KR200390445Y1 - Auto-syncronized supporting system controlling to recover and offset displacement and repulsive force occurred according to working load - Google Patents

Abstract

       In order to prevent the earth and sand from collapsing during the excavation work for the installation of underground structures, the present design utilizes the displacement and load generated by earth pressure or water pressure to support the vertical wall and band support of the earthquake structure. To support the earth pressure or hydraulic pressure while restoring and canceling the displacement and load by interlocking the relationship, and feedback the site measurement value and the design control value to recover and offset the hydraulic jack by automatically linking the stroke of the hydraulic jack again. Supported under the formwork installed for reinforcing concrete and reinforcing steel reinforcement, the displacement and load generated by concrete placing and reinforcing steel reinforcement are linked to the capber amount and load relationship of the design management value to directly recover and offset the displacement and load. Also, feedback the field measurement site and design management value If the eonal concerned will again for the stroke by inserting yuapjaek the retaining wall and the support structure supporting the system for synchronizing to Shore for supporting a concrete structure with recovery and offset automatically by interlocking.

Description

Auto-syncronized supporting system controlling to recover and offset displacement and repulsive force occurred according to working load}

       The present design utilizes the displacement and load generated by earth pressure or water pressure by using the vertical wall and band support of the earthquake structure that is installed to prevent the earth and sand from collapsing during the excavation work to install the underground structure. In order to support the earth pressure or hydraulic pressure by directly restoring and canceling the displacement and load by linking the relationship between and the load, or to be installed under the formwork installed for reinforcement concrete casting and reinforcing steel reinforcement, The present invention relates to an earth retaining structure and a synchronizer support system for supporting structural structures, in which a displacement and load generated are linked to a camber amount and a load relationship of a design management value while supporting and restoring a direct displacement amount and load.

       In general, the earth block structure is connected to the earth excavation surface to install vertical piles at regular intervals, and to support the earth pressure or displacement generated by excavating the soil vertically, and to support the earth pressure or displacement at a predetermined interval inside the vertical piles and the girdle and the right angle brace In the installation, in the case of installing the inclined (raker) brace instead of the right angle brace, it is installed inclined so as to maintain a constant angle in contact with the upper portion of the raker girder in a band installed on the upper portion of the vertical pile, and the lower portion of the raker girder After the foundation is installed on the excavation surface of the trench, it is installed on it so as to directly support the vertical pile.

       The above description describes the existing method of installing the raker girder to support the vertical pile of the soil barrier. The vertical pile support of the soil barrier using the existing raker girder can support only one stage. The applicability was limited compared to the very high effective aspects such as maximum security and reduction of construction cost.

       The system was developed to overcome this. The system installs a vertical member at a position coincident with the lateral band position of the vertical wall installed by the stepwise excavation on the girder, and installs a load displacement linkage and fixing device at the end of the vertical member, The tension cable is installed, and the tension cable is fixed to fixing devices provided at both ends of the raker girder.

       The vertical member changes its length according to the earth pressure and the magnitude of the displacement, and the shape of the tension cable installed in connection with the vertical member is similar to that of the moment distribution diagram.

       After the first step is excavated after cutting by Icelandic method around the vertical pile of earthen board, the synchronizer raker girder support system is installed and fixed on the foundation installed on the final excavation surface after cutting the central part. In accordance with the two-stage excavation installed in the two-stage excavation and the position of the vertical material of the first stage of the system, directly install and fix the load-carrying brace with the screw jack, and then to the load displacement interlocking and fixing device installed at the end of the vertical Insert the hydraulic jack and interlock the strokes by directly comparing the design management values and the measurement results of the displacement gauges attached to the girders and vertical members with the load gauges according to the displacements and load sizes of the working loads. The tension cable installed adjacent to it acts as a reaction zone for the jack, And a supporting synchronized raker girder support system.

       This excavation several times in the three-stage, four-stage, etc. of the earthquake raker girder to repeatedly install and interlock the system to support the earth walls.

       Another embodiment is to use the earthen wall as a vertical pile at regular intervals in connection with the earth excavation surface and excavation of the soil vertically while installing the girders horizontally at regular intervals inside the vertical piles The horizontal braces with screw jacks are installed on both ends of the girder to make them significantly wider to fix the synchronizer girders supporting system, and then the fixing devices are installed at both ends of the girders girder system, and the vertical members are installed at regular intervals. While the length of the vertical member is extended to the center portion, while the vertical member is gradually reduced in the length of the vertical member installed on both sides while the load displacement interlocking and fixing device is installed at the end of the vertical member fixed to the both sides of the band girders While the tension cable is fixed to the device, the tension cable is Install the hydraulic jack into the load displacement linkage and fixing device according to the external earth pressure and displacement size by installing it in contact with the load displacement linkage and fixing device installed in the part. It is a synchronizer girders supporting system that significantly cancels horizontal braces by directly canceling and recovering earth pressure and water pressure of the earth wall by interlocking with feedback from actual field measurements.

       As another application example, the displacement amount and load generated by placing concrete under the formwork for placing concrete structures and reinforcing steel are directly linked to the camber amount and load relationship of the design management value and directly offset the displacement amount and load. As a structural support bar installed to support a concrete structure, the bridge case is described as an example. A foundation is installed on the ground between the bridges, a temporary vent is installed thereon, and a vertical girder is installed on the temporary vent. After the horizontal beam is installed laterally at regular intervals on the vertical girder, formwork for forming concrete concrete slab is installed thereon,

       A vertical member is installed at regular intervals at a lower portion of the vertical girder, and the vertical member is installed at both sides while the length of the vertical member is increased, and the vertical member is gradually reduced in length. After the fixing device is installed, the tension cable is fixed to the fixing devices installed on both sides of the vertical girder, and the tension cable is installed in contact with the load displacement linkage and the fixing device installed at the lower part of the vertical member so that the parabolic tension cable is installed. Afterwards, it is a synchronized movement blockage system for installing concrete by directly placing and reconstructing the working load and displacement by the same mechanism as that of the raker girder system or the strip system.

