) depending on the situation so that a command value to the actuator 17 is prevented from being an excessively large value. Further, there may be used a comparison evaluation sensor, which makes a comparison between a planned value and a measured value of power generation efficiency and evaluate the resultant.

(36) As the management sensor for monitoring and tripping, for example, there is used one or plurality of sensors among an actuator thrust force meter (load cell) for measuring thrust force of the actuator 17 (force of a load of a hydraulic cylinder), a distortion meter for measuring a distortion (stress) force of the low-pressure casing end plate 11a, and an accelerometer for measuring vibration of the low-pressure casing end plate 11a.

(37) As the comparison evaluation sensor, for example, there is used one or both of the followings: an axial torque meter for measuring rotation torque of the rotor 12; and an in-casing thermometer for measuring temperature in the casing 11.

(38) The controller 22 controls the actuator 17 through the hydraulic unit 23. First, based on the measured value of the thermal expansion difference obtained by the sensor 21 as the thermal expansion difference meter (or the measured value of the displacement amount of the bearing housing 13 obtained by the sensor 21 as the bearing housing displacement meter), the actuator 17 is controlled so that the thermal expansion difference becomes 0 (or a target value input in advance). Specifically, a control amount of the actuator 17 is calculated, and the actuator 17 is controlled through the hydraulic unit 23 so that the control amount of the actuator 17 becomes the target value (further, when a target control velocity is set, and a displacement velocity is calculated based on the displacement amount of the bearing housing 13, the resultant may be used for controlling the actuator 17).

(39) Further, when the actuator thrust force meter described above is additionally used as the sensor 21, the controller 22 performs monitoring and control of the actuator 17 so that the measured value of the thrust force of the actuator 17 obtained by the sensor 21 as the actuator thrust force meter becomes equal to or less than a predetermined force (first predetermined value).

(40) Further, when the distortion meter described above is additionally used as the sensor 21, in order to monitor strength of the low-pressure casing end plate 11a, the controller 22 performs monitoring and control of the actuator 17 so that the measured value of the distortion of the low-pressure casing end plate 11a obtained by the sensor 21 as the distortion meter becomes equal to or less than a predetermined distortion (second predetermined value).

(41) Further, when the accelerometer described above is additionally used as the sensor 21, the controller 22 performs monitoring and control of the actuator 17 so that the measured value of the vibration of the low-pressure casing end plate 11a obtained by the sensor 21 as the accelerometer becomes equal to or less than a predetermined vibration (third predetermined value).

(42) Further, when the axial torque meter is additionally used as the sensor 21, the controller 22 performs control of the actuator 17 so that, based on the measured value of the axial torque obtained by the sensor 21 as the axial torque meter, a relative position between the casing 11 and the rotor 12 in the rotor axial direction becomes a position enabling the maximum output of the steam turbine. Accordingly, the thermal expansion difference is adjusted.

(43) Further, when the in-casing thermometer is additionally used as the sensor 21, the controller 22 performs control of the actuator 17 so that, based on the measured value of the gas temperature in the casing 11 obtained by the sensor 21 as the in-casing thermometer, the relative position between the casing 11 and the rotor 12 in the rotor axial direction becomes a position enabling the maximum efficiency of the steam turbine. Accordingly, the thermal expansion difference is adjusted.

(44) The casing position adjustment device according to this embodiment includes the configuration as described above. Thus, when the controller 22 performs control of the actuator 17, the low-pressure casing end plate 11a extends in the rotor thermal expansion direction, and the thermal expansion difference can be canceled.

(45) FIG. 7 is a circuit diagram for illustrating a structure of the hydraulic unit 23 to be controlled by the controller 22. As illustrated in FIG. 7, the hydraulic unit 23 includes a hydraulic tank 23a, a filter 23b, a motor 23c, a hydraulic pump 23d, a check valve 23e, a relief valve 23f, a pressure meter 23g, a solenoid valve 23h, pilot check valves 23i and 23j, and velocity regulating throttles 23k and 23l.

(46) The hydraulic pump 23d sucks oil from the hydraulic tank 23a through the filter 23b, and sends the oil to the fixed side of the hydraulic unit 23. The hydraulic pump 23d is operated by the motor 23c to which the hydraulic pump 23d is connected. Further, on the fixed side of the hydraulic pump 23d, the hydraulic pump 23d is connected in parallel to the relief valve 23f and the solenoid valve 23h (through the check valve 23e). Further, between the hydraulic pump 23d and the solenoid valve 23h, the pressure meter 23g is provided. Note that, the relief valve 23f prevents a hydraulic pressure from increasing and exceeding a set pressure.

