KR102246774B1 - Descending Control System for Downward Segment and Construction Method of Vertical Hole Using by the Same - Google Patents

Abstract

The present invention relates to a descending control system for a downward segment and construction method of a vertical hole using the same, comprising: a segment controller that forms a wall surface of a vertical hole by stacking segments in a plurality of layers, being installed at the entrance of the vertical hole, and being raised and lowered through a control unit; a fixture mounted on segments; a strand connecting a segment shoe, the fixture of the laminated segment and the segment controller to each other; and a stopper fastened to the strand.

Description

{Descending Control System for Downward Segment and Construction Method of Vertical Hole Using by the Same}

The present invention relates to a lowering control system for a segment for constructing a vertical sphere, and more specifically, a segment that forms a wall surface of a vertical sphere by stacking the segments in a plurality of layers, but is installed at the entrance of the vertical sphere and can be elevated through a control unit. It relates to a top-down segment descent control system consisting of a controller, a fixture mounted on the segment, a steel strand connecting the segment shoe and the laminated segment and a segment controller to each other, and a stopper fastened to the strand, and a vertical ball construction method using the same.

In general, when forming underground facilities such as subways, underground tunnels, underground multi-dimensional parking lots, underground pipes, ventilation, emergency passages, power outlets, and communication zones, the ground is excavated in a circular shape along the vertical downward direction from the ground surface, and then inside the vertical zone. Concrete is poured into the installed formwork to form a concrete wall, and recently, a number of arch-shaped blocks are connected to form a ring-shaped segment, and the formed segment is stacked on the top of the excavation surface to construct a vertical hole. With the introduction of the construction method, the construction method is being improved.

When the bottom surface of the segment is excavated during the construction of a vertical hole, a force to sink in the vertical downward direction is generated by the self-weight of the stacked segment, and the top stacking and number of new segments until the depth of the vertical sphere to be constructed is reached. The excavation work of the ground under the direct ball is repeated.

Each block constituting the segment may be composed of a precast concrete block manufactured in advance, or may be composed of a caisson serving as a concrete formwork, and a vertical ball is formed by stacking segments formed by connecting blocks composed of caissons. In the case of construction, a process of pouring concrete into the caisson, pouring, and curing may be additionally performed.

When constructing a top-down segment vertical hole using the self-weight of the segment, if the soil constituting the excavated ground is formed of a ground with high frictional force such as clay, the frictional force between the outer wall of the sinking segment and the excavation surface increases significantly and equalizes the segment. The descent may not be possible, and the uneven descent of the segment has emerged as the cause of the occurrence of the inclined subsidence.

Therefore, a construction method that induces smooth descending of the laminated segment through the self-weight and pressure input of the segment by installing a support structure around the vertical opening and installing one or more press fittings on the support structure to press-fit the top of the laminated segment. Is being applied.

However, when constructing a top-down segment vertical hole in which the segment is pressed through the above indenter, the soft ground is formed only on a part of the excavation surface during the descending process of the segment due to the vertical hole excavation, or when excessive excavation occurs at some of the excavation points Or, as the segment descends relatively quickly at the excessive excavation point, excessive inclination of the lower segment may occur, and due to the excessive inclination of the lower segment, the inclination of the wall of the segment, the gap between adjacent upper and lower segments, or eccentricity may occur. Segment misalignment may occur.

At this time, the inclination of the segment can be partially corrected by pressing the top of the segment in the area where excessive inclination has not occurred.However, when the number of stages of the stacked segment increases, the pressing force by the indenter is applied to the segment stacked at the lower end. As it is dispersed, the inclination correction of the segment is not properly performed. Accordingly, the structural stability of the constructed vertical sphere is deteriorated, and the airtightness between the connecting surfaces of the segments is lowered, and leakage is likely to occur.

In order to solve such a problem, in the method of constructing an underground vertical structure published in Korean Patent Publication No. 10-1025367 (registered on March 21, 2011), a segment shoe that protects the lowermost section of a stacked segment during segment descending By installing a pulling unit on the support unit mounted between the lowermost segments, connecting the ground anchor pre-embedded in the ground of the vertical excavation surface to the end of the pulling unit, and operating the pulling unit, the inclination of the lower end of the stacked segment is prevented. It is proposing a controlled construction method.

However, in the above underground vertical structure construction method, the ground anchor must be pre-filled in the ground of the vertical hole excavation surface.Before performing vertical hole excavation for segment descent, the buried earth anchor is removed, and the earth anchor is re-filled after the excavation is completed. The construction period may be delayed due to repeating.

In addition, when the inclination of the segments occurs, the gap between the stacked segments may occur due to the expansion of the stacking surface between the segments or the occurrence of eccentricity.According to the construction method of the underground vertical structure, the horizontality of the segment at the lowermost end through the pull unit Even if it is corrected, the occurrence of eccentricity between the stacked segments cannot be corrected. Whenever excessive slope subsidence of the lower segment occurs during the excavation of the vertical sphere, the stacked segments are widened, and the eccentricity between the segments gradually increases. It had a problem of deteriorating structural stability.

Korean Registered Patent Publication No. 10-1025367 (registered on March 21, 2011)

In an embodiment of the present invention, when performing vertical hole construction according to the top-down segment vertical hole construction method consisting of stepwise repetitive work such as excavation of vertical spheres and segment descending, the descending of a segment that can secure the stability of the segment descending operation under various soil conditions. The purpose of this is to further improve the completeness of the top-down segment vertical hole construction method by configuring a control system to induce precise descending of the segment and improving the structural weakness that occurs during construction of the top-down segment vertical sphere.

In an embodiment of the present invention, when excessive excavation occurs in the vertical sphere construction process according to the top-down segment vertical sphere construction method, or when soft ground is formed on a part of the excavation surface, slope settlement of the segment is prevented, and accordingly, the segment An object is to improve the structural stability of the constructed vertical sphere and the airtightness of the connection between the segments by preventing the inclination of the wall surface, the gap between the adjacent upper and lower segments, or the deviation between the segments due to the occurrence of eccentricity.

In an embodiment of the present invention, by constructing a control system that induces precise descending of a segment in the vertical sphere construction process according to the top-down segment vertical sphere construction method, an object of the present invention is to make the correction process of the inclined subsidence occurring in the segment descending process easier and faster. It is done.

In an embodiment of the present invention, when a vertical sphere is constructed according to the top-down segment vertical sphere construction method that is constructed at a high depth, inclination of the segment wall surface or gap between adjacent upper and lower segments, or An object of the present invention is to provide a segment control system capable of correcting or controlling a shift between segments caused by eccentricity.

According to an embodiment of the present invention, a plurality of layers of a ring-shaped segment connected to a plurality of arch-shaped blocks or segment blocks made of a caisson are stacked on the top surface of a ring-shaped segment shoe inserted into the excavation surface of a circular cross section. A segment controller consisting of an upper support that forms a wall, but is installed on the upper surface of the inlet of the vertical sphere, and is connected to each lower support so as to be elevated through a control unit, and an upper fixture that is directly or indirectly mounted on the upper support of the segment controller, Two or more fixtures are mounted per segment to form a certain angle on the surface of the segment block, each fixture having at least one first fixing hole, and a second fixing device formed on the upper fixture to have the same number as the total number of the first fixing holes formed in each fixture. Holes, the third fixing holes formed in the segment shoe so as to have the same number and arrangement intervals as the first fixing holes formed in each fixture, and the segment shoe passing through each of the first, second, and third fixing holes at corresponding positions in the vertical direction. It is composed of a plurality of strands connecting the fixture of the stacked segment and the segment controller to each other, an upper stopper fastened to each strand to be located above the second fixing hole, and a lower stopper fastened to each strand to be located below the third fixing hole. .

According to an embodiment of the present invention, two or more segment controllers are installed so as to achieve the same number and angle as the fasteners mounted on each segment, and a second fixing hole formed in the upper fastener of each segment controller is a first fixing hole formed in each fastener. It is formed to have the same number of holes and arrangement spacing.

