KR102361554B1 - Apparatus for guiding turning of a power plant casing - Google Patents

Abstract

A turning guide apparatus for a casing of a power generation facility according to an embodiment of the present invention includes a rotation supporting mechanism mounted on a casing of a power generation facility and configured to support the casing of the power generation facility to rotate; and a plurality of supports for supporting the casing of the power generation facility. The turning guide apparatus of the present invention can guide turn-over or rotation of the casing to be facilitated in a narrow space without limitation in the structure and outer shape of the casing when the casing is separated for inspection, replacement, repair and the like of a turbine which is a part of the power generation facility.

Description

Power plant casing turning guide device {APPARATUS FOR GUIDING TURNING OF A POWER PLANT CASING}

The present invention relates to a casing turning guide device for a power generation facility, and more particularly, when separating a casing for inspection, replacement, repair, etc. of a turbine, which is a part of a power generation facility, without being limited by the structure and appearance of the casing It relates to a power generation facility casing turning guide device capable of stably guiding the rotation (turning) or reversal (turn-over) of the casing in a narrow space within the power generation facility site.

A power plant is a facility that generates electrical energy, and the power plant is connected to an electrical grid. Power generation facilities use steam turbines, gas turbines, and the like to generate electrical energy.

A steam turbine is an engine that converts the thermal energy of high-pressure steam into mechanical energy. The rotating blade rotates by recoil and converts the generated rotational force into electrical energy.

Gas turbine uses combustion gas instead of steam. It is a power generation facility that produces electricity using combustion gas of fuel. It is possible.

These power generation facilities usually produce electric power by the rotational force of the turbine. That is, the rotary shaft of the power generation facility is connected to the turbine rotary shaft, and as the turbine rotary shaft rotates, the power generation facility rotary shaft connected thereto rotates to produce electric power. At this time, the turbine rotating shaft is rotated by high-pressure steam, and by controlling the steam inflow of a constant pressure supplied to the turbine, the rotation of the turbine rotating shaft is maintained at the rated rotation speed to produce electricity.

The turbine is protected by the casing as the power plant casing is configured to enclose the inner parts of the turbine. The power generation facility casing is composed of an upper casing and a lower casing, and the size and weight of the power generation facility casing are different depending on the model or type of the turbine. Since the operation efficiency of the turbine may be lowered due to abrasion of the sealing part, other damage, etc., inspection and maintenance of the turbine are required periodically. In particular, various parts such as a diaphragm, a blade ring, etc. are assembled in the power generation facility casing, and it is necessary to disassemble the various parts assembled in the power generation facility casing during inspection and maintenance of the turbine. In particular, since the upper casing cannot be disassembled when the upper casing is assembled to the lower casing, the blade ring, the diaphragm, etc. can be disassembled from the upper casing only after the upper casing is separated from the lower casing and then turned over. However, if the lifting load and height of the lifting crane are difficult to reverse, the inspection and maintenance of the turbine may not be performed smoothly.

More specifically, it is necessary to disassemble and invert the upper casing constituting the casing for inspection, replacement, repair, etc. of the internal parts of the turbine located inside the casing to expose the inside of the upper casing. If the weight is large, there may be a situation in which the reverse operation of the upper casing cannot be performed in the facility space. In particular, at the site, it is necessary to lift the upper casing using the loading bay and the boom crane outside the building and then reverse it. Since it is unsuitable for the facility maintenance process such as work time, excessive cost, and concern about damage to internal parts, the turbine may be overdamaged. Inspection and maintenance of the internal parts of the turbine are performed only in this case, which greatly affects the power generation efficiency. In general, domestic power generation facilities consist of several units, so the current working method has a problem that significant inefficiency occurs when working on multiple units.

Matters described in this background section are prepared to enhance understanding of the background of the invention, and may include matters that are not already known to those of ordinary skill in the art to which this technology belongs.

The present invention has been devised in consideration of the above points, and when the casing is separated for inspection, replacement, repair, etc. of a turbine, which is a part of the power generation facility, it is not limited in the structure and appearance of the casing, but in a narrow space An object of the present invention is to provide a power generation facility casing turning guide device that can guide the inversion (turn-over) or rotation of the casing to be easily made.

Power generation facility casing turning guide device according to an embodiment of the present invention for achieving the above object, is mounted on the power generation facility casing, a rotation support mechanism configured to rotatably support the power generation facility casing; And it may include a plurality of supports for supporting the power generation facility casing.