(47) The solenoid valve 23h switches a flow direction of the oil sent from the hydraulic pump 23d between two directions. To one part of the solenoid valve 23h on the fixed side, the pilot check valve 23i and the velocity regulating throttle 23k are provided. To another part of the solenoid valve 23h on the fixed side, the pilot check valve 23j and the velocity regulating throttle 23l are provided.

(48) In a case in which the pump is stopped due to, for example, a power cut, the pilot check valves 23i and 23j are valves for adjusting the actuator 17 as a hydraulic cylinder to maintain its position.

(49) The velocity regulating throttles 23k and 23l are provided to the fixed sides of the pilot check valves 23i and 23j, respectively. The velocity regulating throttle 23k is a velocity regulating throttle (meter-in valve) when the casing 11 is pressed by the actuator 17. Further, the velocity regulating throttle 23k functions as a velocity regulator when an impact load is applied in a direction of pressing the actuator 17 from the casing 11 side due to, for example, change in pressure in the casing 11. Meanwhile, the velocity regulating throttle 23l is a velocity regulating throttle (meter-in valve) when the actuator 17 pulls and positions the casing 11.

(50) That is, in a case in which the actuator 17 is of a hydraulic type (or pneumatic type), the pilot check valves 23i and 23j are provided so that the thrust force of the actuator 17 is not lost due to, for example, a power cut. The velocity regulating throttles 23k and 23l are included to regulate operation velocity so that a sudden operation of the actuator 17 is prevented.

(51) Description is given of the casing position adjustment device according to this embodiment above. In the casing position adjustment device according to this embodiment, the thermal expansion difference is subjected to a sensory feedback, and the casing position adjustment is performed. Accordingly, the turbine efficiency can be improved.

(52) Further, in the casing position adjustment device according to this embodiment, when a large thrust load is applied due to, for example, an earthquake, the load can be received by the anchor bolts instead of the actuators. Accordingly, a serious accident such as a blade contact can be avoided.

(53) Further, in the casing position adjustment device according to this embodiment, when the actuator malfunctions, the casing is fixed by the anchor bolts. Accordingly, a serious accident such as a blade contact can be avoided.

(54) Further, in the casing position adjustment device according to this embodiment, the actuators only require thrust force for casing deformation. Thus, small-sized and inexpensive actuators can be employed.

(55) Further, through use of the casing position adjustment device according to this embodiment, the steam turbine can be operated at the maximum output point or the maximum efficiency point.

Second Embodiment

(56) The casing position adjustment device according to a second embodiment of the present invention is obtained by changing mounting positions of the actuators in the casing position adjustment device according to the first embodiment. Description is mainly given of configurations different from those in the first embodiment below. Description for identical configurations are omitted to the extent possible.

(57) FIGS. 8A to 8C are schematic views for illustrating installation positions of the actuators in this embodiment. FIG. 8A is a top view. FIG. 8B is a side view. FIG. 8C is a partially enlarged view of a portion surrounded by the dashed line of FIG. 8B. Note that, in FIGS. 8A and 8B, illustration of the thrust bearing is omitted.

(58) A bearing housing 33 of the journal bearing included in the casing position adjustment device according to this embodiment is obtained by partially changing the shape of the bearing housing 13. Further, the actuators 27 are connected to the bearing housing 33.

(59) An arm 33a is formed to extend in the same direction from each of both side surfaces of the bearing housing 33 in the rotor radial direction and the horizontal direction. The actuators 27 are fixed to the arms 33a from the fixed side in the rotor axial direction, and presses the bearing housing 33 in the thermal expansion direction of the rotor 12 (to the free side in the rotor axial direction).

(60) Reaction force receivers 28 are fixed to the base 14 with firm bolts (such as anchor bolts) 29 on the fixed side in the rotor axial direction, and the actuators 27 are fixed to the reaction force receivers 28. Note that, one or a plurality of bolts 29 may be used.

(61) In the casing position adjustment device according to this embodiment, when the thermal expansion difference is caused, the actuators 27 press the bearing housing 33 in the thermal expansion direction of the rotor 12 (to the free side in the rotor axial direction). Then, as indicated by the dashed lines in FIGS. 8A and 8B, the low-pressure casing end plate 11a is deformed to extend in the thermal expansion direction of the rotor 12 (to the free side in the rotor axial direction). With this, the casing 11 and the bearing housing 33 are displaced in the rotor heat expansion direction. Accordingly, the heat expansion difference can be canceled.