According to an embodiment of the present invention, the vertical end of the upper support extends to be positioned above the stacked segment, and the lower surface of the extended upper support extends downwardly so that the support unit can be disposed at the top end of the stacked segment. And, the upper support and the support unit are configured to be able to change the connection angle through the first hinge.

According to an embodiment of the present invention, the lower support includes an upper structure on which a control unit is mounted and a lower structure fixed to an entrance of a vertical hole. A horizontal movement unit is added to move horizontally in the direction toward or away from the unit.

According to an embodiment of the present invention, the segment controller is mounted so as to protrude toward the center of the vertical sphere, and a guide bar whose protrusion length is adjusted through slide movement, a second pulley rotatably mounted to the protruding end of the guide bar, and a second pulley. 2 An eccentricity measuring device consisting of a wire spanning a pulley and having a weight mounted at one end, and a wire reel that controls the unwinding, rewinding, or stopping state of the wire by connecting the other end of the wire is added.

According to an embodiment of the present invention, the fixture is composed of two members, an inner fixture and an outer fixture, which can be coupled and separated from each other, and a coupling surface between the inner fixture and the outer fixture is formed to pass through the center of each of the first fixing holes.

According to an embodiment of the present invention, a fastener mounting groove having a concave groove shape to which a fastener is mounted is formed on the surface of the segment block.

According to an embodiment of the present invention, a downwardly inclined surface is formed at the lower end of the segment shoe while going outward from the vertical sphere center direction, and a third fixing hole is formed on the inclined surface of the lower end of the segment shoe, and toward the inside or outside of the segment shoe. A first pulley having a circular cross-sectional shape is mounted, and the stranded wire connected to the third fixing hole spans the first pulley, thereby changing the connection direction between the stranded wire and the segment shoe.

According to an embodiment of the present invention, the segment controller is equipped with a reel on which a strand is wound.

According to an embodiment of the present invention, two or more press-fit units are disposed to form a predetermined angle on the upper surface of the vertical opening, and the press-fit unit includes a press-fit support and a press-fit unit connected downward to the end of the press-fit support.

According to an embodiment of the present invention, the segment shoe is equipped with one or more auxiliary controllers, wherein the auxiliary controller has a fixture formed protruding from the inner arch surface of the segment shoe so as to face the vertical sphere center direction, and is mounted on the lower portion of the fixture and elongated or It consists of a retractable auxiliary control unit.

According to an embodiment of the present invention, by fixing the segment to the strand through a fixture mounted on the segment shoe, it is possible to prevent the occurrence of segment expansion and inclination due to excessive subsidence or slope subsidence of the segment during the descending process of the segment due to excavation of the vertical ball. There is an effect that can be.

According to an exemplary embodiment of the present invention, when the segment shoe is inclined, it is possible to rearrange the inclined segments by controlling the elevation of the segment through a fixture connected to a segment controller and a stranded wire.

According to an exemplary embodiment of the present invention, a reaction force equal to the tensile force of the strand is generated on the upper surface of the segment through the support unit of the segment controller, thereby reducing the magnitude of the moment acting on the segment controller.

According to an exemplary embodiment of the present invention, even when the vertical arrangement direction between the segment and the support unit is inconsistent through the support unit connected so that the connection angle can be changed through the first hinge, there is an effect that the segment can be supported.

According to an embodiment of the present invention, by allowing the horizontal movement of the segment controller through the horizontal movement unit, the position of each fastening hole in the segment controller and the fixed section is matched to prevent damage due to overload of the stranded wire or the upper stopper. have.

According to an embodiment of the present invention, by controlling the elevation of the control unit of each segment controller by reflecting a correction value for compensating for the inclination of the segment measured by the eccentricity measuring device, there is an effect that the segment alignment is made more precisely.

According to an embodiment of the present invention, there is an effect of multiplexing the correction means of the top-down segment lowering control system through a segment controller, a fixture, and a press fitting, so that a more precise segment control system can be constructed.

According to an embodiment of the present invention, by forming a fixture to which a strand is fixed into two members that can be combined and separated, there is an effect of correcting the gap between segments during construction of a vertical sphere, and enabling the recovery of the strand after completion of the vertical sphere construction. .

According to an embodiment of the present invention, by minimizing the protruding height of the fixture through the fixture mounting groove formed on the surface of the segment block, there is an effect of minimizing interference with the excavation surface of the vertical sphere when the segment descends.

According to an embodiment of the present invention, since the connection direction between the stranded wire and the segment shoe is switched through the first pulley formed on the segment shoe, there is an effect of facilitating separation between the segment shoe and the stranded wire.

According to an embodiment of the present invention, an indenter is disposed on the guide wall, so that the soil constituting the ground is made of clay, or the strength of each part of the ground in the section maintaining the fixed state of the laminated segment while the blasting work is performed for rock excavation. When is different, there is an effect that can induce a uniform descent of the segment.

According to an embodiment of the present invention, when excavating the inner surface of a vertical sphere constructed step by step, the auxiliary controller prevents the unequal subsidence of the segment, and when the excavation work is completed, an equal descent of the segment is induced by the automatic control of the auxiliary controller, By controlling the magnitude of the reaction force acting for each portion of the lower surface of the segment shoe, there is an effect of more effectively correcting the inclination or spreading of the stacked segments.

1 is a diagram illustrating a shape of a segment formed by connecting a plurality of segment blocks.
2 is a plan view showing a top-down segment lowering control system according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating a vertical cross-sectional structure of a top-down segment descent control system according to the AA′ diagram of FIG. 2.
4 is a view showing the shape and installation structure of a segment controller of a top-down segment lowering control system according to an embodiment of the present invention.
FIG. 5 is a cross-sectional structure of the segment descent control system according to the line BB′ of FIG. 3, and is a view showing the shape and mounting structure of a fixture installed on the segment.
6 is a view showing a vertical cross-sectional structure of a fixture installed on a segment along the CC' diagram of FIG. 5.
7 is a view showing a shape of a segment controller to which a support unit is added according to an embodiment of the present invention.
8 is a diagram illustrating a process of aligning an upper fixture of a segment controller and a fixed section mounted on the segment through a lower support to which a horizontal moving unit is added according to an embodiment of the present invention.
9 is a view showing a shape of a segment controller to which an eccentricity measuring device is added according to an embodiment of the present invention.
10 is a view showing a process of installing a fixture in a segment in which a fixture mounting groove is formed according to an embodiment of the present invention.
11 is a view showing a cross-sectional structure of a segment shoe to which a pulley is added according to an embodiment of the present invention.
12 is a diagram illustrating a direction in which a tensile force is applied by an operation of a control unit and a support unit when a segment controller is operated according to an exemplary embodiment of the present invention.
13 is a diagram illustrating a structure of a segment controller to which a reel is added according to an embodiment of the present invention.
14 is a view showing a plan view of a top-down segment lowering control system to which an indenter is added according to an embodiment of the present invention.
FIG. 15 is a diagram showing a vertical cross-sectional structure of a top-down segment lowering control system to which an indenter according to the diagram DD′ of FIG. 2 is added.
16 is a diagram illustrating an angle adjustment of a press-in unit of a press-fitting machine to which a hinge is added according to an embodiment of the present invention.
17 is a view showing a plan view of a top-down segment descent control system to which an auxiliary controller is added according to an embodiment of the present invention.
18 is a diagram showing a vertical cross-sectional structure of a top-down segment descent control system to which an auxiliary controller according to the diagram E-E' of FIG. 17 is added.
19 is a diagram illustrating a segment alignment control process according to an operation of an auxiliary controller according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

It will be described in detail focusing on the parts necessary to understand the operation and operation according to the present invention.

While describing the embodiments of the present invention, descriptions of technical contents that are well known in the technical field to which the present invention pertains and are not directly related to the present invention will be omitted.