The rotation support mechanism may include a base, a support structure mounted on the base, and a rotation shaft rotatably mounted between the support structure and the power generation facility casing.

The position of the rotation support mechanism is adjustable by a plurality of casters, and the plurality of casters may be mounted on the base.

Each caster may include a bracket, a wheel rotatably mounted to the bracket, a stud bolt extending upwardly from the bracket, and an adjustment nut rotatably mounted to the stud bolt.

The rotation shaft is configured to be supported on the upper end of the support structure through a rotation guide block, the rotation guide block is attached to the upper end of the support structure, and the rotation guide block has a receiving groove for rotatably receiving the rotation shaft. can

The receiving groove is opened toward the rotation guide block, and by attaching a cover plate to the upper surface of the rotation guide block, the upper end of the receiving groove is closed.

A height of the receiving groove may be greater than a diameter of the rotation shaft.

The power generation facility casing is configured to rotate by a main crane, the main crane is connected to the power generation facility casing through a plurality of hoist rings, and the plurality of hoist rings may be rotatably mounted to the power generation facility casing. .

The plurality of supports may be configured to support the power generation facility casing before/after the power generation facility casing is rotated by the main crane.

The plurality of supports may include a plurality of first supports for supporting the power generation facility casing before inversion and a plurality of second supports for supporting the power generation facility casing after the inversion.

Each first support may include a base, a plurality of structural members extending upwardly from the base, and a support plate attached to upper ends of the plurality of structural members.

Each second support may include a support structure and a support plate attached to an upper end of the support structure.

A positioning member is mounted to the support plate, the positioning member extends vertically upward from the upper surface of the support plate, and the power generation facility casing may have a positioning hole corresponding to the positioning member.

The plurality of second supports may be configured to be movable by a plurality of casters, and the plurality of casters may be mounted to a lower end of the support structure.

Each caster may include a bracket, a wheel rotatably mounted to the bracket, a stud bolt extending upwardly from the bracket, and an adjustment nut rotatably mounted to the stud bolt.

According to the present invention, it is possible not only to stably guide the casing of the power generation facility to be rotated or inverted by the operation of the main crane, but also to quickly and efficiently perform the reversal or rotation of the casing in a narrow space of the power generation facility site, thereby Maintenance, inspection, etc. of the turbine of the power generation facility can be performed very quickly and easily.

In particular, the rotation support mechanism is detachably mounted on one side of the power generation facility casing, a plurality of supports for supporting the other side of the power generation facility casing are detachably mounted on the floor of the power generation facility site, and the rotation support mechanism is the power generation facility casing It stably supports rotation or reversal, and a plurality of supports can individually support the other side of the power generation facility casing before and after the reversal of the power generation facility casing, so there is no need to transport the power generation facility casing from the site of the power generation facility to the outside It can be quickly reversed at the site of the power plant.

According to the present invention, even under the condition that it is difficult to reverse the power generation facility by the crane or the lifting load of the crane is small, by detachably mounting a plurality of supports and rotation support mechanisms on the site floor of the power generation facility, the power generation facility casing can be installed with only the main crane. It can be stably reversed.

According to the present invention, since the chain or rope of the main crane is connected to the power generation facility casing through a hoist ring, etc., a phenomenon in which the chain or rope of the main crane is twisted during operation of the main crane can be reliably prevented.

1 is a perspective view showing a power generation facility casing turning guide device according to an embodiment of the present invention.
FIG. 2 is a view showing a support structure, a rotation shaft, a rotation guide block, and a cover plate of the rotation support mechanism of the power generation facility casing turning guide device shown in FIG. 1 .
3 is an exploded perspective view showing the rotation support mechanism of the power generation facility casing turning guide device shown in FIG.
4 is an exploded perspective view showing a first support and a second support of the power generation facility casing turning guide device shown in FIG.
5 is an exploded perspective view illustrating the support plate and the positioning member shown in FIG. 4 .
6 is a front view showing the front of the power generation facility casing turning guide device shown in FIG.
7 is a side view showing the side of the power generation facility casing turning guide device shown in FIG.
8 is a plan view showing the upper surface of the power generation facility casing turning guide device shown in FIG.
9 is a perspective view showing a state in which the power generation facility casing turning guide device according to an embodiment of the present invention supports the inverted power generation facility casing.
10 is a perspective view showing a first hoisting ring of the power generation facility casing turning guide device according to an embodiment of the present invention.
11 is a perspective view illustrating a first hoisting ring and a fixing block of a power generation facility casing turning guide device according to another embodiment of the present invention.
12 is a perspective view showing a power generation facility casing turning guide device according to another embodiment of the present invention.
13 is a view showing a structure in which the rotating shaft of the power generation facility casing turning guide device shown in FIG. 12 is rotatably mounted to one flange of the power generation facility casing through a pair of fixed blocks.
14 is a perspective view showing a power generation facility casing turning guide device according to another embodiment of the present invention.
15 is a view showing a structure in which the rotating shaft of the power generation facility casing turning guide device shown in FIG. 14 is rotatably mounted to one flange of the power generation facility casing through a pair of rotary guide plates.
16 is a side view showing a power generation facility casing turning guide device according to another embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. In addition, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Power generation facility casing turning guide device 10 according to the present invention may be configured to guide the power generation facility casing (1) is reversed (turn-over) or rotated by the main crane (5).

