KR102086002B1 - Method for Rotating of Precast Arch Segment using Rotating Force by Eccentricity - Google Patents

Abstract

The present invention is a problem in the prior art by easily and safely rotating the segment arch segment using the rotational force generated by the eccentricity in the state in which the segment arch segment is placed on the device in the transfer and mounting the segment arch segment Rotation of the segment arch segment and rotation of the segment arch segment using it can solve the cost increase caused by the use of a large number of lifting equipments and the high level of skill required, and further prevent the concrete surface damage of the segment arch segment Method ".
In the present invention, it comprises a rotary stage 2 and a fixed frame 3, when the segmented arch segment 100 is lifted into the air and placed on the rotary stage 2 while maintaining the horizontal arrangement state, eccentricity As a result, the rotating arranging base 2 is rotated and the segment arch segment 100 in the horizontal arrangement is rotated in the vertical arrangement.

Description

Method for Rotating of Precast Arch Segment using Rotating Force by Eccentricity}

The present invention relates to an apparatus and a method for rotating a segment arch segment forming a precast arch structure. Specifically, the present invention relates to a precast arch structure, which is made of a precast concrete member and continuously coupled to each other in an extending direction of an arch shape. In transporting and mounting the "segment arch segment" to the site, it is possible to easily and safely rotate the segment arch segment by using the rotational force generated by the eccentricity while the segment arch segment is placed on the device, thereby reducing many of the problems of the prior art. Rotation device of segmented arch segment and method of rotating segmented arch segment using the same, which can solve the increase in cost according to the use of a number of lifting equipments and the need for advanced skill, and further prevent the damage of concrete surface of the segmented arch segment "About The.

A method of constructing a tunnel structure that is used as an open tunnel, an ecological passage, etc. by arranging a plurality of precast arch structures having an arch shape adjacent to each other is proposed through Korean Patent Registration No. 10-1491952. Such a precast arch structure transfers the "segment arch segment" made of precast concrete members in the factory in the form of dividing the arch shape into a plurality of sites, and then the segment arch segments are continuously connected to each other in the extension direction of the segment. It is constructed by joining.

The segmented arch segment is a convex curved member having a predetermined width in the direction in which the tunnel extends and a predetermined length in the direction in which the arc of the arch extends. For convenience, the direction in which the arc of the arch extends throughout the present specification including the claims is described as "length direction", and the direction orthogonal to this in the horizontal plane, that is, the direction corresponding to the width of the segment arch segment is described as "width direction". do.

Generally, the segmented arch segment is manufactured in a factory with one side (second side) in the width direction lying on the ground. In other words, the segmented arch segment is produced in such a manner that the width direction becomes vertical. Therefore, when the segment arch segment manufactured in this state is transported to the site and mounted to form a precast arch structure, the segment arch segment should be rotated so that the width direction becomes horizontal. For convenience, in this specification, the state in which the segment arch segment is placed so that the width direction becomes the vertical direction, that is, the second side is in contact with the ground when manufactured, is referred to as a "horizontal arrangement state", and the segment is formed so that the width direction becomes the horizontal direction. The state in which the arch segment is placed is described as "vertical arrangement state".

Conventionally, when a segment arch arch is mounted on-site, the length of the lifting rope connected to each of the plurality of salvage equipments can be determined in a state in which the segment arch segments are fully lifted into the air using a plurality of lifting equipments (for example, a lifting crane). By adjusting the segment arch segment was rotated. 15 to 17 are schematic perspective views sequentially illustrating a process of rotating the segment arch segment 100 according to the prior art, respectively. For convenience of description, the arcuate convex outer surface of the segment arch segment 100 is denoted by reference numeral 130, and the first side to which the lifting rope is coupled among the widthwise sides of the segment arch segment 100 is denoted by numeral 110. Indicated. For reference, the state in which the segmented arch segment is placed as shown in FIG. 15 corresponds to the "horizontal arrangement state", and the state in which the segmented arch segment is placed as shown in FIG. 17 corresponds to the "vertical arrangement state".