This is to more clearly convey the gist of the present invention by omitting unnecessary description.

In addition, in describing the constituent elements of the present invention, different reference numerals may be assigned to constituent elements of the same name according to the drawings, and the same reference numerals may be denoted even in different drawings.

However, even in such a case, it does not mean that the corresponding component has different functions according to the embodiment, or that it has the same function in different embodiments, and the function of each component is the corresponding embodiment. It should be judged based on the description of each component in.

In addition, technical terms used in the present specification should be interpreted as generally understood by those of ordinary skill in the technical field to which the present invention pertains, unless otherwise defined in this specification. It should not be construed as a meaning or an excessively reduced meaning.

In addition, the singular expression used in the present specification includes a plurality of expressions unless the context indicates otherwise.

In the present application, terms such as “consisting of” or “comprising” should not be construed as necessarily including all of the various elements or various steps described in the specification, and some of the elements or some steps It may not be included, or it should be interpreted that it may further include additional components or steps.

Hereinafter, the configuration of the top-down segment descent control system according to the present invention will be described.

In the present invention, the vertical opening (1) refers to a tunnel that is excavated vertically downward from the ground surface to form underground facilities such as subways, underground tunnels, and underground multi-dimensional parking lots, or ventilation holes and emergency passages connected to the underground facilities, and , The vertical sphere (1) inside the excavation surface excavated for construction, the segment 20 forming a ring (ring) shape is stacked in a plurality of layers to form the wall surface of the vertical sphere (1).

The segment 20 is formed by connecting each side of the segment block 21 made of an arch-shaped block or a caisson, as shown in FIG. 1, and constitutes a segment 20 of one layer. The segment blocks 21 may be fixed to each other through curved bolts or other fastening members.

When the vertical sphere (1) descends the segment (20) due to excavation, the descending speed of each segment (20) varies depending on the strength of the excavated ground, and uneven descending due to the inclination of the segment (20) due to the floating settlement phenomenon In order to prevent the occurrence of gaps or deviations between the segments 20, the top-down segment lowering control system of the present invention includes a segment controller 100 that controls the stacking of the segments 20 through elevating and lowering.

The segment controller 100 is mounted on the upper surface of the inlet of the vertical sphere 1 as shown in FIGS. 2 and 3. When the segment block 21 is made of precast concrete, when the segment controller 100 at the entrance of the vertical sphere 1 is installed due to the high weight of the segment 20, the ground surface may be deformed or damaged. Therefore, it is preferable to install a guide wall 2, which is a structure on which the segment controller 100 is mounted, along the periphery of the inlet of the vertical sphere 1, and install the segment controller 100 on the top of the guide wall 2 And, in the configuration and construction method of the present invention to be described later, it will be described on the premise that the guide wall 2 is installed at the entrance of the vertical sphere 1 and the segment controller 100 is mounted on the top of the guide wall 2.

In order to more effectively control the inclination of the segment 20 according to the lowering speed control for each segment 20, two or more segment controllers 100 are mounted on the upper surface of the guide wall 2 so as to form a certain angle, and a more stable segment ( 20) For descent control, it is preferable to install three or more.

The segment controller 100 is composed of a lower support 120 installed on the upper surface of the guide wall 2 and an upper support 110 disposed on the lower support 120, as shown in FIG. 4, and the upper support ( 110 and the lower support 120 are connected to each other through the control unit 130, the upper support 110 is equipped with an upper fastener 111 having one or more second fixing grooves 112 formed thereon. The upper fixture 111 may be directly mounted on the upper support 110 or may be indirectly mounted through other structures connected to the upper support 110.

The control unit 130 composed of a piston and a cylinder allows the length of the upper support 110 to rise or fall while extending or contracting through the internal fluid pressure control.

The segments 20 are stacked in a plurality of layers on the excavated vertical sphere 1. A fixture 200 is provided on the inner or outer surface of the arch of the segment block 12 constituting the segment 20 of each layer so as to form the same angle as the installation distance of the segment controller 100 installed on the guide wall 2. It is installed.

At this time, the inner surface of the arch of the segment block 12 or segment 20 described in the present invention refers to a surface in contact with a cavity formed in the center of the segment 20 stacked during construction of the vertical sphere 1, and the segment The outer surface of the arch of the block 12 or segment 20 means a surface in contact with the vertical surface of the ground excavated during the construction of the vertical tool 1, and in FIGS. 2 to 16, the fixture 200 is mounted on the outer surface of the arch. An embodiment of the case has been shown.

The fixture 200 has an arch shape having the same curvature as the arch of the segment block 12 on which the fixture 200 is mounted, as shown in FIG. 5. When the fixture 200 is mounted on the outer side of the arch of the segment 20, the inner side of the arch of the fixture 200 and the outer side of the arch of the segment 20 form the same curvature, and the fixture 200 is the segment 20 ) When mounted on the inner side of the arch, the outer side of the arch of the fixture 200 and the inner side of the arch of the segment 20 form the same curvature, and the fixture 200 is mounted on the surface of the segment block 12 on which the fixture 200 is mounted. Holes 23 are formed.

A fastening hole 240 is formed at a position corresponding to the location of the fastener fastening hole 23 formed to penetrate the inner and outer surfaces of the fastener 200, and the fastener fastening hole 23 passes through the fastening hole 240. The fixture 200 is mounted on the surface of the segment 20 through a fastening member that is fastened to. The fixture 200 is formed with one or more first fixing holes 230 penetrating upward and downward when mounted on the surface of the segment 20.

In the process of lowering the segment 20 by excavation of the vertical sphere (1), even if a soft ground that may cause partial excessive slope subsidence of the segment 20 stacked on a part of the vertical sphere (1) excavation surface is formed, the fixture ( Through 200), the segments 20 of each layer are individually fixed to the stranded wire 30 and the alignment between the stacked segments 20 can be maintained, so that the gaps between the segments 20 and thus the eccentricity between the segments 20 Make it possible to prevent it from occurring.

On the lower surface of the lowermost segment 20 stacked inside the vertical sphere (1), the segment 10 is lowered by the weight of the segment 20 during excavation of the vertical sphere (1), and the lowermost segment ( Segment shoe 10 is mounted to prevent damage to the lower surface of 20).

The segment shoe 10 supports the load of the segment 20 stacked on the top, prevents damage from the force acting from the excavation surface of the vertical sphere 1, and uses steel to reduce the cost required for manufacturing. It is preferable to be made of a metal material containing.

One or more third fixing holes 11 are formed in the segment shoe 10. The first fixing holes 230 of the fixture 200 and the third fixing holes 11 of the segment shoe 10 are formed in the same number as the second fixing holes 112 formed in the segment controller 100, and (1) When the segment shoe 10 and the segment 20 are inserted into the interior, the first fixing hole 230, the second fixing hole 112, and the third fixing hole 11 at positions corresponding to each other are in a straight line. It is preferable that it is formed so as to be able to be disposed.

At least one prestressing strand (30) passes through each of the second fixing holes 112, the first fixing holes 120, and the third fixing holes 11 arranged in a straight line, and the segment shoe 10 and the The fixture 200 and the segment controller 100 of the stacked segments 20 are connected to each other, and the stranded wire 30 is formed by twisting three or more strands of steel wires.

The second fixing hole 112 is equipped with an upper stopper 31 serving as a brake for controlling locking or releasing of each strand 30 passing through each of the second fixing holes 112, and , The upper stopper 31 is a vertical hole (1) bottom surface excavation, a vertical hole (1) blasting work for bottom surface excavation, segment 20 stacking, fixture 200 mounting, fixture 200 and strand wire 30 When performing interlocking, the stranded wire 30 is fixed to maintain the stopped state of the segment shoe 10 and the segment 20, and when the segment 20 descends, it is separated from the stranded wire 30 and the fixed state of the stranded wire 30 is released. To lower the segment 20.

