KR101176937B1 - Underground reclamation type water storage tank having a assembling structure and its constructing method - Google Patents

Abstract

PURPOSE: An underground prefabricated water storage tank and a construction method thereof are provided to prevent cracks caused by water leakage and drying shrinkage and to simply assemble precast concrete blocks on a construction site. CONSTITUTION: An underground prefabricated water storage tank comprises L-shaped sidewall blocks(10), upper slab blocks(50), cylindrical column blocks(30), independent footing blocks(20), and elastic assembling rings. The independent footing blocks are assembled in the bottom ends of the cylindrical column blocks to support the cylindrical column blocks. The elastic assembling rings are arranged between the independent footing blocks and the cylindrical column blocks and improve resistance to buoyancy applied to the upper slab blocks and the cylindrical column blocks.

Description

Underground reclamation type water storage tank having a assembling structure and its constructing method}

The present invention relates to an underground buried storage tank for temporarily storing and discharging excess water, initial rainwater, overflow water, constant water, and sewage. The present invention relates to an underground buried prefabricated storage tank and its construction method that can be easily assembled in time, thereby improving workability and reducing costs.

Recently, due to an increase in the amount of runoff due to an increase in buildings or an increase in the surface pavement rate, since rainwater enters the sewer or river at a time during heavy rains, a storage tank is constructed to prevent flooding and storage due to exceeding an inflow allowance. It is designed to store initial rainfall, monthly flow and constant water.

On the other hand, if the inflow of the river is small, the water quality deteriorates, and the groundwater is also depleted, which causes problems. For this reason, technologies for storing rainwater in underground storage tanks, utilizing them as heavy water and adjusting outflows to rivers, and preventing water pollution by storing contaminated initial rainwater and overflow waters to suppress stream and lake outflows For such aquatic conservation, the storage tank constructed in the underground space such as the playground includes a storage tank constructed by a site casting method and an underground buried prefabricated storage tank for assembling precast concrete blocks.

Here, in the case of the storage tank by on-site casting method, there is a problem that water cracking property is easily degraded due to initial cracking due to on-site casting, and a large amount of waste is generated during construction, causing environmental pollution, and the construction period takes a long time. Due to considerable problems in terms of environmental and economical efficiency, in recent years, the use of the PC method of producing precast concrete blocks in advance in a factory and then transporting and assembling them on site is increasing.

However, in the case of the precast concrete block used in the existing underground buried prefabricated storage tank, there is a problem in that the construction is difficult due to the complicated means for fastening while accommodating the manufacturing error occurring in the product, resulting in considerable difficulty in construction. In addition, it is difficult to operate mechanical equipment for internal maintenance due to the small internal cross section width.

In addition, according to the general configuration of the conventional underground buried prefabricated storage tank does not provide a structure that can provide adaptability to the various bearing capacity of the ground where the bottom of the storage tank is disposed, the adaptability to the soft ground or the differential settlement Structural stability is deteriorated, and in addition, the buried work, such as anchors, bolts, etc. for fixing the column to the floor slab in the field is required in advance, and the work required to interconnect them during construction, there is a problem in poor workability.

An object of the present invention is to enable the construction of a storage tank having a smooth internal space of the operation of the mechanical equipment for maintenance, and to simplify the construction and ease of construction when assembling combined due to the simplification of the precast concrete block assembly structure It is possible to reduce the cost by constructing the underground storage tank with labor and time, and by tightly connecting the connection parts of the precast concrete blocks, it has high resistance to uneven settlement and prevents cracks due to leakage and drying shrinkage. To provide underground buried reservoirs.

In addition, the present invention adopts a column structure connectable to the pile foundation as a vertical support member inside the storage tank to improve the adaptability to the foundation foundation on which the prefabricated storage tank is installed, and the independent foundation is sized according to the site conditions (ground conditions) It is possible to obtain variable supporting force by adjusting the power supply, and also to provide the column structure to stably provide the column and girder connection by securing the maximum joint cross section within the buckling range with respect to the structure of the column. The girder and the two upper slab connecting structures have a transverse shear force by improving the method of joining the upper slab and the girder member supporting the upper slab at the lower part of the upper slab forming the reservoir top plate structure as a structural member supported on the surface. Upper slab with higher stiffness relative to There is no need for bolts and holes for installation in the bar.

In addition, the present invention to improve the ease of construction and to increase the maintenance efficiency of the cleaning work, such as the construction of the floor slab construction of the storage tank while eliminating the need for the form assembly process, and the floor slab and the pillar of It is intended to provide a structure that enables construction even in soft ground by improving the joining structure so that the buried work such as anchors, bolts, etc. is unnecessary, improving the workability, and improving the integrity to increase the resistance to leakage.