       Insert the hydraulic jack into the load displacement linkage and fixing device attached to the end of the vertical member installed at right angles to the raker girder, band girders, and vertical girder of the synchronizer support system as described above. When the support system is installed at the design position in which the displacement amount and stress required for the design are introduced at the design position, the displacement and the stress are acted on the girder by the external load, which is the displacement of the design management value introduced at the time of manufacture. And a mechanism that cancels directly by the stress and the girder is provided with a displacement gauge and a load gauge to connect the measured values of the actual displacement and load to the computer and feed back to the design management value, if there is a risk of deviation from the allowable value. Operate the hydraulic cylinders that are interconnected to each other to reduce the stroke of the hydraulic jack. It is a synchronizer support system used for a raker girder, bandage girder, or copper bar that supports concrete concrete structure to support external load such as earth pressure by restoring direct displacement or offsetting load to adjust it to design control value. will be.

       The purpose of the present invention is to insert a hydraulic jack into the load displacement interlocking and fixing device attached to the end of the vertical member installed at right angles to the raker girder, band girders and the vertical girder of the synchronizer support system, By using the reaction force, the displacement and load required in the design are introduced in advance, and a system in which the tension force is introduced in the design position instead of the conventional compression prestressing force is introduced into the cable, and the external load acts on the girder. Displacement and load due to external load have a mechanism that directly recovers and cancels by the camber and load introduced and required in the design at the time of manufacture.In addition, a sensor of displacement gauge and load gauge is attached on the girder and connected to the computer. Feed back actual measurements and design control values to In case of fear, it is possible to operate hydraulic cylinders that are interconnected to each other in circuit, so that the stroke of hydraulic jacks can be interlocked to adjust within the design management value. It is to provide a method of installing a synchronizer support system applied to a wall raker girder, a strip girder, or a copper cladding method for supporting concrete structures.

       In the prior art, as shown in Fig. 1 to support the earth pressure by installing a raker strut 11 inclined to the earth pressure acting on the vertical wall excavated soil vertically in one stage, the first stage belt 13 for structural safety Excavation depth is extremely limited because it can only be installed and supported. If the excavation depth is deep or the displacement is large, the horizontal brace and the intermediate pile must be installed in addition to the raker strut 11 so that the air can be increased. Due to the problems and the need to install additional steel materials, the increase in construction cost and the use of auxiliary steel has become a narrow space, there is a problem such as constraints of the equipment work space.

       Conventionally used in conventional excavating earth wall construction technology is the installation of the vertical pile 15 as shown in Figure 2 and the belt strip 13 is installed at regular intervals laterally to support it, and the strip sheet 13 Install the intermediate pile 19 so as to support the brace 20 horizontally installed at 2 to 4m intervals and these braces 20, and install the bracing 18 to ensure the safety of the temporary structural system, the belt length 13 And a jack jack 12 is installed between the brace 20 to install the earth wall 10 to support the earth pressure.

       The barrier wall 10 installed by the above method has a bandage 13 due to the action of increasing air pressure and earth pressure due to the economical deterioration due to the dense steel arrangement, which is the problem mentioned in FIG. It is difficult to control the displacement generated in the case that the civil petition due to the subsidence of the earth wall and the vertical wall of the retaining wall 10 do not face each other.

       In order to somewhat expand the gap between the brace 20 and the brace 20 as shown in Figure 3 in order to solve the problem as described above, as shown in Figure 2 to install the band 13 and the brace 20, but the brace ( Attaching a separate reinforcing band length 23 to the band length 13 between the 20 and the brace 20, and the PS steel wire 22 to the fixing device 21 installed in pairs at both ends of the reinforcing band length 23 Next, the PS steel wire 22 is tensioned and fixed, so that the prestressing force of compression acts to offset the moment of external force by the eccentric moment generated thereby.

       The moment of reversal of moment in the PS steel wire 22 anchoring position causes a stress concentration in the position, and the uniform stress linear distribution generated in the strip 13 due to the eccentric moment causes the parabolic state of the moment generated by the external force. Due to the mismatch between the stress state and the displacement generated during the excavation at each excavation stage, which is characteristic of the excavation work, the stress state generated in the strip 13 is not appropriately restored and the displacement is changed step by step. There is a problem in that it does not properly correspond to the limit of the applicability, and the displacement of the vertical wall can not be properly controlled, causing settlement problems of earth and sand on the peripheral surface of the vertical wall.