A lower stopper 32 is fastened to each strand 30 that has passed through the third fixing hole 11 so as to be located under the third fixing hole 11, and the segment shoe 10 disposed above the lower stopper 32 And to fix and support the stacked segments 20.

And, as the stacking amount of the segment 20 increases according to the excavation of the vertical sphere 1, a moment acting on the control unit 130 is generated by a tensile force transmitted to the segment controller 100 through the stranded wire 30. Deformation or damage of the control unit 130 may occur. To prevent this, the first support 140 connecting the upper support 110 and the lower support 120 to each other is integrally installed on the outer surface of the control unit 130, or a predetermined distance from the control unit 130 Can be installed to be spaced apart.

In the first support 140, when two members that are slidably coupled are connected to the upper support 110 and the lower support 120, respectively, when the upper support 110 is raised or lowered according to the operation of the control unit 130 It provides a supporting force for an external force applied to the control unit 130 by a moment action, and has a function of guiding the elevating direction of the upper support 110 through a sliding operation.

In addition, a second support 150 may be installed between the upper support 110 and the lower support 120 so as to be spaced apart from the first support 140 by a predetermined distance. The second support 150, together with the first support 140, further strengthens the support force for the external force applied to the control unit 130 by a moment action, and the control unit 130 and the control unit 130 and the control unit 130 and the control unit 130 and the The first support 140 and the second support 150 are preferably arranged in a straight line so as to face the center of the vertical sphere (1).

At this time, bearings such as a sliding bearing or a roller bearing may be added to the sliding operation portions of the first support 140 and the second support 150 so that the segment controller 100 can perform a stable elevating and descending operation.

As described above, the upper fixture 111 may be indirectly mounted through other structures connected to the upper support 110, and either the first support 140 or the second support 150 is the upper support 110 ) May correspond to other structures that are connected to.

When the upper fixture 111 is mounted on the first support 140 or the second support 150, the upper fixture 111 is slidably connected up and down of the first support 140 or the second support 150 It is formed on an upper member connected to the upper supporter 110 of the two members, and when the upper supporter 110 is elevated and lowered according to the operation of the control unit 130, the segment 20 ) Can be lowered or fixed or controlled for alignment.

When the upper fixture 111 is mounted on the first support 140 or the second support 150, the upper fixture 111 is formed on the side of the segment controller 100 and the upper fixture 111 is formed on the upper support 110 ), the position of the upper fixture 111 is lower than when it is directly mounted on, so that the operator can more easily perform the work of connecting the stranded wire 30 to the second fixing hole 112.

In addition, an upper fixture 111 may be additionally mounted on a lower member connected to the lower support 120 among two members slidably connected to the first support 140 or the second support 150. When maintaining the fixed state of the segment 20 for excavation through the upper stopper 31 mounted on the upper fixture 111 mounted on the member, the load support of the segment 20 can be made more stably. To be there.

In addition, as shown in FIG. 7, the end of the upper support 110 in the vertical sphere 1 direction may be extended to be positioned above the stacked segments 20. The support unit 160 may be mounted downward on the lower surface of the extended upper support 110.

The support unit 160 is composed of a piston and a cylinder, and the length is extended or contracted through the internal fluid pressure control, and the upper surface of the stacked top segment 20 is pressed or disconnected from the upper surface of the segment 20 Can occur. During the upward movement operation of the segment controller 100 to correct the inclination of the stacked segments 20, the support unit 160 presses the upper surface of the segment 20.

As shown in FIG. 12, when the segment 20 is lifted through the elongation of the control unit 130, the tensile force of the stranded wire 30 by the load of the segment 20 is applied to the upper support 110. As the upper surface of the segment 20 is pressed through the extension of the support unit 160, a reaction force equal to the tensile force of the strand 30 is generated, thereby acting on the segment controller 100 It allows you to reduce the magnitude of the moment you make.

While pressing the upper surface of the uppermost segment 20 on which the support unit 160 is stacked, it is possible to prevent the gap between the upper and lower segments 20 by minimizing the step between the connecting portions of the upper and lower segments 20 generated in the process of laminating the segment 20. , In order to smoothly correct the step difference between the segments 20, it is preferable to partially release the fastening between the fixture 200 and the stranded wire 30 mounted on the segment 20 where the step difference occurs.

In addition, the upper support 110 and the support unit 160 may be connected so that the connection angle can be changed through the first hinge 170, and the segments 20 stacked due to the occurrence of gaps or inclinations between the segments 20 Even if the uppermost end surface and the lower end of the support unit 160 are not disposed on a vertical line, support and pressure of the segment 20 through the support unit 160 can be performed.

In addition, as shown in FIG. 8, the lower support 120 may be connected so that the upper structure 121 on which the control unit 130 is mounted and the lower structure 122 fixed on the guide wall 2 are slidable with each other. In addition, a horizontal moving unit 123 may be mounted on a connection between the upper structure 121 and the lower structure 122.

When the first fixing groove 230 and the second fixing groove 112 are not arranged on a vertical line, the direction of extension or contraction of the control unit 130 and the direction of the tensile force acting from the stranded wire 30 do not coincide with each other. Tensile force acting on the stranded wire 30 is generated as the resultant force of the horizontal component and the vertical component. As the resultant force of the tensile force acting on the stranded wire 30 increases due to the tensile force according to the horizontal component, the possibility of breakage due to an overload of the stranded wire 30 or the upper stopper 31 may increase.

Therefore, the horizontal movement unit 123 horizontally moves the upper structure 121 in a direction approaching or away from the vertical sphere (1) center direction, so that the first fixing groove 230 and the segment controller 100 of the fixture 200 By allowing the second fixing groove 112 to be disposed on a vertical line, damage due to overload occurrence of the stranded wire 30 or the upper stopper 31 is prevented.

In addition, an eccentricity measuring device 400 for measuring the inclination of the stacked segments 20 may be added to the segment controller 100.

The eccentricity measuring device 400 is mounted so that the guide bar 410 protrudes toward the center of the vertical sphere 1, as shown in FIG. 9, and the guide bar 410 is the guide wall 2 and the stacked segment 20 ) It can be configured to adjust the protruding length through slide movement according to the interval between the inner walls.

The second pulley 411 is rotatably mounted on the protruding end of the guide bar 410, and the wire 420 is overlaid on the second pulley 411. A weight 421 is mounted at one end of the wire 420 that goes up and down along the inner wall of the segment 20, and a wire that controls the unwinding, rewinding, or stopping state of the wire 420 at the other end of the wire 420 The reel 430 is connected.

When the depth of the vertical sphere (1) gradually increases according to the excavation of the vertical sphere (1) and the stacking of the segments (20), the wire reel 430 is released and the weight 421 mounted on the wire 420 is lowered. 2 By measuring the degree of inclination of the segment 20 through the change in the distance between the wire 420 positioned between the pulley 411 and the weight 421 and the inner wall surface of the stacked segment 20, Control the operation.

In addition, as shown in FIG. 10, the fixture 200 may be composed of two members, an inner fixture 210 and an outer fixture 220 that can be coupled and separated from each other. The first fixing hole 230 in the shape of a semicircle passes through the center of each of the first fixing holes 230 while the coupling surface between the inner fastener 210 and the outer fastener 220 passes through the inner fastener 210 and the outer fastener 220 Can be formed respectively.

After connecting the stranded wire 30 to the first fixing hole 230, when the fastening member is inserted into the fastening hole 240 and fastened, the outer fastener 220 and the inner fastener 210 are close to each other and the stranded wire 30 is connected to each other. The segment 20 and the stranded wire 30 are fixed by pressing, and when the fastening member is a bolt, an insert nut may be inserted into the fastener fastening hole 23.