In order to rotate the segmented arch segment 100 in a horizontally arranged state as shown in FIG. 15 to be in a vertically arranged state as shown in FIG. 17, first, a plurality of outer surfaces are formed on the outer surface 130 of the segmented arch segment 100. The lifting rope 2a is connected, and a plurality of side lifting ropes 2b are connected to the widthwise side surface (first side surface) 110 of the segment arch segment 100. In order to connect the lifting rope, the lifting ring 4 is fixed to the outer surface 130 and the first side 110 of the segment arch segment 100, respectively, using a lifting link 40 using a lifting link 40. The lower end of the lifting rope is connected between the lifting ring (4). As shown in FIG. 15, in the state in which the other side in the width direction of the segment arch segment 100 is placed to face the ground or the transport vehicle, the segment arch arch segment 2 may be pulled up by pulling both the outer lifting rope 2a and the side lifting rope 2b. 100) is floated in the air in a horizontal arrangement. Subsequently, the segmented arch segment 100 is rotated by pulling the outer lifting rope 2a upward as shown in FIG. 16 or angling the side lifting rope 2b further downward. As shown in FIG. 17, the arcuate convex outer surface 130 of the segmented arch segment 100 is installed in the designed position by making it in a vertically placed state looking upward.

However, in the lifting and rotation mounting process of the segment arch segment 100 according to the prior art, the outer lifting rope (2a) and the side lifting rope (2b) must move in different forms, respectively, the outer lifting rope (2a) and the side The lifting equipment for adjusting the movement of each of the lifting ropes 2b should be separated. That is, the lifting equipment for adjusting the outer lifting rope 2a and the lifting equipment for adjusting the side lifting rope 2b are separately required. Therefore, in the prior art, a large number of lifting equipments are required, and accordingly, a large amount of lifting equipment is required, and a skilled worker is required to move the outer lifting rope 2a and the side lifting rope 2b precisely in different forms. Since it is necessary, the construction efficiency is lowered and the cost is greatly increased.

Above all, in the prior art, the lifting link 40 and the lifting rope come into contact with the outer surface and the first side 110 of the segment arch segment 100 in the process of rotating the segment arch segment 100 as described above. Damage such as falling off occurs on the concrete surface of the segment 100. That is, in the position indicated by the circle R in FIGS. 15 and 17, the lifting link 40 and the lifting rope come into contact with the outer surface 130 and the first side 110 of the segment arch segment 100, and the segment arch segment 100 The lifting link 40 and the lifting rope is in contact with the outer surface of the segment arch segment 100 in the process of rotation of the) will cause a problem that the damage to the concrete surface of the segment arch segment (100).

Furthermore, in the process of pulling up the lifting rope as described above, the segment arch segment 100 itself may also rotate in the horizontal direction, so that the work itself becomes unstable as well as the segment arch arch segment 100 that rotates in the horizontal direction. There is also a problem in that the risk of a safety accident that can collide with workers or surrounding objects is very high.

Republic of Korea Patent Publication No. 10-1491952 (2015. 02. 09. announcement).

The present invention was developed to overcome the limitations of the prior art as described above, in order to build a precast arch structure using the segment arch segment, the segment arch segment is transported to the site so that the width direction of the segment arch segment becomes a horizontal direction. In the rotation, it is an object of the present invention to provide a technology that can improve the construction efficiency and reduce the cost by allowing the segmented arch segment to be rotated stably and easily even with a small number of lifting equipment.

In another aspect, the present invention by minimizing the direct contact of the lifting link and the lifting rope in the segment arch segment in the process of rotating the segment arch segment, to provide a technique that can prevent the concrete surface damage of the segment arch segment that occurred in the prior art For the purpose of

Furthermore, an object of the present invention is to provide a technique capable of preventing horizontal rotation of the segment arch segment itself and the occurrence of a safety accident.