       The improvement of the method of FIG. 3 is to improve the method of FIG. 4 to increase the spacing of the brace 20 installed in the belt 13, so that the eccentricity is generated in the reinforcing belt 23 so that a large distance is generated. The spacer 24 is installed, and the PS steel wire 22 is in contact with the lower end of the spacer 24 while fixing the PS steel wire 22 to the fixing device 21 installed at both ends of the reinforcing strip length 23. After installation, the tensile force is applied to both ends of the PS steel wire 22, and then it is tension-fixed to the fixing device 21, and a compressive force is introduced into the PS steel wire 22, and the compressive force is generated by an external force by generating an eccentric moment. As a way to offset the moment,

       In the case of the method, since the external force moment increases considerably when installing the strip length 13 between the long spans, the eccentric moment must be generated largely to offset the prestress force introduced into the reinforcing strip length 23, and the PS steel wire ( 22) The amount is also excessively used, and the fixing device 21 used accordingly is excessively required, and the additional reinforcing band length 23 is required to be superimposed so that an excessive amount of steel and excessive tensile force are required, which is an uneconomical factor. Due to the excessive weight of the installed device, the efficiency of the field installation work is reduced and the prestress cannot be adjusted as the device is manufactured and installed. Therefore, it is appropriate to cope with the load change caused by the stepping and backfilling, which is the characteristic of the excavation work. There is a limit to its applicability, and the displacement of the generated vertical wall There is a problem of civil complaints due to the inability to control the back settlement of the vertical wall, there is a problem in that the excavation work should be relatively large because the length of the spacer is increased to generate excessive eccentric moment.

       In addition, the structure supporting movement bar for supporting the load of the slab in the existing slab concrete casting, as described in Figures 5 and 6, the entire structure for supporting the entire lower part of the concrete slab concrete 31 with the steel pipe support (33) There is a support structure of the structure 30 by means of a temporary vent (39) to install and support the support shaft method (30) and the temporary vent (39), the vertical girders (35) and side beams (36) installed thereon. The amount of steel used to support both of the above is increased, and the steel pipe holder 33 and the temporary vent 39 are installed in the lower space to be supported, so the lower space cannot be utilized, so the traffic bypass road can be separately created or temporarily constructed during the bridge construction. As a result, there are problems such as additional cost of construction and civil complaints due to the closure of roads. It has to be a hydraulics problem occurs lingering issues that have to be there to stop the construction during the rainy season.

       The present invention is proposed to improve the problems as described above, if the internal load and displacement caused by the external load, that is, earth pressure, hydraulic pressure, pour weight on the raker girder, band girders or longitudinal girders applied to the wall and the structure support bar The hydraulic jack is inserted into the load displacement interlocking and fixing device attached to the end of the vertical member installed at right angles to the strip girders, the raker girder and the vertical girder, and the tension cable installed in contact with the device length is used as a reaction force. When the displacement amount and load are introduced by the jack's stroke linkage, and the cable is equipped with a synchronized support system in which a tension force is introduced at the installation position, it has a mechanism to recover the displacement due to the external load and at the same time cancel the load. On the vertical girder, a displacement gauge and a sensor of a load gauge are attached to calculate the measured measurement value. To the design management value by connecting to the control system, and when there is a deviation or deviation from the allowable limit, by operating the hydraulically interconnected hydraulic jacks to interlock the strokes of the hydraulic jacks to manage displacement and load within the design management values. A method of installing a system for supporting earth pressure or supporting a concrete concrete structure by acting upward by a displacement recovery amount to cancel the displacement and load acting on the longitudinal girder and returning it to its original state.

       By constructing the construction using the above system, the application depth can be greatly increased to execute the multi-stage excavation stage, and the Icelandic method can be applied by greatly reducing the number of braces, and the equipment space is maximized to shorten the air. It can improve the economic efficiency by reducing construction cost by reducing the cost of materials and materials, and can apply the conventional method supported by the belt and brace more efficiently, thereby minimizing the use of steel materials, increasing the economic efficiency, and reducing the air by securing the working space. It is designed to feed the displacement of the load displacement linkage and the fixing device to feed back and control the load change due to the excavation or backfilling step by step, and to automatically adjust the stroke of the construction. Stability can be increased, and the previously generated displacement is partially restored. In order to prevent and recover the settlement of the surrounding rear surface, it is economical, safety and efficiency that can block civil complaints that may occur in urban construction in advance, and it is very effective to apply conventional methods more efficiently. It is to provide a construction method of a wide range of applicability.

       The present invention, when used as a retaining wall, is installed in the vertical pile 15 in order to support the earth pressure or displacement caused by installing the vertical pile 15 at regular intervals in connection with the earth excavation surface and excavating the soil vertically In installing the band 13 and the horizontal brace horizontally at intervals, in the case of installing the raker (tilt) brace 45 instead of the horizontal brace, the raker on the band 13 installed on the upper portion of the vertical pile 15 It is installed to be inclined to maintain a constant angle while being installed in contact with the upper portion of the girder 45, the lower portion of the raker girder 45 is installed on the excavation surface of the final breaker line 16, and then installed thereon Let's do it,

       On the raker girder 45, a vertical member 44 is installed at a position coincident with the horizontal direction 13 position of the vertical wall 15, which is installed according to the stepwise excavation, and the load is applied to the end of the vertical member 44. Displacement interlocking and fixing device 60 is provided, and the tension cable 43 is installed in contact with the device 60, and the tension cable 43 is fixed to the fixing device 42 at both ends of the raker girder 45. do.

       The vertical member 44 changes its length according to the earth pressure and the magnitude of the displacement, and the shape of the tension cable 43 which is installed in contact with the vertical member is similar to the moment distribution and is proportional to the external force. The synchronization support system 40 is characterized by having a structure that is more economical, safer and more efficient because of less adjustment.