At this time, when the fixture 200 is mounted on the outer arch surface of the stacked segment 20, the fixture fastening hole 23 is formed to penetrate the inner and outer arch surfaces of the segment 20, and the end of the insert nut is fastened to the fixture. The inside of the segment 20 is exposed to the outside of the segment 20 through the hole 23, so that the end of the insert nut exposed when removing and collecting the strand 30 after the vertical hole 1 is completed, the strand 30 and the fixture ( 200) can be separated more easily.

And, in order to increase the fastening force with the stranded wire 30, a pattern consisting of grooves and protrusions is formed on the surface of the first fixing hole 230, or a high strength capable of elastic deformation between the stranded wire 30 and the first fixing hole 230 The member can be inserted.

In addition, a fastener mounting groove 22, which is a concave groove having a shape similar to the shape of the contact surface of the fastener 200, may be formed on the surface of the segment block 21 at the position where the fastener 200 is mounted, and in particular, the fastener mounting groove 22 ) Is formed on the outer surface of the stacked segment 20, by reducing the height of the fixture 200 protruding from the arch surface of the segment 20, excavation during the descending of the segment 20 during the construction of the vertical tool 1 By reducing the interference with the surface, the segment 20 may be lowered more smoothly.

In addition, as shown in FIG. 11, a downward inclined surface is formed at the lower end of the segment shoe 10 while going outward from the center of the vertical sphere 1 to increase straightness when the segment shoe 10 and the segment 20 descend. , A third fixing hole 11 is formed on an inclined surface of the lower end of the segment shoe 10, and a first pulley 12 having a circular cross-sectional shape may be mounted inside or outside the segment shoe 10.

As the stranded wire 30 connected to the third fixing hole 11 spans the first pulley 12, the direction of connection between the stranded wire 30 and the segment shoe 10 is changed. When the segment 20 is mounted on the outer arch surface, the lower stopper 32 is formed on the inner side of the vertical sphere (1), so that when the vertical sphere (1) is separated and recovered after the construction is completed, the strand (30) It makes the separation between the and the lower stopper 32 easier.

In addition, as shown in FIG. 13, the segment controller 100 may be equipped with a reel 180 on which the stranded wire 30 is wound.

At this time, a mark that can be distinguished through a line or color at regular intervals may be formed on the surface of the strand so that the length of the strand released from the reel 180 can be known.

In addition, two or more press fittings 300 may be disposed on the upper surface of the guide wall 2 to form a predetermined angle.

The press fitting unit 300 is composed of a press fitting support 310 installed on the upper surface of the guide wall 2 and a press fitting unit 320 connected downward to the end of the press fitting support 310, and a press fitting unit 320 consisting of a piston and a cylinder. ) Descends or rises while extending or contracting the length through the internal fluid pressure control, pressing the upper surface of the stacked uppermost segment 20 to cause the segment 20 to descend or Separation takes place.

At this time, the press-fit support 310 of the press-fit device 300 includes a vertical frame 311 mounted on the upper surface of the guide wall 2, and the other end of the vertical frame 311 protrudes toward the center of the vertical sphere 1 ( 311) Consists of a horizontal frame 312 connected to the upper portion, as shown in FIG. 16, the press-fit unit 320 is connected to the lower surface of the horizontal frame 312 through a second hinge 321, the second It may be configured to change the angle of the press-fitting unit 320 around the hinge 321 as an axis.

In addition, as shown in FIGS. 17 and 18, one or more auxiliary controllers 500 may be mounted on the segment shoe 10 so as to be disposed at a predetermined angle, and each auxiliary controller 500 is an inner side of the segment shoe 10. It is composed of a fixing table 510 formed to protrude from the arch surface toward the center of the vertical sphere 1 and an auxiliary control unit 520 mounted under the fixing table 510.

The fixing member 510 may protrude to form a ring shape along the inner arch surface of the segment shoe 10 or may partially protrude only at a portion where the auxiliary control unit 520 is mounted, and the auxiliary control unit 520 is a fluid The length is stretched or contracted through pressure control.

As shown in FIG. 19, when the auxiliary control unit 520 is extended, the lower end of the auxiliary control unit 520 descends and comes into contact with the excavation surface under the vertical sphere 1, and the auxiliary control unit 520 In the state of contact between the end and the vertical sphere (1) excavation surface, the auxiliary control unit 520 is additionally extended and operated at the portion where the segment 20 is inflated or inclined.

Adjusting the magnitude of the reaction force against the load of the segment shoe 10 and the segment 20 at the additional extension operation portion of the auxiliary control unit 520, and thereby correcting the inclination or spread of the stacked segments 20. have.

In addition, the auxiliary controller 500 may be mounted together with the press-fit device 300, and the downward pressure input by the operation of the press-fit device 300 and the upward pressure input by the operation of the auxiliary controller 500 work together. By doing so, it is possible to more effectively correct the inclination or spread of the stacked segments 20.

At this time, the auxiliary controller 500 may be mounted to achieve the same number and arrangement angle as the press-fit unit 300, or may be mounted to achieve a different number and arrangement angle from the press-fit unit 300.

The vertical sphere construction method using the top-down segment descent control system configured as above will be described as follows.

1. Excavation steps:

In the excavation stage, the vertical hole (1) is excavated to form the entrance of the vertical hole (1) location, and the vertical hole (1) where the excavated vertical hole (1) floor surface and the guide wall (2) will be installed. Floor concrete is poured along the entrance edge of ).

2. Segment shoe and bottom segment installation steps:

When the digging step is completed, the segment shoe 10 is placed at the construction position of the vertical hole 1 on the upper surface of the concrete floor, and the lowermost segment 20 is stacked and fixedly coupled to the upper segment shoe 10.

3. Guide wall installation steps:

In the guide wall installation step, concrete is poured along the edge of the segment shoe 10 arranged on the floor concrete to install the guide wall 2, which is the supporting structure of the segment controller 100, and the concrete reinforcement of the guide wall 2 When the reinforcing structure is formed, a fastening structure or fastening device that is coupled to the lower base of the segment controller 100 is pre-installed.

4. Segment controller installation steps:

When the guide wall installation step is completed, the segment controller installation step of installing the segment controller 100 to the upper surface of the guide wall (2) installed along the vertical hole (1) entrance is performed. When the inclination of 20) occurs and the inclination is corrected through the segment controller 100, it is preferable to install and install three or more segment controllers 100 at a predetermined angle so that more smooth correction may be achieved. At this time, the number of segment controllers 100 installed on the guide wall 2 is determined in consideration of the total load of the stacked segments 20 according to the diameter and depth of the vertical sphere 1 to be constructed.

5. Steps for connecting strands:

In the step of connecting the stranded wire, the second fixing hole 112 formed in the upper fixture 111 of the segment controller 100 and the third fixing of the segment shoe 10 inserted into the vertical hole 1 are made at one end of the stranded wire 30. After passing through the holes 11 in order, the lower stopper 32 is fastened to the lower end of the strand 30 that has passed through the third fixing hole 11, and the upper stopper 31 mounted in the second fixing hole 112 ) To fix the upper end of the stranded wire 30.

A 13m diameter segment 20 formed by connecting the segment blocks 21 made of precast concrete is stacked to a depth of 60m, and when the vertical sphere 1 is constructed, the segment shoe 10 and the entire stacked segment 20 are applied. In order to support the load, more than 160 pc steel wires with a diameter of 12.7mm are required, and if the steel wire 30 is composed of 7 strands formed by twisting 7 strands of 12.7mm diameter pc steel wire, more than 25 The stranded wire 30 should be connected.

At this time, when each segment 20 is formed by connecting 10 segment blocks 21, one fixture 200 is mounted per two neighboring segment blocks 21, and a total of five fixtures are attached to the segment 20. The 200 is mounted, and five strands 30 may be connected to each fixture 200.

In the step of connecting the stranded wire, in principle, the outer connection method of the segment 20, in which the stranded wire 30 is connected so that it is located on the outer arch of the stacked segment 20, is applied, and depending on the construction site conditions, the strand 30 ) Can be applied by switching to the inner connecting method of the segment 20 connecting so as to be positioned on the inner arch surface of the stacked segments 20.