In order to achieve the above object, in the present invention, as a rotating device for rotating the segment arch segment made of a convex curved precast concrete member having a width in the direction in which the arc of the arch extends, the segment arch segment It is placed in a horizontal arrangement state and comprises a rotating base for making the segment arch segment by vertical rotation, and a fixed frame rotatably coupled to the top of the rotating base, the segment arch segment, the horizontal arrangement It is lifted into the air while being maintained and placed on the rotating cradle, and the position where the segment arch segment is placed on the rotating cradle is eccentric from the center of gravity of the segment arch segment, and rotated by the eccentricity of the position where the segment arch segment is placed. As the cradle rotates, it is in horizontal position. Segmental arch segment is provided with a rotating device of segment arch segments being rotated in a vertical arrangement.

In addition, in the present invention, in order to achieve the above object, as a rotation method for rotating a segment arch segment made of a convex curved precast concrete member having a width and a length in the direction in which the arc of the arch extends, the segment arch segment Is placed in a horizontal arrangement state and uses a rotating device including a rotating base that makes the segment arch segment into a vertical arrangement state by rotation, and a fixed frame rotatably coupled to the top of the rotating base. Lifting the segmented arch segment into the air while maintaining the horizontal placement of the segment; Placing the lifted segment arch segment on the rotation base in a horizontal arrangement, wherein the segment arch segment is placed on the rotation base so that the position where the segment arch segment is placed on the rotation base is eccentric from the center of the segment arch segment; And causing the segment arch segment to be rotated to the vertical arrangement state while the rotation base is rotated by the eccentricity of the position at which the segment arch segment is placed, thereby providing a rotation method of the segment arch segment. .

In the rotating device and the rotating method of the present invention described above, the rotating support includes an inner support member for supporting an arcuate concave inner surface of the segment arch segment when the segment arch segment is laid or when rotating the segment arch segment, and the segment arch. A side support member coupled to the inner support member orthogonal to the inner support member such that one side of the segment in the width direction is placed; A first hinge portion is formed on the rear surface of the inner surface support member, and a second hinge portion is provided at the upper end of the fixing frame, and the first hinge portion and the second hinge portion are hinged to be coupled to each other so that the rotating base can rotate. In particular, the other end portion of the side support member may be further provided integrally with an anti-separation protrusion protruding in parallel with the inner surface support member to prevent the segment arch segment from being separated from the side support member. A pressure fixing member made of a rod member may be further provided to penetrate the separation preventing protrusion so that the segment may be pressed against the outer surface of the segment arch segment while being placed on the side support member.

In the present invention, the lifting equipment for adjusting the side lifting ropes is only necessary when the segment arch segment is placed on the rotating device, and since a separate outer lifting rope is not required, it is necessary to rotate the segment arch segment in comparison with the prior art. It is possible to reduce the number and manpower of the lifting equipment required, thereby significantly reducing the cost and significantly improving the construction efficiency.

In particular, in the present invention, the lifting link and the lifting rope installed for lifting the segment arch segment can be prevented from coming into close contact with the surface of the segment arch segment or to collide with the lifting arch segment. Alternatively, the effect of preventing damage to the concrete surface of the segmented arch segment due to the lifting link and the lifting rope is exerted.

In addition, the present invention also has the advantage that it is possible to solve the problems of the prior art that the segment arch arch itself rotates in the horizontal direction in the process of pulling up the lifting rope to cause a safety accident.