       After cutting the central part by the Icelandic method around the vertical pile 15, the first stage transverse length 13 and the foundation 17 installed on the central excavated final excavation surface 16 were installed after the first step excavation. After the installation of the synchronizer support system 40 is fixed, the two-stage excavation 59 is installed and the screw jack 12 is attached in accordance with the position of the first stage 44 of the system 40. After the load transmission brace 40 is installed and fixed at right angles, the hydraulic jack 64 is inserted into the load displacement interlocking and fixing device 60 installed at the end of the vertical member 44 of the first stage, and the stroke is transferred to the displacement and load. Comparing the measured values of the design management value and the measurement results of the displacement gauge 54 and the load gauge 53 attached to the girder 45 and the vertical member 44 so that the displacement and load can be directly returned and canceled, and the stroke is interlocked. When the tension cable 43 is installed in contact with the reaction force of the jack (64) A synchronizing raker girder support system for installing and supporting a tensile force to act as a role.

       The excavation is carried out in three or four stages, such that the system is repeatedly installed and interlocked to support the retaining wall.

       Another embodiment of the retaining wall, the vertical pile 15 is installed at regular intervals in connection with the earth excavation surface, and the excavation of the earth and sand vertically while the vertical pile (15) inside the horizontal girders (46) ) And then install the horizontal brace 20 with the screw jack 12 attached to both ends of the girder girder 46 to allow the girder girder 46 to be supported. The fixing device 42 is installed at both ends of the side), and the vertical member 44 is installed at regular intervals, while the length of the vertical member 44 is increased in the center portion, and the length of the vertical member 44 installed on both sides is gradually increased. While installing the small vertical member 44, the load displacement interlocking and fixing device 60 is installed at one end of the vertical member 44, and then a tension cable (for the fixing device 42 provided on both sides of the band girder 46). 43) after the tension cable 43 is fixed It is installed in contact with the load displacement interlocking and fixing device 60 installed in the lower portion of the woven fabric 44 so that the parabolic tension cable 43 is installed so that the load displacement interlocking and fixing device and the hydraulic jack are installed according to the displacement size. The stroke of the jack 64 is fed back to the design management value and the actual field measurement result so as to support the earth pressure of the retaining wall so as to greatly reduce the horizontal brace girder gird support system 40.

       As another application embodiment, which is to be applied to the structure support bar (30) to support the structure when installing the concrete structure, it is generated while placing the concrete installed in the lower part of the formwork 32 for installing the concrete structure It is a structure supporting bar installed to support concrete structure while restoring and offsetting displacement amount and load by linking displacement amount and load to the camber amount and load relationship of the design management value. After installing the foundation 38 on the ground between the installation of the temporary vent 39 thereon, and the vertical girders 35 on the temporary vents 39 after a certain interval on the vertical girders 35 After the horizontal beam 36 is installed laterally, formwork 32 for forming the concrete concrete slab 34 is installed thereon.

       Vertical member 44 is installed at a lower portion of the vertical girder at regular intervals, while the length of the vertical member 44 is increased in the center, while the vertical member 44 is gradually reduced in length. 44), load displacement interlocking and fixing device 60 to be installed in the lower portion of the vertical member 44, and then tension cable 43 to the fixing device 42 installed on both sides of the longitudinal girder (35). While fixing, the tension cable 43 is installed in contact with the load displacement interlocking and fixing device 60 installed in the lower portion of the vertical member 44 so that the parabolic tension cable 43 is installed, and then occurs when concrete is poured. If there is a risk of offsetting and restoring the load and displacement, or the deviation from the design management value through actual measurement and feedback, insert the jack again and install the structure while directly controlling the stroke adjustment of the jack with the computer. A synchronizing Shore support system 40 for recording.

       Load displacement interlocking and fixing device 60 attached to the end of the vertical member 44 installed at right angles to the raker girder 45, the column girder 46, and the longitudinal girder 54 of the synchronizer support system 40 as described above. Insert the hydraulic jack (64) into the system, and use the tension cable (43) installed in contact with the end of the device (60) as a reaction force, and install the system (40) in the state where the displacement amount and load required in the design were introduced. It has a mechanism for canceling the load and the displacement recovery 55 caused by the external load acting on the girders (45, 46, 54), and on the girder by installing a displacement meter 54 and a load meter 58 When connected to the (48) and the design management value (49) feedback or if there is a risk of deviation or deviation, the hydraulic cylinder 50 is interlocked to operate through the hydraulic hose 51 is delivered to the stroke of the hydraulic jack (64) Interlock (56) directly into the design management value Synchronized support system for supporting and using raker girder, strip girders, or concrete concrete structures on the wall of walls to support external loads such as earth pressure by restoring displacement (55) or offsetting loads (57). 40).

       Hereinafter, with reference to the accompanying drawings the configuration and operation of the present invention in detail as follows.

       FIG. 7 is a view showing that the synchronizer support system of the present invention is installed on a raker girder installed to support a vertical pile and installs a retaining wall to support earth pressure. The vertical pile 15 is connected to a soil excavation surface at regular intervals. To install and support the earth pressure or displacement generated by excavating the soil vertically to install a strip 13 horizontally at regular intervals inside the vertical pile (15), the strip is installed on top of the vertical pile (15) The raker girder 45 is installed to be inclined while being installed in contact with the upper portion of the raker girder 45 so as to maintain a constant angle, and the lower portion of the raker girder 45 is disposed on the excavation surface of the final trench line 16. After installing the foundation 17, let it be installed there,

      On the raker girder 45, a vertical member 44 is installed at a position perpendicular to the band long 13 installed horizontally on the vertical pile 15 installed by the stepwise excavation, and the load displacement is applied to the end of the vertical member 44. Interlock and

The fixing device 60 is installed, and the tension cable 43 is installed in contact with the device 60 and fixed to the fixing device 42 installed at both ends of the raker girder 45.