1, the power generation facility casing turning guide device 10 according to an embodiment of the present invention includes a rotation support mechanism 11 configured to rotatably support the power generation facility casing 1, and the power generation facility casing 1 ) may include a plurality of supports (12, 13) for supporting the edges.

A turbine, which is a major component of a power plant, includes a casing that protects internal parts, and the casing includes an upper casing and a lower casing coupled to each other. The flange of the upper casing is coupled to the flange of the lower casing.

According to the embodiment, the power generation facility casing 1 may be the upper casing of the turbine, and the power generation facility casing turning guide device 10 may be mounted on the floor 8 adjacent to the turbine at the power generation facility site. After the flange of the upper casing is separated from the flange of the lower casing, the upper casing may be moved to the power generation facility casing turning guide device 10 by the main crane 5 . After that, when the main crane 5 turns or rotates the upper casing, the upper casing may be guided by the power generation facility casing turning guide device 10 . Specifically, the chain or rope 6 of the main crane 5 may be connected to one side of the power generation facility casing 1, and as the main crane 5 moves vertically (lifting) and horizontally moves, the power generation facility casing 1 ) can rotate around the rotation support mechanism 11, and through this, the power generation facility casing 1 can be inverted (turn-over), and the inverted power generation facility casing 1 as shown in FIG. 9 is a plurality of It can be safely supported by the supports (12, 13).

The rotation support mechanism 11 may be mounted in a central portion adjacent to one flange of the power generation facility casing 1 , and the rotation support mechanism 11 rotatably supports the central portion adjacent to one flange of the power generation facility casing 1 . can do. In particular, the rotation support mechanism 11 prevents the power generation facility casing 1 from being separated from the main crane 5 when the power generation facility casing 1 is rotated or reversed by the main crane 5, and the power generation facility casing ( It can guide the rotation or reversal of 1).

According to one embodiment, the rotation support mechanism 11 is rotatably between the base 21, the support structure 22 mounted on the base 21, the support structure 22 and the power generation facility casing (1). It may include a rotating shaft 23 to be mounted.

Referring to FIG. 3 , the base 21 may be detachably mounted on the bottom of the lower casing or power generation facility through fasteners (anchor bolts). The base 21 may have a plurality of fastening holes 21a to which a plurality of fasteners are individually fastened.

The rotation support mechanism 11 may be configured such that its position is adjustable by a plurality of casters 50 , and the plurality of casters 50 may be mounted on the base 21 . The base 21 may have a plurality of mounting walls 21b to which a plurality of casters 50 are individually mounted, and each mounting wall 21b is formed on a vertical wall 21c extending vertically from the base 21 . may be horizontally connected to each other, and a fastening hole 21d may be formed in each mounting wall 21b. According to an example, the plurality of mounting walls 21b may be located at each corner of the base 21 . The caster 50 includes a bracket 51 , a wheel 52 rotatably mounted to the bracket 51 , a stud bolt 53 extending upward from the bracket 51 , and a screw to the stud bolt 53 . It may include a engageable adjustment nut 54 . The stud bolt 53 passes through the fastening hole 21d of the mounting wall 21b of the base 21, and the adjustment nut 54 is screwed to the stud bolt 53 on the upper surface of the mounting wall 21b, thereby being a caster. 50 may be fixed to the mounting wall 21b. By adjusting the fastening position of the adjustment nut 54 , the vertical height of the caster 50 may be relatively adjusted, and thus the vertical height of the rotation support mechanism 11 may be varied. When the position is adjusted after the base 21 is moved by the plurality of casters 50, the fastener (bolt) is fastened to the fastener hole 21a of the base 21 so that the base 21 can be fixed to the floor. have.