(62) Note that, the reaction forces of the actuators 27 in this case are received by the reaction force receivers 28. The reaction force receivers 28 are fixed by the bolts 29, and hence are not moved by the reaction forces of the actuators 27.

(63) Note that, when the bearing housing 33 (and the casing 11) is adjusted in the thermal expansion direction, a force of 2838 kN (about 290 tf) is required as sliding friction in the rotor axis direction. When the two actuators 27 press and pull the bearing housing 33 against the friction, each actuator requires thrust force equal to or larger than 1419 kN. In order to obtain the thrust force and achieve a compact design, hydraulic actuators exerting a high pressure of 70 MPa are employed as the actuators 27.

(64) That is, in the casing position adjustment device according to this embodiment, the journal bearing 19 is fixed to the casing 11, and includes the bearing housing 33 having the arms 33a respectively extending from both sides in the radial direction and the horizontal direction. The actuators 27 are respectively connected to the arms 33a from the fixed side in the axial direction.

(65) Further, the reaction force receivers 28 are respectively fixed to the fixed sides of the arms 33a on the base 14, and the actuators 27 are interposed between the reaction force receivers 28 and the arms 33a.

(66) In the casing position adjustment device according to this embodiment, the actuators 27 are provided to the bearing housing 33 side, and hence a height from the base at the connection positions are relatively small. Thus, the reaction force receivers 28 can be reduced in size. Further, mounting work or other work can be facilitated.

(67) In the casing position adjustment device according to this embodiment, a surface temperature of the bearing housing 33 is equal to or less than about 60°, and the actuators 27 are connected to the bearing housing 33 through the arms 33a. Thus, the actuators 27 having normal temperature can be used.

(68) In the casing position adjustment device according to this embodiment, radial deformation of the bearing housing 33 due to the thermal expansion is negligible, and hence it is not required to mount universal joints to the actuators 27 and connection portions.

Third Embodiment

(69) The casing position adjustment device according to a third embodiment of the present invention is obtained by changing the shape of the reaction force receivers 18 in the casing position adjustment device according to the first embodiment. Description is mainly made of configurations different from those in the first embodiment below. Description for identical configurations are omitted to the extent possible.

(70) FIG. 9 is a partially enlarged view corresponding to FIG. 4C, for illustrating illustration positions of the actuators 17 in this embodiment.

(71) In the casing position adjustment device according to this embodiment, similarly to the first embodiment, the actuators 17 are respectively connected to both the ends of the low-pressure casing end plate 11a in the rotor radial direction and the horizontal direction.

(72) The actuators 17 are respectively fixed to the reaction force receivers 38 respectively arranged to both the sides of the low-pressure casing end plate 11a in the horizontal direction on the base 14 on the free side. The reaction force receivers 38 are fixed to the base 14 by firm bolts (such as anchor bolts) 39.

(73) That is, in the casing position adjustment device according to this embodiment, the reaction force receivers 38 are respectively fixed to both the ends of the low-pressure casing end plate 11a in the radial direction and the horizontal direction on the base 14 on the free side. The actuators 17 are interposed between the reaction force receivers 38 and the low-pressure casing end plate 11a.

(74) In the casing position adjustment device according to this embodiment, when the actuators 17 pull the low-pressure casing end plate 11a, the low-pressure casing end plate 11a is deformed to extend in the thermal expansion direction of the rotor 12 (to the free side in the axial direction). In this case, the reaction forces of the actuators 17 are received by the reaction force receivers 38. The reaction force receivers 38 are fixed by the bolts 39, and hence are not moved by the reaction forces of the actuators 17. In this manner, stress is applied to other parts, and deformation is prevented. Thus, a further high responsibility is achieved.

INDUSTRIAL APPLICABILITY

(75) The present invention is suitable for a casing position adjustment device for a steam turbine to be used in, for example, a power plant.

REFERENCE SIGNS LIST

(76) 11 Casing 11A Low-pressure casing 11a Low-pressure casing end plate 11B Rib 11b Rigid portion (high-pressure casing) 12 Rotor 13, 33 Bearing housing 14 Base 14a Base plate 15 Anchor bolt 16 Thrust bearing 17, 27 Actuator 18, 28, 38 Reaction force receiver 21 Sensor 22 Controller 23 Hydraulic unit 23a Hydraulic tank 23b Filter 23c Motor 23d Hydraulic pump 23e Check valve 23f Relief valve 23g Pressure meter 23h Solenoid valve 23i, 23j Pilot check valve 23k, 23l Velocity regulating throttle 29, 39 Bolt 33a Arm