1 and 2 are schematic perspective views showing different directions of looking at the rotating apparatus according to the first embodiment of the present invention, respectively.
3 is a schematic perspective view illustrating a state in which the rotating device of FIG. 1 rotates.
Figure 4 and Figure 5 is a schematic perspective view showing a different direction of looking at the segmented arch segment placed in a horizontal arrangement state on the rotary cradle of the rotary device in the present invention, respectively.
FIG. 6 is a schematic cross-sectional view taken along arrow AA of FIG. 4.
Figure 7 is a schematic perspective view showing a state in which the rotating cradle of the rotating device according to the invention rotates.
FIG. 8 is a schematic cross-sectional view taken along the arrow BB of FIG. 7.
9 and 10 are schematic perspective views showing different directions in which the segment arch arch segment is viewed in a vertically disposed state by the rotation of the rotary base in the present invention, respectively.
FIG. 11 is a schematic cross-sectional view taken along the arrow CC of FIG. 9.
12 is a schematic perspective view of a rotating apparatus according to a second embodiment of the present invention.
FIG. 13 is a schematic perspective view corresponding to FIG. 4 showing that two rotary devices of the present invention are used to rotate one segmented arch segment. FIG.
14 is a schematic perspective view corresponding to FIG. 1 showing a rotating apparatus according to another embodiment of the present invention, in which a plurality of fixing frames are provided in one rotating cradle.
15 to 17 are schematic perspective views sequentially illustrating a process of rotating segment arch segments according to the prior art, respectively.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described. Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is described as one embodiment, whereby the technical spirit of the present invention and its core configuration and operation are not limited.

1 and 2 are schematic perspective views showing different directions of looking at the rotating apparatus 1 according to the first embodiment of the present invention for rotating the segmented arch segment, respectively, and in FIG. A schematic perspective view is shown showing a state in which the rotating device 1 rotates. Rotating device 1 according to the invention, the segment is placed in the horizontal arrangement of the segment arch 100, the rotation stage (2) to make the segment arch segment 100 in the vertical arrangement state by the rotation, and the rotation stage (2) comprises a fixed frame (3) rotatably coupled to the top.

Specifically, the rotation base 2 is in close contact with the arcuate concave inner surface of the segment arch segment 100 when the segment arch segment 100 is placed or when the segment arch segment 100 is rotated. It is coupled to the inner surface support member 20 perpendicular to the inner surface support member 20 so that the inner surface support member 20 for supporting the inner surface and one side surface (second side surface) in the width direction of the segment arch segment 100 are placed. It comprises a side support member 21. The first hinge portion 22 is formed on the rear surface of the inner surface supporting member 20 so that the first hinge portion 22 is hinged with the second hinge portion 35 provided at the upper end of the fixing frame 3, and thus the first and second hinge portions The inner support member 20 is rotatable in the state shown in FIG. 3 from the state shown in FIGS. 1 and 2 by the rotatable hinge coupling between the 22 and 35. Of course, the inner support member 20 can also rotate in the state shown in Figures 1 and 2 in the state shown in FIG.

The side support member 21 is a member having one end integrally formed with the inner surface support member 20 and disposed to be orthogonal to the inner surface support member 20, and the second side surface of the segment arch segment 100 is the side support member. (21) directly above. If necessary, the other end of the side support member 21 is prevented from protruding in parallel with the inner surface support member 20 to prevent the segment arch segment 100 from being separated from the side support member 21. Protruding portion 24 may be provided integrally. Furthermore, if necessary, the pressing fixing member 25 may be further provided to closely contact the outer surface of the segment arch segment 100 while the segment arch segment 100 is placed on the side support member 21. As illustrated in the drawings, the pressure fixing member 25 may be formed of a rod member that penetrates through the separation preventing protrusion 24. In this case, it is preferable that the contact plate 250 is provided at an end portion (an end in close contact with the segment arch segment) of the rod member constituting the pressing fixing member 25. The pressure fixing member 25 made of a rod member may be penetrated while having a screw coupling to the release preventing protrusion 24, and when the release preventing protrusion 24 is rotated, the pressure fixing member 25 may be rotated by screwing. While advancing toward the support member 20, it is in close contact with the outer surface of the segment arch segment 100.

The fixed frame 3 is a member standing vertically on the ground, and is provided with a second hinge portion 35 at an upper end thereof so that the inner support member 20 is hinged to be rotatable. If necessary, when the inner support member 20 is rotated from the vertical state to the horizontal state, the inner support member 20 is held in close contact with the rear surface of the inner support member 20 to stably maintain the horizontal state of the inner support member 20. Supporting projections 34 may be provided on the upper surface of the fixing frame (3).