The support structure 22 may be configured to support the rotation shaft 23 from the base 21 at a predetermined height. The support structure 22 may include a plurality of structural members 22a, 22b, and 22c, and each structural member 22a, 22b, 22c may be formed of a rigid member such as an H-beam, a C-shaped channel, or the like. According to an example, the plurality of structural members 22a, 22b, and 22c include a plurality of vertical members 22a extending vertically from the base 21 and a plurality of inclined members connecting the vertical members 22a in an inclined direction. (22b) and a plurality of vertical members (22a) and a plurality of horizontal members (22c) for horizontally connecting the plurality of inclined members (22b) may include.

The rotation guide block 24 may be attached to the upper end of the support structure 22 , and in particular, the rotation guide block 24 may be attached to the upper end of the vertical members 22a through fasteners, welding, or the like. Referring to FIG. 2 , the rotation guide block 24 may have an accommodation groove 24a for rotatably receiving the rotation shaft 23 , and the accommodation groove 24a is opened toward the upper portion of the rotation guide block 24 . can be The receiving groove 24a may have a width W equal to or similar to the diameter D of the rotation shaft 23, and the receiving groove 24a has a height H greater than the diameter D of the rotation shaft 23. can have Accordingly, when the power generation facility casing 1 is rotated by the main crane 5, the rotating shaft 23 can smoothly guide the rotation within the receiving groove 24a. The accommodating groove 24a may have a pair of tapered surfaces 24b formed at the top thereof, and when the rotating shaft 23 is assembled to the receiving groove 24a of the rotating guide block 24, the rotating shaft 23 has one Receiving into the receiving groove 24a through the pair of tapered surfaces 24b may be guided.

A cover plate 25 may be coupled to the upper surface of each rotation guide block 24 by a plurality of fasteners, and the cover plate 25 closes the upper end of the receiving groove 24a to the receiving groove 24a. Separation of the accommodated rotation shaft 23 from the rotation guide block 24 can be prevented. The height (H) of the receiving groove (24a) can be formed larger than the diameter (D) of the rotation shaft 23, before the power generation facility casing (1) is reversed ( 0 ° position) and after the inversion (180 ° position) ), the interval G between the rotation shaft 23 and the cover plate 25 may be a value obtained by subtracting the diameter D of the rotation shaft 23 from the height H of the receiving groove 24a (G = HD) . For example, the interval G between the rotation shaft 23 and the cover plate 25 may be 30 mm.

Referring to FIG. 2 , a pair of rotation guide blocks 24 may be attached to the upper end of the support structure 22 , and the pair of rotation guide blocks 24 are provided along the width direction of the power generation facility casing 1 . can be spaced apart. Each rotation guide block 24 may have a receiving groove 24a for rotatably receiving the rotation shaft 23 . The portions adjacent to both ends of the rotation shaft 23 are individually accommodated in the receiving grooves 24a of the pair of rotation guide blocks 24 so that the rotation shaft 23 is rotatable by the pair of rotation guide blocks 24 . can be supported

Referring to FIG. 3 , the rotation shaft 23 may have a pair of stoppers 23a, and the pair of stoppers 23a may be symmetrically disposed on both left and right sides. Each stopper 23a may be spaced apart from each end of the rotation shaft 23 , and each stopper 23a may be configured to contact a side surface of the rotation guide block 24 . Each stopper 23a may protrude radially outward from the rotation shaft 23 , and in particular, each stopper 23a may be configured in an annular structure extending along the circumferential direction of the rotation shaft 23 . Each stopper 23a may be adjacent to each end of the rotation shaft 23 . Screw portions may be formed at both ends of the rotation shaft 23 , and a pair of stop nuts 23b may be screwed to each screw portion of the rotation shaft 23 . Each stop nut 23b and a corresponding stopper 23a may be disposed to face each other on both sides of each rotation guide block 24, and each stop nut 23b is coupled to each end of the rotation shaft 23. Accordingly, each stop nut 23b may be located farther from the center of the rotation shaft 23 than the corresponding stopper 23a, and each stopper 23a is the center of the rotation shaft 23 rather than the corresponding stop nut 23b. can be positioned towards According to an example, the pair of stoppers 23a may form a unitary one-piece structure with the rotation shaft 23 through casting or the like. According to another example, the pair of stoppers 23a may be coupled to the rotation shaft 23 through welding or the like.