      The vertical member 44 is installed varying the length in accordance with the earth pressure and the size of the displacement, the installation shape of the tension cable 43 installed in contact with the vertical member 44 installed in the various length is installed in proportion to the moment size Therefore, the synchronization support system 40 is installed to have a more effective offset and recovery mechanism of the external load and displacement.

      The foundation (17) installed on the first stage horizontal strip (13) and the trench (16), which is the final excavated surface of the central section, are cut after the first stage is excavated and cut in the center part of the soil pile vertical pile (15). And fix the synchronizer support system 40 to the second stage, and excavate in two stages to form a two-stage excavation line 59, and then install the two-stage belt length 13 and the first stage vertical member 44 of the system 40. In accordance with the position, and fixed to the load transmission brace 41 with the screw jack 12 attached to the right angle, the hydraulic jack (64) to the load displacement interlocking and fixing device (60) installed at the end of the vertical member 44 of the first stage. ), And the strokes are connected to the computer by connecting the design management values of the displacements and loads and the measurement results of the displacement gauges 54 and the load gauges 53 attached to the girder 45 and the vertical member 44 to a computer. By comparing the hydraulic cylinders of the hydraulic jacks When the stroke is interlocked, the stroke size is returned and canceled, and when the stroke is interlocked, the tension cable 43, which is in contact with the stroke, serves as a reaction zone for the jack 64, and the cable is introduced with a tensile force to act on the girder. It is a synchronized support system that installs and supports over displacement and displacement directly.

      The excavation is repeatedly carried out in three, four, and the like to repeatedly install and interlock the system to support the retaining wall.

       8 is a view showing the installation of the earthen wall to support the earth pressure by installing the synchronizer support system of the present invention to the band girders, the vertical pile 15 is installed at regular intervals in connection with the earth excavation surface and the soil is vertically The horizontal brace 20 is provided with screw jacks 12 attached to both ends of the girder girders 46 at a wider interval after the installation of the girders 46 laterally at regular intervals inside the vertical pile 15 while being excavated. ) To support the strip girders 46, and then, the fixing devices 42 are installed at both ends of the strip girders 46, and the vertical members 44 are installed at regular intervals. After installing the load displacement interlocking and fixing device 60 at one end of the vertical member 44 while installing the vertical member 44 gradually decreasing the length of the vertical member 44 installed on both sides while lengthening the central portion. The girdle The tension cable 43 is installed in contact with the load displacement interlocking and fixing device 60 installed in the lower portion of the vertical member 44 while fixing the tension cable 43 in the fixing device 42 provided on both sides of the girder 46. The parabolic tension cable 43 is installed so that the hydraulic jack is inserted into the load displacement linkage and fixing device according to the load and displacement size, and the stroke of the jack 64 is fed back to the design management value and the actual field measurement result. By interlocking to support the earth pressure of the retaining wall is a synchronized support system 40 to greatly reduce the horizontal brace.

       9 is a view showing a process of directly controlling the load and displacement generated in the raker girder, belt girders, and vertical girders of the earthen wall using the synchronizer support system of the present invention, as shown in FIGS. The hydraulic jack is connected to the load displacement interlocking and fixing device 60 attached to the end of the vertical member 44 installed at right angles to the raker girder 45, the band girder 46, and the longitudinal girder 54 of the synchronizer support system 40. Insert (64), use the tension cable (43) installed in contact with the end of the device (60) as a reaction force, and the tension cable (47) is introduced into the tension cable to introduce the displacement amount and load required in the design (40). ) Is installed in the design position, and has a mechanism for canceling the displacement and the load caused by the external load acting on the girders 45, 46, 54 and the direct displacement recovery 55 and the load. With displacement meter 54 When the relay 58 is installed and connected to the computer 48 to feed back the design management value 49 to operate the hydraulic cylinder 50 interlocked with each other when there is a risk of deviation or deviation from the allowance, the hydraulic hose 51 is operated. Raker girder of the earthquake wall which is transmitted to interlock 56 of hydraulic jack 64 to recover displacement 55 to adjust directly into design management value or offset load 57 to support external load such as earth pressure. (2) A synchronizer support system (40) for supporting girders or concrete concrete structures and for use in clubs.

       10 is a view showing a process in which the synchronizer support system of the present invention is installed to support the formwork in the lower part of the concrete slab to control the load and displacement generated by the concrete slab. It is to be applied to the structure support bar (30) so that it can be supported, it is installed in the lower part of the formwork 32 for installing the concrete structure, the displacement amount and load generated while placing concrete to the camber amount and load relationship of the design management value It is a structure support bar which is interlocked and installed to support a concrete structure while restoring and canceling displacement and load. For example, in the case of a bridge, a base 38 is installed on the ground between the piers 37. After installing the temporary vent 39, the vertical girder 35 is installed on the temporary vent 39, the vertical girder 35 At regular intervals to install the mold 32, for forming a concrete slab thereon after installing a hoengbim 36 in the transverse and,

      Vertical member 44 is installed at a lower portion of the vertical girder at regular intervals, while the length of the vertical member 44 is increased in the center, while the vertical member 44 is gradually reduced in length. 44), load displacement interlocking and fixing device 60 to be installed in the lower portion of the vertical member 44, and then tension cable 43 to the fixing device 42 installed on both sides of the longitudinal girder (35). After fixing, the tension cable 43 is installed in contact with the load displacement interlocking and fixing device 60 installed below the vertical member 44 so that the parabolic tension cable 43 is installed. And a synchronizer support system 40 for installing concrete by pouring concrete while adjusting by an offset mechanism.