The fixed frame 3 may also be configured such that its upper end can move up and down in the vertical direction. That is, in the embodiment shown in the drawings, the fixed frame 3 in the vertical direction is divided into an upper end portion 31 capable of raising and lowering, and a lower end portion 32 for supporting it, and the expansion and contraction apparatus 38 inside the lower end portion. Is built in, and the upper end portion 31 is coupled to the expansion and contraction device 38, so that the upper end portion 31 is moved up and down by the expansion and contraction of the expansion and contraction device 38. When the vertical height of the fixed frame 3 can be changed by the structure of the elevating and lowering of the upper end 31, the rotating apparatus 1 of the present invention with respect to the segment arch segment 100 of various sizes. Will be available. That is, the vertical height required to perform the rotating operation by mounting the segment arch segment 100 in the air in the rotating device (1) depends on the size, curvature, etc. of the segment arch segment 100, the fixed frame (3) as described above When the vertical height can be changed, the segmented arch segment 100 of various sizes and shapes can be rotated by the rotating apparatus 1 of the present invention, thereby increasing the versatility of the apparatus.

Next, with reference to FIGS. 4 to 11 will be described a specific method step for rotating the segment arch segment 100 from the horizontal arrangement to the vertical arrangement using the rotary device 1 of the present invention as described above.

4 and 5 are schematic perspective views showing different directions in which the segment arch arch 100 is placed in the horizontal arrangement state on the rotary stage 2 of the rotating apparatus 1, respectively. 4 shows a schematic cross sectional view along arrow AA of FIG. 4.

First, the segmented arch segment 100, which has been transported in the horizontal arrangement state, is lifted into the air while maintaining the horizontal arrangement state, and is placed on the rotary base 2. At this time, one side surface (second side surface) in the width direction at the arcuate center portion of the segment arch segment 100 is placed on the side support member 21 of the rotary base 2. Specifically, in the segmented arch segment 100 in a horizontally arranged state, a plurality of side lifting ropes 2b are connected to the other side surface (first side surface) 110 in the width direction. As in the prior art, the lifting ring 4 is fixedly installed on the first side 110 of the segment arch segment 100, and the lower end of the side lifting rope 2b is removed using a lifting link 40. The lifting ring 4 can be connected. However, in the present invention, unlike the prior art, it is not necessary to connect the lifting rope to the outer surface 130 of the segment arch segment 100 in advance.

In this way, the side lifting rope 2b is connected to the first side 110 of the segment arch segment 100, and the segment arch arch 100 is horizontal by pulling the side lifting rope 2b using a lifting device such as a crane. Lifted into the air to maintain the arrangement, so that the widthwise one side (second side) is placed on the side support member 21 at the arch-shaped center portion of the segment arch segment 100 as shown in FIGS. The segmented arch segment 100 is installed on the rotary base 2 of the rotating apparatus 1. When the release preventing protrusions 24 are provided on the side support member 21, the segment arch segments 100 are placed in the interval between the inner support member 20 and the release preventing protrusions 24, and are fixed in pressure. If the member 25 is further provided, the pressure fixing member 25 advances toward the segment arch segment 100 in a state in which the segment arch segment 100 is placed on the side support member 21. It may be in close contact with the outer surface 130, through which the segment arch segment 100 is stably positioned on the rotary cradle (2).