Both ends of the rotation shaft 23 may be rotatably connected to the power generation facility casing 1 through a pair of rotation guide blocks 24 and a pair of cover plates 25 . Referring to FIG. 1 , the power generation facility casing 1 may have a center recessed space 2 recessed in its central portion and a pair of center sidewalls 2a defining the center recessed space 2 , and a pair of The center sidewall 2a may be positioned to face each other. The pair of first fixing brackets 3 may be adjacent to one side flange of the power generation facility casing 1, and the pair of first fixing brackets 3 are individually attached to the pair of center sidewalls 2a. A pair of first fixing brackets 3 may be positioned to face each other.

Referring to FIG. 2 , each stop nut 23b is screwed to each screw portion of the rotation shaft 23 , so that both ends of the rotation shaft 23 are connected to a pair of first fixing brackets 3 by a pair of stop nuts 23b. ) can be mounted individually. That is, each stop nut 23b is screwed to each end of the rotation shaft 23 , so that each end of the rotation shaft 23 can be rotatably supported by the mounting hole of each first fixing bracket 3 .

Referring to FIG. 1 , a plurality of supports 12 and 13 may be configured to support the flange of the other side of the power generation facility casing 1 before/after the power generation facility casing 1 is rotated by the main crane 5 . . A plurality of supports (12, 13) are a plurality of first support 12 for supporting the other flange of the power generation facility casing (1) before inversion and a plurality of supporting the other flange of the power generation facility casing (1) after inversion of the second support 13 may be included.

The plurality of first supports 12 may be horizontally spaced apart from the rotation support mechanism 11 . When the power generation facility casing (1) is rotatably supported through the rotation support mechanism (11), the plurality of first supports (12) before the rotation (reversal) of the power generation facility casing (1) the power generation facility casing (1) It may be configured to support the flange of the other side of the. The plurality of first supports 12 may be detachably mounted on the floor of the power generation facility through fasteners (anchor bolts).

Referring to FIG. 4 , each first support 12 is attached to a base 12a, a plurality of structural members 12b extending upward from the base 12a, and the upper end of the plurality of structural members 12b. It may include a support plate (12c). The plurality of structural members 12b may be formed of a rigid member such as an H-beam or a C-shaped channel. The support plate (12c) may be configured to be flat so as to stably contact the other side flange of the power generation facility casing (1). Since the support plate 12c is in direct contact with the flange of the other side of the power generation facility casing 1, the power generation facility casing 1 is stably supported by the plurality of first supports 12 before being reversed by the main crane 5. can

The plurality of second supports 13 may be configured to support the other flange of the power generation facility casing 1 after the power generation facility casing 1 is reversed by the main crane 5 . In particular, the plurality of second supports 13 may be disposed opposite to the plurality of first supports 12 with respect to the rotation support mechanism 11 .

Referring to FIG. 4 , each second support 13 may include a support structure 14 and a support plate 15 attached to the upper end of the support structure 14 .

Support structure 14 may include a plurality of structural members (14a, 14b, 14c), the plurality of structural members (14a, 14b, 14c) is a plurality of horizontal members (14a) adjacent to the floor of the power generation facility site and , a plurality of vertical members 14b vertically extending from the plurality of horizontal members 14a, and a plurality of inclined members 14c extending obliquely from the plurality of horizontal members 14a toward the upper end of each vertical member 14b. can be composed of The plurality of horizontal members 14a can form a rectangular frame structure by being rigidly connected to each other, and the plurality of horizontal members 14a can be separated on the floor of the power plant site through a plurality of fasteners (bolts, nuts). can be installed properly. The lower end of each vertical member 14b may be coupled to the horizontal member 14a through fasteners, welding, or the like. The lower end of each inclined member 14c is coupled to the horizontal member 14a through fasteners, welding, etc., and the upper end of each inclined member 14c is adjacent to the upper end of the vertical member 14b through fasteners, welding, etc. By being coupled to each other, each inclined member 14c can stably support each vertical member 14b in the inclined direction.

The support plate 15 may be fixed to the upper end of the vertical member 14b through a bolt 14d and a nut 14e. Referring to FIG. 5 , the positioning member 16 may be mounted on the support plate 15 , and the positioning member 16 may extend vertically upward from the upper surface of the support plate 15 . The support plate 15 may have a plurality of fastening holes 15a and 15b, and the bolt 14d and the lower threaded portion of the positioning member 16 may be inserted into the plurality of fastening holes 15a and 15b. After the bolt 14d is inserted into the fastening hole 15a of the support plate 15, the nut 14e is screwed into the threaded portion of the bolt 14d from the bottom of the support plate 15, so that the support plate 15 is It may be firmly fixed to the upper end of the vertical members (14b). After the lower threaded portion 16a of the positioning member 16 is inserted into the fastening hole 15b of the support plate 15, the fixing nut 16b is screwed to the lower threaded portion of the positioning member 16, whereby the positioning member 16 ) can be firmly fixed to the support plate (15).