       11 is a view showing a state in which the tension cable is installed in the load displacement interlocking and fixing device installed in the lower portion of the vertical member of the synchronizer support system of the present invention, the raker girder 45 and the strip girders 46 or longitudinal girder 35 Designed by installing the load displacement interlocking and fixing device (60) in the lower portion of the vertical member 44 installed at regular intervals at each length in the lower portion of the, and the tension cable (43) in contact with the device (60) Interlocking 56 of the jack's stroke into the tooth acts as a reaction zone while generating tension in the tension cable, thereby causing a recovery displacement 55 in the vertical member and an internal reaction 57 in the vertical member 44. The reaction force and recovery displacement are transmitted to the girders girder 46 or the longitudinal girders 35 to offset the displacements of the girders or longitudinal girders where a certain amount of displacement is generated by a certain amount of displacement recovery amount. By the girder and the soil pressure will be allowed to equilibrate to a whole remains stable.

       12 is a view showing load displacement interlocking and fixing device of the synchronizer support system of the present invention, in which the stiffener 61 and the lower jack support plate (for fixing the load displacement interlocking and fixing device 60 firmly to the lower part of the vertical member) 62) to connect and fix the stiffener 61 to the vertical member 44, and at regular intervals to secure a space for installing the jack 64 in the lower portion of the lower jack support plate 62 The upper jack support plate 65 is installed, and the edges of the upper and lower support plates 62 and 65 are interconnected with the high tension bolt 63 and the spring and the nut 67, and the lower upper support plate 65 is tensioned. When the tension cable 43 is installed between the tension cable guide plate 66 while the tension cable guide plate 66 capable of guiding the cable 43 is installed, the center portion is convex so as to be in close contact with the tension cable. The curvature plane The jack upper support plate 65 may be installed so that the jack 64 can be inserted and removed, and the displacement stroke 56 is operated as much as the design management value, and then fixed by the high tension bolt 63 and the spring and the shoulder nut 67. It is to install load displacement interlock and fixing device.

       Figure 13 is a view showing a method of fixing the hydraulic jack of the jack lower support plate of the load displacement interlocking and fixing device of the present invention, the jack upper and lower support plates (62, 65) by installing a high-tension bolt 63 to create a hydraulic jack installation space , Insert the hydraulic jack in the center and then tighten the bolt and the spring and the nut (63, 67) in the center of the stiffener (61) installed on both sides of the jack to be fixed.

      14 is a view showing the lower jack support plate of the load displacement interlocking and fixing device of the present invention, as described above in Figure 12, the jack upper, lower support plates 62, 65 are interconnected with a high-tensile bolt 63 to the vertical material ( 44 and the tension cable guide plate 66 installed at both sides while installing the tension cable guide plate 66 capable of guiding the tension cable 43 at the lower portion of the lower jack support plate 65. When the tension cable 43 is installed between the jack lower support plate 65 is installed so that the center surface is convex curvature so that the tension cable more tightly contact.

       Figure 15 is a view showing a cross-sectional AA of Figure 14, to be installed in the form of a open box with a steel plate so as to guide the tension cable 43 to the lower portion of the lower jack support plate 65 to install the tension cable in the box do.

       Fig. 16 is a view showing that the bands are horizontally installed by installing a load-distributing wedge support plate on a vertical pile arranged to install the bands of the synchronizer support system of the present invention, and the soil excavation surface is not a straight line. Since the vertical pile 15 installed along the surface is knitted and installed at a predetermined angle, the bands 13 and 46 installed in the longitudinal direction of the vertical pile at regular intervals on the side of the knitted vertical pile are installed in the future. Since the vertical member 44 must be installed at right angles to the bands 13 and 46 to manage the displacement and the load due to the external load by adjusting the load displacement interlocking and the displacement interlocking of the fixing device 60 installed at the lower portion of the vertical member. When the gap is formed between the vertical pile 15 and the bands 13 and 46 knitted at a predetermined angle, the displacement recovery and the lower Since the offset is not directly transmitted, the load distribution wedge plate 70 is installed within the gap thus compensated for the biased angle so that the belt is installed at right angles to the knitted vertical pile and the vertical material is automatically installed vertically on the band. To do this.

      The load-distributing wedge support plate 70 has a constant thickness of a polygon composed of a sleeper 72 and the iron plate 71 so as not to be deformed to the pressure of the load absorbing dispersion, as shown in the drawing and banded in the vertical pile When installed at right angles, a certain distance is formed between the vertical pile and the band, and the load-distributing interlock and fixing device installed on the vertical member installed on the band by inserting the load-distributing wedge plate in the gap does not cause any direct load offset and displacement recovery. This is to allow the mechanism to be directly transmitted to the girder through the vertical material without structural influence.

       This design utilizes the earthen wall to prevent the earth and sand from collapsing during the excavation work to install the underground structure. Automatically introduces displacement and external load to install on site, offsets displacement and load caused by external force acting on existing girder, and interlocks by on-site measurement and feedback to adjust internal load and displacement again. It is installed in the lower part of the formwork for supporting the concrete structure, or the stress and displacement generated when placing concrete, in conjunction with the design management value, automatically introduces the displacement and internal load by the program pre-inputted on the computer. Installed on site, and the external force acting on this installed girder It is related to a retaining wall and a synchronized support system for a structural support bar, to offset the displacement and the load caused by the load, and to support the concrete structure by mutually interlocking by on-site measurement and feedback.