FIG. 7 is a schematic perspective view showing a state in which the rotating base 2 of the rotating device 1 rotates, and FIG. 8 is a schematic cross-sectional view taken along the arrow B-B of FIG. 7. Since the position where the segment arch segment 100 is placed on the rotation support base 2 is out of the center of gravity of the segment arch segment 100, an eccentricity is generated, and when the tension force which is pulling the side lifting rope 2b is reduced, it is caused by the eccentricity. The rotating base 2 naturally rotates. That is, the inner support member 20, which is in the vertically upright position in FIGS. 4 to 6 without rotation, is rotated as shown in FIGS. 7 and 8 by the eccentricity of the position where the segment arch segment 100 is placed. As a result, the segment arch segment 100 placed on the rotation support 2 naturally rotates. At this time, the inner surface supporting member 20 is in close contact with the inner surface of the segment arch segment 100 to support the segment arch segment 100. While the segment arch segment 100 is rotated, it is preferable that the rotation operation of the segment arch segment 100 proceeds while being tensioned by applying a predetermined tensile force to the side tension rope 2b continuously. In this case, the tensile force exerted on the side tension rope 2b may not be a very large tensile force as when lifting the segment arch segment 100 in the prior art, and the side arch while the segment arch segment 100 rotates. The tensile force applied to the lifting rope 2b may be appropriately adjusted in accordance with the development situation. Of course, the side lifting rope (2b) may be completely loosened.

9 and 10 are schematic perspective views showing different directions in which the rotation base 2 is completely rotated following the state of FIG. 7 to view the segmented arch segment 100 in the vertically placed state. FIG. 11 is a schematic cross-sectional view taken along arrow CC of FIG. 9. When the rotation support 2 rotates to reach the horizontal state of the inner support member 20, the inner surface of the segment arch segment 100, which is in close contact with the inner support member 20, comes to a horizontal position. The arch segment 100 is in a vertically placed state as shown in FIGS. 9 to 11. As mentioned above, during this process the side lifting rope 2b does not need to be subjected to a very high tensile force as in the prior art when lifting the segmented arch segment 100. That is, in the present invention, since the segment arch segment 100 is rotated together with the rotary base 2 in a state supported by the inner support member 20 and the side support member 21 by being placed on the rotary support 2, the side lifting The rope 2b may be in a loose state or a tension force applied to the side lifting rope 2b such that the lifting link 40 and the side lifting rope 2b do not touch the surface of the segment arch segment 100. It is okay. Of course, the tension applied to the side lifting rope 2b while the segmented arch segment 100 is rotated may be appropriately adjusted according to the development situation.

Therefore, in the present invention, the lifting arch 40 and the lifting rope are segmented arch segment 100 in the process of rotation of the segment arch segment 100 in which the segment arch segment 100 is completely vertically disposed as shown in FIGS. 9 to 11. It will not be in close contact with the surface of the), and thus unlike the prior art it is possible to prevent the occurrence of damage to the concrete surface of the segment arch segment 100 due to the strong contact of the lifting link 40 and the lifting rope.

In the prior art, the outer lifting rope 2a must be provided separately from the side lifting rope 2b for the rotation of the segment arch segment 100, and the additional lifting equipment such as a crane for adjusting this due to the use of the additional lifting rope. And more manpower was required, but in the present invention, the lifting device for adjusting the side lifting rope (2b) only need to be placed only when placing the segmented arch segment 100 on the rotating device (1), a separate outer lifting rope (2a) ) Is not necessarily more necessary, which can reduce the number and manpower of the lifting equipment, thereby significantly reducing the cost.

After the segmented arch segment 100 is vertically arranged as shown in FIGS. 9 to 11, the segmented arch segment 100 is separated from the rotating device 1 to construct a necessary installation site, that is, a precast arch structure. You just need to move to a place to do it. To this end, a separate lifting rope may be coupled to the segment arch segment 100, but after releasing the side lift rope 2b from the first side 110 of the segment arch segment 100, the segment arch segment 100 It may be used in a state in which the position is changed by being coupled to the outer surface 130. That is, the side lifting rope 2b separated from the first side 110 of the segment arch segment 100 is coupled to the lifting ring 4 provided on the outer surface 130 of the segment arch segment 100, and then the side lifting By lifting the rope (2b) to separate the segmented arch segment 100 in the vertical state from the rotating device (1) it can be moved to the factory.