9, the power generation facility casing (1) may have a positioning hole (1a) corresponding to the positioning member (16), the positioning hole (1a) is formed at the edge of the flange of the other side of the power generation facility casing (1) can be After the power generation facility casing (1) is inverted, the positioning member 16 is inserted into the positioning hole (1a) when supported by the second support (13) so that the power generation facility casing (1) is inverted after the positioning is can be done precisely.

Referring to FIG. 9 , in a state in which the power generation facility casing 1 is inverted, the four second supports 13 may be disposed to support the four corner portions of the power generation facility casing 1 .

Referring to FIG. 4 , the plurality of second supports 13 may be configured to be movable by a plurality of casters 60 , and the plurality of casters 60 may be mounted at the lower end of the support structure 14 . . The plurality of casters 60 may be mounted on the horizontal member 14a of the support structure 14 . The support structure 14 may have a plurality of mounting plates 68 , and each mounting plate 68 may be attached to the horizontal member 14a through welding, fasteners, or the like. Each mounting plate 68 may have a fastening hole 68a. The caster 60 includes a bracket 61 , a wheel 62 rotatably mounted to the bracket 61 , a stud bolt 63 extending upward from the bracket 61 , and a screw to the stud bolt 63 . It may include a engageable adjustment nut (64). The stud bolt 63 passes through the fastening hole 68a of the mounting plate 68, and the adjustment nut 64 is screwed to the stud bolt 63 on the upper surface of the mounting plate 68, whereby the caster 60 is mounted. It may be fixed to the plate 68 . By adjusting the fastening position of the adjustment nut 64 , the vertical height of the caster 60 may be relatively adjusted, and thus the vertical height of the second supports 13 may be varied. When the position of the support structure 14 is adjusted after moving by the plurality of casters 60 , the support structure 14 may be detachably mounted on the floor of the power generation facility site through a plurality of fasteners.

1, 6 to 9, the hook block (5a, hook block) of the main crane (5) can be connected to the adjacent part of the flange of the other side of the power generation facility casing (1) through a chain or rope (6) have. Power generation facility casing turning guide device 10 according to an embodiment of the present invention may have a plurality of hoist rings 17 and 18, and the hook block 5a of the main crane 5 is a chain or rope 6 It can be connected to a plurality of hoisting rings (17, 18) through.

7 to 9 , a pair of first hoisting rings 17 may be mounted on the portion adjacent to the flange of the other side of the power generation facility casing 1 , and the pair of first hoisting rings 17 are They may be sufficiently spaced apart from each other. The pair of second hoist rings 18 may be individually connected to the pair of first hoist rings 17 , and thus the pair of second hoist rings 18 may be sufficiently spaced apart from each other. The hook block 5a of the main crane 5 may be connected to the pair of second hoisting rings 18 via a chain or rope 6 . The power generation facility casing (1) may include a pair of second fixing brackets (4) individually attached to the pair of center sidewalls (2a) through welding or the like, and a pair of second fixing brackets (4) may be adjacent to the flange of the other side of the power generation facility casing (1), and a pair of second fixing brackets (4) are individually attached to a pair of center side walls (2a), so that a pair of second fixing brackets (4) may be positioned to face each other.

Referring to FIG. 10 , the pair of first hoist rings 17 may be fixedly connected to the pair of support blocks 19 . The support block 19 may have a rotation shaft 19a, and the first hoist ring 17 and the support block 19 may rotate together around the rotation axis of the rotation shaft 19a. A part of the rotation shaft 19a may be formed with a threaded portion. After the rotation shaft 19a of the support block 19 is inserted into the mounting hole of the second fixing bracket 4, the nut 19b is screwed into the threaded portion of the rotation shaft 19a, so that the first hoisting string 17 is 2 It can be rotatably supported by the fixing bracket (4).

Referring to FIG. 11 , the first hoist ring 17 may be rotatably mounted to the fixing block 31 through the support block 19 . The fixing block 31 may be directly fixed to the flange of the other side of the power generation facility casing 1 through a fastener or the like.

As such, the chain or rope 6 of the main crane 5 is connected to the other edge of the power generation facility casing 1 through a plurality of hoist rings 17 and 18, so that the chain or rope 6 is twisted reliably can be prevented.