6. Segment Lamination Steps:

In the segment stacking step, the segment stacking step, the segment fixing step, and the segment lowering step are repeatedly performed until the depth of the vertical sphere 1 to be constructed is reached.

6-1. Segment Lamination Process:

In the segment stacking process, the lowermost segment of the segment 20 is stacked on the segment shoe 10 or the segment 20 is additionally stacked on the stacked segment 20.

The segment block 21 constituting the segment 20 may be made of a precast block in a state in which manufacturing is completed or a caisson for manufacturing by pouring concrete on site, and when the segment block 21 is made of a caisson The step of curing by pouring concrete may be added to the segment lamination process.

In addition, the connection between the segment blocks 21 constituting each segment 20 in the segment stacking process may be bonded to each other through curved bolts or other fastening members or fixing members, and between the segments 20 stacked vertically adjacent to each other. The connection part may also be bonded to each other through curved bolts or other fastening members or fixing members.

6-2. Segment fixing process:

Before or after lamination of the segments 20 of each layer, fasteners 200 are provided on the inner or outer arch surface of the segment 20 so as to achieve the same number and arrangement angle as the segment controller 100 installed on the guide wall 2. In the segment fixing process, the stranded wire 30 is connected and fixed to the first fixing hole 230 of the fixture 200 mounted on the stacked segment 20 of the corresponding layer.

At this time, in the case of applying the external connection method of the segment 20 connecting the strand 30 to the outer arch surface of the segment 20 in the step of connecting the stranded wire, the fixture 200 is mounted to the outer arch surface of the segment 20, When the segment 20 inner connection method for connecting the stranded wire 30 to the inner arch surface of the segment 20 is applied, the fixture 200 is mounted on the inner arch surface of the segment 20.

Separately from the curved bolt or other fastening member or fixing member that binds the connection between the segments 20, a fixing member for the stranded wire 30 is additionally inserted into the first fixing hole 230 of the fixture 200 and stacked up and down. By generating multiple fastenings between the segmented segments 20, the fastening force between the segments 20 is strengthened to prevent the occurrence of separation between the segments 20 during the segment descending process performed next time, and the installation of the segments 20 equally descending. You can induce it.

6-3. Segment descending process:

In the segment descending process, when the segment 20 is connected and bound to the strand 30 through the fixture 200, the bottom surface of the vertical sphere 1 is excavated, and a locking state through the control of the upper stopper 31 By releasing the upper end of the stranded wire 30 of, the segment shoe 10 and the segment 20 descend according to the downward movement of the segment shoe 10 and the segment 20 as much as the excavated depth by the weight of the stacked segments 20.

At this time, in the case where the fixture 200 is mounted on the outer arch surface of the segment 20 in the segment fixing process, the vertical hole 1 when the segment shoe 10 and the segment 20 descend, the side excavation surface and the protruding fixture ( 200) Since inter-corner interference may not occur and smooth descent may not be achieved, a fixture mounting groove 22 is formed on the mounting surface of the fixture 200 of the segment block 21, so that the segment 20 protrudes from the arch surface. The height of the fixture 200 can be minimized.

6-4. Segment alignment process:

During the segment lamination step, if the soft ground appears on a part of the excavation surface, the segment shoe 10 and the segment 20 descend more rapidly in the soft ground, and the laminated segment 20 according to the inclination of the segment 20 Liver eccentricity can occur.

When eccentricity between the segments 20 occurs, each segment controller 100 is sent to each segment controller 100 through an extension or contraction operation of the control unit 130 of each segment controller 100 in a locked state of the strand 30 through the upper stopper 31. The tension of the connected strands 30 is individually controlled, and through this, a segment alignment process is further included to achieve true alignment between the segments 20.

When performing the segment alignment process, the stranded wire 30 is lifted by the extension operation of the control unit 130 to lift the segment shoe 10 and the segment 20, and the stranded wire 30 caused by the load of the segment 20 with the upper support 110. ) Of the tensile force is applied.

In addition, when performing the segment alignment process, the top end surface of the stacked segment 20 and the lower end of the support unit 160 are not disposed on a vertical line due to the inclination of the segment 20, or the first fixing groove 230 and the first 2 The fixing groove 112 may not be disposed on a vertical line.

Therefore, by sliding the upper structure 121 of the lower support 120 through the horizontal movement unit 123 to achieve vertical alignment between the first fixing groove 230 and the second fixing groove 112, the strand 30 Alternatively, the possibility of damage due to overload of the upper stopper 31 is reduced.

At this time, when alignment between the segment 20 and the support unit 160 is not made according to the inclination of the segment 20 or the movement of the support unit 160 through the horizontal movement unit 123, the support unit 160 By changing the angle connected to the upper support 110 through the first hinge 170 mounted on the upper part, the contact between the segment 20 and the support unit 160 can be made, so that the support or pressure of the segment 20 is reduced. You can make it happen.

The support unit 160 mounted downward on the lower surface of the upper support 110 extends and contacts the upper surface of the stacked uppermost segment 20, thereby pressing the upper surface of the segment 20 and tensioning the stranded wire 30. The amount of the moment acting on the segment controller 100 may be reduced by generating a reaction force equal to the force).

In addition, a reaction force acting on the upper surface of the segment 20 by the support unit 160 minimizes the step difference between the connecting portions of the upper and lower segments 20 in the process of laminating the segments 20, thereby minimizing the difference between the upper and lower segments 20. Try to prevent it from spreading.

At this time, when performing the step correction between the segments 20 through the support unit 160, the fastening between the fixture 200 and the stranded wire 30 mounted on the segment 20 to be corrected for the step must be partially released.

6-5. The process of measuring segment eccentricity:

In addition, an eccentricity measurement process of measuring the eccentricity of the stacked segments 20 through the eccentricity measuring device 400 when performing the segment stacking step may be included.

In the eccentricity measurement process, the distance between the inner arch surface of the stacked segment 20 and the wire 420 is adjusted by adjusting the length of the guide bar 410, and the vertical sphere 1 is stretched through the wire reel 430. After adjusting the length of the wire 420, the degree of inclination of the segment 20 is measured through a change in the distance between the wire 420 and the inner wall surface of the stacked segment 20.

In the segment alignment process, the segment 20 is aligned by controlling the elevation of the control unit 130 of each segment controller 100 by reflecting a correction value for compensating for the inclination of the segment 20 measured in the eccentricity measurement process. , When the alignment of the segments 20 is completed, the suspended construction process or the next construction process continues.

7. Strand separation steps:

In addition, after the segment lamination step is completed, a strand separation step of separating the strand 30 from the segment shoe 10 and the fixture 200 may be added and performed.

In the step of separating the stranded wire, the lower stopper 32 is separated, the fastening member fastened to the fastener fastening hole 23 through the fastening hole 240 of the fastener 200 is separated, and the upper stopper 31 is released. ), the stranded wire 30 is recovered by rewinding the stranded wire 30 through the reel 180.

At this time, in the case of applying the external connection method of the segment 20 connecting the strand 30 to the outer arch of the segment 20 in the step of connecting the stranded wire, the fastener fastening hole 23 is formed as shown in FIGS. 10 and 11. The insert nut is inserted so that the inner side of the segment 20 is exposed to the outside of the segment 20 through the first pulley 12, and the binding direction of the stranded wire 30 with the segment shoe 10 is switched, and the lower stopper 32 is turned into a vertical hole ( 1) It can be formed on the inner side. Through this, the operator loosens the insert nut and the lower stopper 32 inside the vertical sphere 1, so that the stranded wire 30 can be recovered from the fixture 200 or the segment shoe 10.