       It is possible to increase the depth of application for excavation in multiple stages using the lay cover team, maximize the space utilization by greatly reducing the number of props, and maximize the efficiency while reducing the construction cost by reducing the air and materials. In addition to improving the compatibility of the system of the present invention by improving the compatibility of the system of the present invention, while also being able to be applied to the conventional method that was supported by the belt and braces, it is possible to reduce the air by minimizing the use of steel to increase the economy and at the same time to secure the working space It is possible to feed back and control the load change due to the excavation or backfilling step by step, and to respond to the displacement according to the load change appropriately, thereby increasing the efficiency and economic efficiency of the construction work. At the same time, the conventional method It is a method of constructing a very useful and useful system that is compatible to use.

       1 is a view showing the retaining wall to support the earth pressure by installing a raker strut in one stage in the prior art.

       Figure 2 is a view showing the retaining wall made of a prior art belt and the horizontal brace and the intermediate pile.

       Figure 3 is a view showing that the reinforcing strips attached to the reinforcement bands installed with a horizontal PS steel wire introduced pre-stressing force to the strip of the earth wall made of a brace and the strip of the prior art.

       Figure 4 is a view showing the reinforcement by installing a reinforcement belt installed with a plurality of spacers and the PS steel wire introduced prestressing compressive force to the spacer of the earth wall made of a brace and the band as a prior art.

       5 is a view showing that to support the concrete concrete as a whole steel pipe column in the prior art.

       Figure 6 is a view showing that the installation to support the concrete slab is installed on the installation of the temporary belt on the piling foundation in the prior art.

       7 is a view showing that the synchronizer raker girder support system of the present invention supports the vertical pile and the band to install the retaining wall to offset the reaction force and displacement caused by earth pressure.

       8 is a view showing the installation of the retaining wall to offset the reaction force and displacement caused by earth pressure by installing the synchronizer support system of the present invention to the band girders.

       9 is a view showing a process for automatically adjusting the synchronizing support system of the present invention to offset the reaction force and displacement caused by the earth pressure of the earth wall.

       10 is a view illustrating a process of canceling control of reaction force and displacement generated in a concrete concrete slab by installing a synchronizer support system of the present invention in a lower portion of a concrete slab;

       Figure 11 is a view showing a state in which the tension cable is installed in the load displacement interlocking and fixing device installed on the lower portion of the vertical member of the synchronizer support system of the present invention.

       Figure 12 is a view showing the load displacement interlocking and the installation, displacement interlocking, fixing device of the synchronized support system of the present invention.

       Figure 13 is a view showing the lower jack support plate of the load displacement linkage and fixing device of the present invention.

       14 is a view showing a jack upper support plate of the load displacement interlocking and fixing device of the present invention.

       Fig. 15 shows a cross section A-A of Fig. 14;

      Figure 16 is a view showing that the belt length is installed horizontally by installing a load-distributing wedge support plate on the vertical pile knitted in order to install the synchronizer support system of the present invention.

<Description of the symbols for the main parts of the drawings>

        10: retaining wall 11: Raker Strut

        12: screw jack 13: strip

        14: earth and sand 15: vertical pile

        16: breaker ship 17: raker support base

        18 bracing 19: intermediate file

        20: horizontal brace 21: tension fixing device

        22: PS steel wire 23: reinforcing band

        24: Spacer 25: Compression Free Stress

        30: structure supporting bridge 31: concrete concrete

        32: formwork 33: steel pipe holder

        35: bell girder

        36 side beams 37 pier

        38: foundation 39: hypothesis

        40: synchronized support system 41: load transfer brace

        42: fixing device 43: tension cable

        44: vertical 45: raker girder

        46: strip girders 47: tensile force

        48: Computer 49: Feedback

        50: hydraulic cylinder 51: hydraulic hose

        53: load meter

        54: displacement meter 55: displacement recovery amount

        56: interlock displacement 57: internal reaction

        58: Iceland Method 59: Drilling Steps

        60: load displacement interlocking and fixing device 61: stiffener

        62: jack lower support plate 63: high tension bolt

        64: jack 65: jack upper support plate

        66: tension cable guide plate 67: spring and nut

        70: load distribution wedge support plate 71: reinforcing steel plate

        72: load distribution support

Claims (8)