12 shows a power generation facility casing turning guide device according to another embodiment of the present invention. 12, the power generation facility casing turning guide device according to another embodiment of the present invention may further include an auxiliary block 35 mounted on the floor 8 of the power generation facility site. The auxiliary block 35 may have a certain height, and thus the upper surface of the auxiliary block 35 is higher than the floor 8 of the power generation facility site. The rotation support mechanism 11 and the plurality of first supports 12 may be mounted on the upper surface of the auxiliary block 35 . The rotation shaft 23 of the rotation support mechanism 11 may be rotatably supported on the bottom surface of one side flange of the power generation facility casing 1 through a pair of fixed blocks 37 . The pair of fixing blocks 37 may be fixed to the bottom surface of the flange of one side of the power generation facility casing 1 through fasteners or the like. 13, each fixed block 37 is a fixed portion (37a) fixed to the bottom surface of one side of the flange of the power generation facility casing (1) through a fastener and a vertical portion extending vertically from the fixing portion (37a) ( 37b). The fixed portion 37a may extend horizontally along one side flange of the power generation facility casing 1 , and the vertical portion 37b may face toward each center side wall 2a of the power generation facility casing 1 , vertical The portion 37b may have a receiving hole 37c for rotatably receiving each end of the rotation shaft 23 . The receiving hole 37c may be aligned with the receiving groove 24a of the rotation guide block 24 .

According to another embodiment of the present invention, according to another embodiment of the present invention, the rotation shaft 23 of the rotation support mechanism 11 is a pair of center sidewalls 2a of the power generation facility casing 1 through a pair of rotation guide plates 38 . ) can be mounted rotatably with respect to A pair of rotation guide plates 38 may be fixed to a pair of center sidewalls 2a of the power generation facility casing 1 .

15 , the third fixing bracket 3a and the fourth fixing bracket 3b may be attached to each center side wall 2a through welding, etc., and the third fixing bracket 3a and the fourth fixing bracket (3b) may be spaced apart along the longitudinal direction of the power generation facility casing (1). Both ends of each rotation guide plate 38 may be fixed to the third fixing bracket 3a and the fourth fixing bracket 3b. A front side mounting hole 38b may be formed at the front end of each rotation guide plate 38 . The guide pin 39a is inserted into the front mounting hole 38b of each rotation guide plate 38, and the fixing ring 39b is fixed to the guide pin 39a, so that the front end of each rotation guide plate 38 is It may be fixedly mounted to the third fixing bracket (3a). A rear mounting hole 38c may be formed at the rear end of each rotation guide plate 38 . The guide pin 39c is inserted into the rear mounting hole 38c of each rotation guide plate 38, and the fixing ring 39d is fixed to the guide pin 39c, so that the rear end of each rotation guide plate 39 is It may be fixedly mounted to the fourth fixing bracket (3b). Each rotation guide plate 38 may have an accommodating hole 38a formed in the central portion thereof, and the accommodating hole 38a may rotatably receive each end of the rotation shaft 23 , and the receiving hole 38a is It may be aligned with the receiving groove (24a) of the rotation guide block (24).

Referring to Figure 16, the power generation facility casing turning guide device according to another embodiment of the present invention may be arranged around the lower casing (1c) of the turbine. The rotation support mechanism 11 may be mounted adjacent to one flange of the upper casing 1 , and the plurality of first supports 12 may be configured to support the other flange of the lower casing 1c . After the flange of the power generation facility casing (1), which is the upper casing, is separated from the flange of the lower casing (1c), the upper casing power generation facility casing (1) is reversed or rotated by the main crane (5), which is the upper casing power generation facility The casing 1 can be inverted directly from the lower casing 1c.

According to the present invention, it is possible not only to stably guide the casing of the power generation facility to be rotated or inverted by the operation of the main crane, but also to quickly and efficiently perform the reversal or rotation of the casing in a narrow space of the power generation facility site, thereby Maintenance, inspection, etc. of the turbine of the power generation facility can be performed very quickly and easily.

In particular, the rotation support mechanism is detachably mounted on one side of the power generation facility casing, a plurality of supports for supporting the other side of the power generation facility casing are detachably mounted on the floor of the power generation facility site, and the rotation support mechanism is the power generation facility casing It stably supports rotation or reversal, and a plurality of supports can individually support the other side of the power generation facility casing before and after the reversal of the power generation facility casing, so there is no need to transport the power generation facility casing from the site of the power generation facility to the outside It can be quickly reversed at the site of the power plant.