4-1. Indenter installation process:

In addition, in the segment descending process of the segment lamination step, if the soil constituting the ground is made of clay, or there is a concern of occurrence of uneven soil pressure due to a change in the ground or a change in stiffness for each depth of the vertical sphere (1), the laminated segment (20) It may not be possible to descend due to its own weight, or excessive inclination may occur.

Accordingly, as shown in FIGS. 14 and 15, in the segment controller installation step, a press fitting installation process of installing two or more press fittings 300 to the upper surface of the guide wall 2 to form a predetermined angle may be added, Accordingly, when performing the segment lowering process, the segment 20 may be pressed downward through the operation of the press fitting unit 320.

When the press-in unit 320 is elongated according to the operation of the press-fit unit 300, the upper stopper 31 is released to release the fixing of the stranded wire 30, and the segment 20 is When the inclination is measured, the operation of the press-fitting unit 320 is stopped and the upper stopper 31 is operated to lock the stranded wire 30.

Thereafter, by controlling the elevation of the control unit 130 of each segment controller 100 by reflecting a correction value for compensating for the inclination of the segment 20 measured through the eccentricity measuring device 400, the segment 20 is aligned And continue the suspended construction process or the next construction process.

Since the indenter 300 is positioned on the top surface of the stacked segments 20, interference may occur between the indenter 300 and the segment 20 to be stacked in a segment stacking process. By changing the angle of the press-fitting unit 320 around the second hinge 321 as an axis, interference with the segment 20 may be prevented, and the segment stacking process may be performed more smoothly.

2-1. Auxiliary controller mounting process:

In addition, in the segment shoe and the lowermost segment installation step, an auxiliary controller mounting process of mounting one or more auxiliary controllers 500 to the segment shoe 10 may be added.

The auxiliary controller 500 added in the auxiliary controller mounting process reacts against the load of the segment shoe 10 and the segment 20 through the control of the extension operation of each auxiliary control unit 520 when performing the segment alignment process in the segment stacking step. The size of the stacked segments 20 is adjusted, thereby correcting the inclination or opening of the stacked segments 20.

According to the amount of eccentricity of the segment 20 measured through the eccentricity measuring device 400 in the eccentricity measurement process, the auxiliary controller 500 can automatically control the eccentricity correction in the segment alignment process, and when performing the segment descending process, the vertical sphere (1) ) It is possible to prevent the unequal settling of the segment 20 during the excavation process, and to induce an even lowering of the segment 20 after excavation of the vertical sphere (1). This makes it possible to more effectively correct the inclination or gap of the stacked segments during the segment alignment process.

In addition, an auxiliary controller mounting process is added in the segment shoe and the lowermost segment installation step, and at the same time, a press fitting installation process is added in the segment controller installation step. The resultant force of the downward pressure input and the upward pressure input acting in the press fitting device 300 and the auxiliary controller 500, respectively, acts, and through this, the alignment of the segment 20 can be more effectively corrected.

Although the embodiments of the present invention have been described with reference to the above contents, those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof.

Therefore, the embodiments described above should be understood as illustrative and non-limiting in all respects, and the scope of the present invention described in the detailed description is indicated by the claims to be described later, and the meaning of the claims and It should be construed that all changes or modifications derived from the scope and equivalent concepts are included in the scope of the present invention.

1: vertical sphere 2: guide wall
10: segment shoe 11: third fixing hole
12: first pulley 20: segment
21: segment block 22: fixture mounting groove
23: fastener fastening hole 30: stranded wire
31: upper stopper 32: lower stopper
100: segment controller 110: upper support
111: upper fixture 112: second fixing hole
120: lower support 121: upper structure
122: lower structure 123: horizontal movement unit
130: control unit 140: first support
150: second support 160: support unit
170: first hinge 180: reel
200: fixture 210: inner fixture
220: outer fastener 230: first fixing hole
240: fastening hole 300: press fitting
310: press-fit support 311: vertical frame
312: horizontal frame 320: press-fit unit
321; Second hinge 400: eccentricity measuring device
410: guide bar 411: second pulley
420: wire 421: weight
430: wire reel 500: auxiliary controller
510: fixture 520: auxiliary control unit

Claims (22)