 If necessary, the vertical length of the rotating device 1 is reduced so that the segmented arch segment 100 is placed on the ground in a vertical arrangement state, and then the position change and lifting of the side lifting rope 2b can be performed. It may be. That is, when the fixed frame 3 is divided into the upper end 31 and the lower end 32, and has an expansion and contraction device 38 for raising and lowering the upper end 31, the segment arch segment 100 rotates. After the completion of the vertical arrangement state, the expansion and contraction device 38 is contracted to lower the upper end 31 so that both longitudinal ends of the segmented arch segment 100 are in contact with the ground, and then the side lifting rope 2b as described above. ) Can be changed and lifted. As described above, in the state in which the segmented arch segment 100 is placed on the ground, subsequent work can be more stably performed, and it is possible to effectively prevent inadvertent damage such as breaking of the segmented arch segment 100. However, the fixed frame 3 does not necessarily have to have such a configuration that the vertical length can be stretched.

On the other hand, in the drawings for the first embodiment of the present invention, both the inner surface support member 20 and the side support member 21 of the rotation support 2 is shown as being made of a plate-shaped member, in the present invention The inner surface support member 20 and the side support member 21 are members supporting the concave inner surface and the second side surface of the segmented arch segment 100, respectively, and the shape thereof is not limited to the plate-shaped member, and the skeleton-shaped member. It may be made of a frame member. FIG. 12 is a schematic perspective view of the rotating apparatus 1 according to the second embodiment of the present invention in which the configurations of the inner surface support member 20 and the side support member 21 are changed. As shown in FIG. 12, in the rotary holder 2 of the rotating apparatus 1, the inner surface supporting member 20 and the side supporting member 21 may be formed of a frame member in the form of a rod, that is, a skeleton.

Depending on the scale and shape of the segment arch segment 100, a plurality of rotating apparatuses 1 according to the present invention may be used to rotate one segment arch segment 100. As shown in FIG. FIG. 13 shows a schematic perspective view corresponding to FIG. 4 showing the use of two rotary devices 1 according to the invention for the rotation of one segmented arch segment 100. As illustrated in the drawings, a plurality of neighboring rotary devices 1 of the present invention may be used as needed.

Furthermore, in the rotating device 1 according to the present invention, a plurality of fixed frames 3 may be provided on one rotating cradle 2. FIG. 14 is a schematic perspective view corresponding to FIG. 1 showing a rotating device 1 according to another embodiment of the present invention, in which a plurality of fixed frames 3 are coupled to one rotating cradle 2. have. As illustrated in the drawings, the rotary device 1 according to the present invention can be modified in such a way that one rotary support 2 is rotatably coupled to two or a plurality of fixed frames 3 at the same time. Other matters of the exemplary embodiment shown in FIGS. 13 and 14 may be equally applicable to the above description, and a repeated description thereof will be omitted.

1: rotator
2: rotating platform
3: fixed frame
20: inner support member
21: side support member

Claims (4)

delete delete delete As a rotation method for rotating the segmented arch segment 100 made of a convex curved precast concrete member having a width and a length in the direction in which the arc of the arch extends,
Segmented arch segment 100 is placed in a horizontal arrangement state and the rotating stage 2 to make the segmented arch segment 100 in a vertical arrangement state by rotation, and the rotating stage 2 is rotatably coupled to the top Using a rotating device (1) comprising a fixed frame (3),
Lifting the segmented arch segment 100 into the air while maintaining the horizontal arrangement of the segmented arch segment 100;
The lifted segment arch segment 100 is placed on the rotation base 2 in a horizontal arrangement, and the position where the segment arch segment 100 is placed on the rotation base 2 is deviated from the center of gravity of the segment arch segment 100. Placing the segment arch segment 100 on the rotary base 2 so as to have a position; And
A segment comprising the step of causing the segment arch 100 to rotate in a vertical arrangement while the rotation base 2 is rotated by the eccentricity of the position where the segment arch segment 100 is placed. Rotation method of the arch segment.

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