According to the present invention, even under the condition that it is difficult to reverse the power generation facility by the crane or the lifting load of the crane is small, by detachably mounting a plurality of supports and rotation support mechanisms on the site floor of the power generation facility, the power generation facility casing can be installed with only the main crane. It can be stably reversed.

According to the present invention, since the chain or rope of the main crane is connected to the power generation facility casing through a hoist ring, etc., a phenomenon in which the chain or rope of the main crane is twisted during operation of the main crane can be reliably prevented.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1: Power generation facility casing 1a: Positioning hole
2: recessed space 2a: side wall
5: Main crane 6: Rope
10: Power generation facility casing turning guide device
11: rotation support mechanism 12: first support
13: second support 14: support structure
14a: horizontal member 14b: vertical member
14c: inclined member 15: support plate
16: positioning member 17: first hoist string
18: second hoist string 19: support block
21: base 21a: fastener
21b: mounting wall 21c: vertical wall
21d: fastening hole 22: support structure
22a: vertical member 22b: inclined member
22c: horizontal member 23: rotation shaft
23a: stopper 23b: stop nut
24: rotation guide block 24a: receiving groove
24b: tapered surface 25: cover plate
31: fixed block 35: auxiliary block
37: fixed block 38: rotation guide plate
50: caster 51: bracket
52: wheel 53: stud bolt
54: adjustment nut 60: caster
61: bracket 62: wheel
63: stud bolt 64: adjustment nut
68: mounting plate

Claims (15)

a rotation support mechanism mounted on one side flange of the power generation facility casing and configured to rotatably support the one side flange of the power generation facility casing; and
a main crane connected to a portion adjacent to the flange of the other side of the power generation facility casing, and configured to move vertically and horizontally;
a first support for supporting the other flange of the power generation facility casing before the power generation facility casing is reversed by the main crane; and
a second support configured to support the flange of the other side of the power generation facility casing after the power generation facility casing is reversed by the main crane; and
The first support and the second support is a power generation facility casing turning guide device configured to be spaced apart with the rotation support mechanism therebetween. The method according to claim 1,
The rotary support mechanism includes a base, a support structure mounted on the base, and a rotary shaft rotatably mounted between the support structure and the power generation facility casing. 3. The method according to claim 2,
The rotation support mechanism is configured to be adjustable in its position by a plurality of casters, the plurality of casters is a power generation facility casing turning guide device mounted to the base. 4. The method according to claim 3,
Each caster includes a bracket, a wheel rotatably mounted to the bracket, a stud bolt extending upward from the bracket, and an adjustment nut rotatably mounted to the stud bolt. 3. The method according to claim 2,
The rotation shaft is configured to be supported on the upper end of the support structure through a rotation guide block,
The rotation guide block is attached to the upper end of the support structure, the rotation guide block is a power generation facility casing turning guide device having a receiving groove for rotatably receiving the rotation shaft. 6. The method of claim 5,
The accommodating groove is opened toward the rotation guide block, and a cover plate is attached to the upper surface of the rotation guide block, whereby the upper end of the accommodating groove is closed. 6. The method of claim 5,
The height of the receiving groove is a power generation facility casing turning guide device that is formed larger than the diameter of the rotation shaft. The method according to claim 1,
The power generation facility casing is configured to rotate by a main crane,
The main crane is connected to a portion adjacent to the flange of the other side of the power generation facility casing through a plurality of hoist rings,
The plurality of hoist rings is a power generation facility casing turning guide device that is rotatably mounted on the power generation facility casing.
delete delete The method according to claim 1,
Each first support is a power generation facility casing turning guide device comprising a base, a plurality of structural members extending upwardly from the base, and a support plate attached to the upper end of the plurality of structural members. The method according to claim 1,
Each second support is a power generation facility casing turning guide device comprising a support structure and a support plate attached to the upper end of the support structure. 13. The method of claim 12,
A positioning member is mounted to the support plate, the positioning member extends vertically upward from the upper surface of the support plate, and the power generation facility casing is a power generation facility casing turning guide device having a positioning hole corresponding to the positioning member. 14. The method of claim 13,
The plurality of second supports are configured to be movable by a plurality of casters,
The plurality of casters is a power generation facility casing turning guide device mounted on the lower end of the support structure. 15. The method of claim 14,
Each caster includes a bracket, a wheel rotatably mounted to the bracket, a stud bolt extending upward from the bracket, and an adjustment nut rotatably mounted to the stud bolt.

Images