A plurality of layers on the top surface of the ring-shaped segment shoe 10 inserted into the excavation surface of a circular cross-section through a ring-shaped segment 20 to which a plurality of arc-shaped blocks or segment blocks 21 made of caisson are connected To form the wall surface of the vertical sphere (1),
A segment controller 100 consisting of a lower support 120 installed at the inlet of the vertical sphere 1, and an upper support 110 connected to each lower support 120 and elevating through the control unit 130;
An upper fixture 111 directly or indirectly mounted on the upper support 110 of the segment controller 100;
Two or more fasteners 200 are mounted for each segment 20 so as to form a predetermined angle on the surface of the segment block 21, each having at least one first fixing hole 230 formed thereon;
A second fixing hole 112 formed in the upper fixture 111 to have the same number as the total number of the first fixing holes 230 formed in each fixture 200;
A third fixing hole 11 formed in the segment shoe 10 so as to have the same number and arrangement intervals as the first fixing holes 230 formed in each fixture 200;
The segment shoe 10 and the fixture 200 of the stacked segment 20 and the segment controller 100 are connected to each other by passing through each of the first, second, and third fixing holes 230, 112 and 11 at corresponding positions in the vertical direction. A plurality of strands 30;
An upper stopper 31 mounted in the second fixing hole 112 to control the fixing or separation of the stranded wire 30;
A lower stopper 32 fastened to each of the strands 30 so as to be located under the third fixing hole 11;
Top-down segment descent control system, characterized in that consisting of. The method of claim 1,
The segment controller 100 is installed in two or more so as to achieve the same number and angle as the fasteners 200 mounted on each segment 20, and a second fixing hole formed in the upper fastener 111 of each segment controller 100 (112) is a top-down segment lowering control system, characterized in that formed to have the same number and arrangement intervals as the first fixing holes 230 formed in each fixture (200). The method of claim 1,
The segment 20 in which the end of the upper support 110 in the vertical sphere 1 direction is positioned above the stacked segment 20, and the support unit 160 is stacked on the lower surface of the extended upper support 110. ), the upper support 110 and the support unit 160 are connected downward so that they can be disposed with the uppermost end surface of the top-down segment lowering control system, characterized in that the connection angle can be changed through the first hinge 170. The method of claim 1,
The lower supporter 120 includes an upper structure 121 on which the control unit 130 is mounted, and a lower structure 122 fixed to the entrance of the vertical hole 1, and the upper structure 121 of the lower supporter 120 ) To the connection between the lower structure 122 and the upper structure 121 horizontally moving in a direction toward or away from the vertical sphere (1). Control system. The method of claim 1,
The segment controller 100 is mounted so as to protrude toward the center of the vertical sphere (1), the guide bar 410 whose protrusion length is adjusted through slide movement, and is rotatably mounted to the protruding end of the guide bar 410. A wire 420 that spans the second pulley 411 and the second pulley 411 and has a weight 421 mounted at one end thereof, and the other end of the wire 420 is connected to unwind or rewind the wire 420 Or a top-down segment descending control system, characterized in that the eccentricity measuring device 400 consisting of a wire reel 430 for controlling the stationary state is added. The method of claim 1,
The fixture 200 is composed of two members of an inner fixture 210 and an outer fixture 220 that can be coupled and separated from each other, and the coupling surface between the inner fixture 210 and the outer fixture 220 is each first fixing hole Top-down segment descent control system, characterized in that formed to pass through the center of (230). The method of claim 1,
The top-down segment lowering control system, characterized in that a concave groove-shaped fixture mounting groove (22) is formed on the surface of the segment block (21). The method of claim 1,
At the lower end of the segment shoe 10, a downwardly inclined surface is formed while going outward from the vertical sphere (1) center direction,
A third fixing hole 11 is formed on the inclined surface of the lower end of the segment shoe 10, and a first pulley 12 having a circular cross-sectional shape is mounted inside or outside the segment shoe 10 to fix the third A top-down segment descending control system, characterized in that the direction of connection between the strand 30 and the segment shoe 10 is changed while the strand 30 connected to the hole 11 spans the first pulley 12. The method of claim 1,
The segment controller (100) is a top-down segment lowering control system, characterized in that the reel (reel, 180) is mounted on the strand (30) is wound. The method of claim 1,
At the entrance of the vertical sphere (1), two or more press fittings 300 are arranged to form a certain angle,
The indenter 300 is a top-down segment lowering control system, characterized in that consisting of a press-fit support 310, a press-fit unit 320 connected downward to the end of the press-fit support 310. The method according to any one of claims 1 or 10,
At least one auxiliary controller 500 is mounted on the segment shoe 10,
Auxiliary controller 500 includes a fixing table 510 formed to protrude from the inner arch surface of the segment shoe 10 so as to face the vertical sphere 1 center direction, and an auxiliary control that is mounted under the fixing table 510 and can be extended or retracted. Top-down segment descent control system, characterized in that consisting of a unit (520). A plurality of layers on the top surface of the ring-shaped segment shoe 10 inserted into the excavation surface of a circular cross-section through a ring-shaped segment 20 to which a plurality of arc-shaped blocks or segment blocks 21 made of caisson are connected By stacking and constructing the wall of the vertical sphere (1),
A segment shoe and a lowermost segment installation step of arranging the segment shoe 10 at the position of the vertical sphere 1 to be constructed, and coupling the lowermost segment 20 to the upper segment shoe 10;
A segment controller that installs a segment controller 100 consisting of an upper support 110 that is connected to the lower support 120 so as to be elevating and descending through the lower support 120 and the control unit 130 on the upper surface of the vertical hole 1 inlet. Installation steps;
The second fixing hole 112 formed in the upper fixture 111 that is directly or indirectly mounted on the upper support 110 of the segment controller 100 and the third fixing hole formed in the segment shoe 10 at the end of the stranded wire 30 After passing through (11) in sequence, the stranded wire 30 is fixed to the upper stopper 31 mounted in the second fixing hole 112, and the stranded wire 30 exposed to the bottom of the third fixing hole 11 A step of connecting a stranded wire for fastening the lower stopper 32;
A segment lamination process in which segments 20 are stacked in a plurality of layers on the segment shoe 10, and a first fixing hole formed in each fastener 200 by mounting two or more fasteners 200 on the surface of the segment 20 A segment fixing process of connecting and fixing the stranded wire 30 to 230, and
The vertical sphere (1) bottom surface is excavated to lower the segment shoe (10) and the segment (20), and when the segment (20) descends or stops, locking or releasing between the upper stopper (31) and the strand (30) a segment stacking step in which a segment lowering process for controlling (releasing) is repeatedly performed;
It consists of,
The segment stacking step further includes a segment alignment process of aligning the segments 20 through tension control of the strands 30 through operation of each control unit 130 when eccentricity occurs between the stacked segments 20. Vertical ball construction method using a top-down segment descent control system. The method of claim 12,
When the segment stacking step is completed, a vertical ball construction method using a top-down segment lowering control system, characterized in that a step of separating the strands 30 by releasing the upper stopper 31 and the lower stopper 32 is added. The method of claim 12,
In the segment controller installation step, two or more segment controllers 100 are installed so as to achieve the same number and angle as the fixtures 200 mounted on each segment 20, and in the upper fixture 111 of each segment controller 100. The second fixing hole 112 formed is a vertical ball construction method using a top-down segment lowering control system, characterized in that formed to have the same number and arrangement intervals as the first fixing holes 230 formed in each fixture 200. The method of claim 12,
The segment controller 100 extends so that the end in the vertical sphere 1 direction of the upper support 110 is positioned above the stacked segment 20, and the support unit 160 is extended to the lower surface of the upper support 110 It is connected downward so that it can be disposed in the top end of the stacked segments 20, and the upper support 110 and the support unit 160 are configured to be able to change the connection angle through the first hinge 170,
Vertical ball construction using a top-down segment lowering control system, characterized in that when the segments 20 are aligned through the operation of the control unit 130 in the segment stacking step, the support unit 160 operates to support the top end of the segment 20 Way. The method of claim 12,
The lower supporter 120 includes an upper structure 121 on which the control unit 130 is mounted, and a lower structure 122 fixed to the entrance of the vertical hole 1, and the upper structure 121 of the lower supporter 120 A horizontal moving unit 123 is added to the connection between the lower structure 122 and the upper structure 121 horizontally moving the upper structure 121 toward or away from the vertical sphere (1),
Vertical ball construction method using a top-down segment lowering control system, characterized in that the position of the upper support 110 is adjusted through the operation of the horizontal moving unit 123 when performing the segment stacking step. The method of claim 12,
The segment stacking step further includes an eccentricity measuring process of measuring the eccentricity of the stacked segments 20 through the eccentricity measuring device 400,
The eccentricity measuring device 400 is mounted on the segment controller 100 so as to protrude toward the center of the vertical sphere 1, and the protruding end of the guide bar 410 and the protruding end of the guide bar 410 is adjusted by slide movement. A second pulley 411 that is rotatably mounted on a wire 420 that spans the second pulley 411 and is mounted with a weight 421 at one end, and the other end of the wire 420 is connected to the wire 420 ) Vertical ball construction method using a top-down segment lowering control system, characterized in that consisting of a wire reel 430 to control the unwinding or rewinding or stop state. The method of claim 12,
The fixture 200 is composed of two members of an inner fixture 210 and an outer fixture 220 that can be coupled and separated from each other, and the coupling surface between the inner fixture 210 and the outer fixture 220 is each first fixing hole It is formed to pass through the center of 230,
In the segment fixing process of the segment stacking step, when the inner fastener 210 and the outer fastener 220 are coupled, the stranded wire 30 is connected to the first fixing hole 230 to fix the stacked segments 20 to each other. Vertical ball construction method using a top-down segment descent control system. The method of claim 12,
The segment block 21 surface has a concave groove-shaped fixture mounting groove 22 on which the fixture 200 is mounted,
A vertical sphere construction method using a top-down segment descending control system, characterized in that it minimizes the occurrence of interference between the side of the vertical sphere (1) excavated in the segment descending process of the segment lamination step and the fixture (200). The method of claim 12,
In the segment shoe and the lowermost segment installation step and the strand connection step, a downwardly inclined surface is formed at the lower end of the segment shoe 10 while going outward from the center direction of the vertical sphere (1),
A third fixing hole 11 is formed on the inclined surface of the lower end of the segment shoe 10, and a first pulley 12 having a circular cross-sectional shape is mounted inside or outside the segment shoe 10 to fix the third Vertical sphere using a top-down segment descent control system, characterized in that the direction of connection between the strand 30 and the segment shoe 10 is changed while the strand 30 connected to the hole 11 spans the first pulley 12 Construction method. The method of claim 12,
In the step of installing the segment controller, two or more press-fit units 300 consisting of a press-fit support 310 and a press-fit unit 320 connected downward to the end of the press-fit support 310 to the upper surface of the inlet of the vertical hole 1 are placed at a certain angle The press fitting installation process to install to achieve is added,
Vertical ball construction method using a top-down segment descending control system, characterized in that the segment 20 is press-fit downward through the operation of the press-fitting unit 320 in the segment descending process of the segment stacking step. The method according to any one of claims 12 or 21,
In the segment shoe and the lowermost segment installation step, an auxiliary controller mounting process of mounting one or more auxiliary controllers 500 to the segment shoe 10 is added,
Auxiliary controller 500 includes a fixing table 510 formed to protrude from the inner arch surface of the segment shoe 10 so as to face the vertical sphere 1 center direction, and an auxiliary control that is mounted under the fixing table 510 and can be extended or retracted. Vertical sphere construction method using a top-down segment lowering control system, characterized in that consisting of a unit (520).

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