       A band installed horizontally at regular intervals on the inner side of the vertical pile to support the earth pressure or displacement generated by installing vertical piles at regular intervals in connection with the earth excavation surface, and excavating the soil vertically;        A raker girder inclined to maintain a constant angle while being installed to be in contact with the upper portion of the raker girder on a belt installed at the upper portion of the vertical pile;        The lower part of the raker girder is installed on the foundation installed on the excavation surface of the final breaker ship,        On the raker girder 45 is a vertical member installed at a position perpendicular to the band 13 is installed horizontally on the vertical pile (15) installed by the stepwise excavation, the length of the vertical member to increase or decrease in proportion to the size of the earth pressure Install vertical materials,        Load displacement interlocking and fixing device (60) installed at the end of the vertical member (44),        Fixing the tension cable in the fixing device 42 provided on both ends of the raker girder while installing the tension cable 43 in contact with the device 60,        The jack jack 12 is installed at right angles with the vertical strips installed in the horizontal strips and the girder step by step while installing the horizontal strips 13 while excavating in multiple stages such as the first step and the second step by the Icelandic method around the vertical piles 15. Hinged load transfer brace with)        The hydraulic jack 64 is inserted into the load displacement interlocking and fixing device 60 installed at the end of the vertical member 44, and the stroke of the jack is inserted into the displacement and load design management value and the girder 45 and the vertical member 44. The measurement results of the attached displacement gauge 54 and the load gauge 53 are interlocked with a computer to directly return and cancel. The jack 64 acts as a reaction force when the stroke of the hydraulic jack is interlocked with the tension cable 43. An automatic synchronization support system that directly controls and offsets displacements and reaction forces generated by an action load, characterized by supporting tension walls to support the retaining walls.        After installing the vertical pile 15 at regular intervals in connection with the earth excavation surface and excavating the earth and sand vertically, after installing the girders 46 horizontally at regular intervals inside the vertical pile 15, the band girders ( 46 is installed on both ends of the screw jack 12 is attached to the horizontal brace 20 to support the band girders 46,        The vertical device 44 is installed on both sides of the strip girders 46 and the vertical member 44 is installed at regular intervals, and the vertical member 44 is installed on both sides while the length of the vertical member 44 is extended to the center portion. Install the vertical member 44, the length of which is gradually reduced,        A load displacement interlocking and fixing device (60) installed at one end of the vertical member (44),        While the tension cable 43 is fixed to the fixing device 42 installed on both sides of the strip girders 46, the tension cable 43 is connected to the load displacement interlocking and fixing device 60 installed at the lower portion of the vertical member 44. Install it,        The displacement generated according to the working load characterized in that the stroke of the hydraulic jack installed in the load displacement interlocking device and the fixing device is connected to the computer by feeding the design management value and the actual field measurement result to the feedback to support the earth pressure of the retaining wall. Automatic synchronization support system that controls direct recovery and offset.        A foundation 38 is installed on the ground between the piers 37, and a temporary vent 39 is installed thereon.        After installing the vertical girders 35 on the temporary vents 39, the horizontal beams 36 horizontally installed at regular intervals on the vertical girders 35, and the formwork 32 installed to form a concrete slab on the horizontal beams. and,        Vertical member 44 is installed at a lower portion of the vertical girder at regular intervals, while the length of the vertical member 44 is increased in the center, while the vertical member 44 is gradually reduced in length. 44) install        Load displacement interlocking and fixing device 60 is installed in the lower portion of the vertical member 44,        While the tension cable 43 is fixed to the fixing device 42 installed on both sides of the vertical girder 35, the tension cable 43 is connected to the load displacement interlocking and fixing device 60 installed at the lower portion of the vertical member 44. Install it,        Placing concrete on the formwork while controlling the load and displacement by operating the hydraulic cylinder system automatically through the measured values, design management values, and feedback by interlocking the measured values such as the load gauge and the displacement meter installed on the vertical girder with a computer. An automatic synchronization support system that controls the direct recovery and offset of displacements and reaction forces generated by a working load characterized by installing concrete concrete structures such as bridges.        The method according to any one of claims 1 to 3,        Controlling the load displacement by interlocking the synchronizer support system with a computer includes load displacement interlocking attached to the end of the vertical member 44 installed at right angles to the raker girder 45, the column girder 46, and the longitudinal girder 54. Insert the hydraulic jack 64 into the fixing device 60, and use the tension cable 43 installed in contact with the end of the device 60 as a reaction force to adjust the stroke of the jack and the internal load and displacement by adjusting the stroke of the jack. Is installed in the design position, and has a mechanism for canceling the load and displacement recovery 55 by the external load acting on the girders (45, 46, 54), On the girder, a displacement gauge 54 and a load gauge 58 are installed and connected to the computer 48 to feed back the design management value 49 to operate the hydraulic cylinders 50 interlocked when there is a risk of deviation or deviation from the allowable value. Hydraulic arc It is transmitted through the switch 51 so that the stroke of the hydraulic jack 64 is interlocked (56) again to recover the displacement amount (55) or offset the load (57) to adjust the design management value so as to support external load such as earth pressure. Automatic synchronization support system that controls to directly recover and offset the displacement and reaction forces generated by the working load characterized by.        The method according to any one of claims 1 to 3,        The internal load and the displacement of the synchronizer support system are inserted into the hydraulic jack into the load displacement linkage and the fixing device, and the stroke of the jack is interlocked up and down to introduce the high tension bolt and the high tension bolt to preserve the introduced state of the internal load and the displacement. It is fixed with spring and shant, and the tension cable acts as a reaction band when the internal load and the displacement are introduced so that the tensile force is introduced to offset the external load and the displacement. Automatic synchronization support system that controls recovery and offset.        The method according to any one of claims 1 to 3,        The load displacement interlocking and fixing device connected to the lower part of the vertical member allows the stiffener and the lower jack support plate to be fixed to the vertical member, and the jack is spaced at regular intervals to secure a space for installing the jack at the lower part of the lower jack support plate. The upper support plate is installed, and the upper and lower edges of the support plate are interconnected with high-tension bolts and springs and shoulders, and the tension cable guide plate for guiding the tension cable to the lower part of the upper support plate to the tension while installing the tension When the tension cable is installed between the cable guide plates, the jack upper support plate is installed so that the center portion becomes a convex curvature surface so that the tension cable is in close contact with the cable guide plate so as to directly recover and offset the displacement and reaction force generated by the working load. Automatic synchrogenizing support system to control.        The method of claim 6,        The tension cable guide plate is installed in the form of a lap box with a steel plate to guide the tension cable to the lower part of the upper support plate of the jack, and then installs the tension cable in the box so as not to be released according to the characteristic load. Automatic synchronization support system to directly control and offset the displacement and reaction force.        The method according to claim 1 or 2,       When the vertical pile and the strip are knitted at a predetermined angle, a load distribution wedge plate having a constant thickness of a triangle is inserted into the gap between the vertical pile and the strip to compensate for the knitting angle. An automatic synchronization support system that controls the direct recovery and offset of displacements and reaction forces generated by the working loads.