Furthermore, the present invention is to provide a structure that can prevent the floating settlement of the side wall while further improving the resistance to the driving earth pressure when installing the precast side wall block forming the side wall of the prefabricated storage tank.

In order to achieve the above object, the present invention in the underground buried prefabricated storage tank, the precast sidewall portion of the storage tank buried in the base and the upper slab and the pillars for supporting the upper slab is divided into a plurality of precast formed in the field Concrete blocks comprising a side wall block, an upper slab block, and a pillar block,

An independent foundation block is provided as a precast concrete product assembled at the bottom of the pillar block to support the pillar block,

The independent foundation block is provided with a first connection member having one end embedded and the other end extending outward.

A second connection member is provided at a lower end of the side wall block and the other end extends into the storage tank.

Assembling a bottom reinforcing bar assembly on the ground bottom between the independent foundation block and the bottom of the side wall block, and cast concrete on-site, the concrete to be cast is the first connecting member of the independent foundation block, the second connection of the side wall block An underground buried prefabricated storage tank is provided, wherein the bottom slab of the prefabricated storage tank is provided integrally with the member and the bottom rebar assembly.

In addition, in order to achieve the above object, the present invention in the underground buried prefabricated storage tank construction method, a plurality of pillars supporting the side wall and the upper slab and the upper slab of the storage tank buried underground to be installed in the field An underground buried prefabricated storage tank construction method using precast concrete blocks, including split sidewall blocks, upper slab blocks, independent foundation blocks, and pillar blocks,

A trench and a foundation ground processing step of carrying out the trench and processing the foundation ground;

A side wall member and an independent foundation installation step of installing an independent foundation block for assembling and installing a side wall block constituting the side wall of the storage tank and a pillar block supporting the upper slab block in the field;

A floor slab reinforcing and concrete placing step of assembling a floor reinforcing bar assembly between the independent foundation block and the bottom of the sidewall block and placing concrete on-site;

A pillar installation step and a girder installation step of assembling a circular pillar block on the independent foundation block and installing a girder member on the upper portion of the pillar block to support the upper slab; And

It provides an underground buried prefabricated storage tank construction method comprising an upper slab installation step of installing an upper slab block on the girder member.

As such, the floor slab construction is completed, and the method of inserting the pillar member into the independent foundation block eliminates the need for the work to prevent the fall of the pillar during the construction or the auxiliary work for the pillar mounting. .

In addition, a member such as a dowel bar may be used as the first connection member embedded in the independent foundation block, and the integration effect of the bottom slab and the column is enhanced by the joining of the dowel bar and the bottom slab reinforcing bar.

Here, more preferably, the variable support capacity can be obtained by adjusting the size (diameter and height) of the independent foundation block in accordance with the site conditions (ground conditions), and when installing on soft ground, the groove in the lower foundation block Formed to combine with the top of the pile foundation built in the soft ground can be made easier to construction, thereby reducing the cost of ground improvement if the ground is soft ground.

And, in the assembly between the independent foundation block and the pillar block (preferably circular cross-section pillar), by using the elastic assembly ring in the assembly cross-section to improve the mutual bonding force between the storage tank upper slab and The resistance to buoyancy acting on the upper end of the pillar member can be increased.

As such, when the connection ring is inserted and fixed, shear resistance occurs when the axial force is applied, thereby reducing the thickness of the independent foundation block.

In addition, in using the circular pillar as the pillar block member, the cross section of the upper end portion of the pillar may be enlarged to more stabilize the joining of the pillar and the girder member while ensuring the joint cross section within the range of axial force and buckling. .

In the fastening structure between the girder member and the upper slab block, an insert having an eyebolt is embedded in the girder member, and the joining ends of the two upper slab blocks disposed to face each other on the upper surface of the upper girder member. Providing symmetrical semicircular dome-shaped open grooves, the upper slab blocks of both sides are fitted to create a dome-shaped open groove into which the eye bolts enter, and the shear rod penetrates the inside of the eye bolt in the longitudinal direction. Insertion further improves the integration of the girder member and the two upper slab blocks.

Here, an uneven groove or tuck may be formed in the lower surface of the upper slab block and the upper surface of the girder member to be bonded to each other to provide better resistance to transverse shear forces.

Furthermore, when installing the side wall block, an underground girder which is pre-embedded in the ground is installed at the lower part thereof, and an uneven groove or tuck is formed in the mutual joining surface of the side wall block and the underground girder to make level (horizontal) installation easier. It improves the resistance to the driving earth pressure while preventing floating settlement of the side wall.

The present invention facilitates workability when assembling and facilitates underground storage tanks due to the simplification of prefabricated concrete blocks to allow construction of storage tanks with smooth internal space for the operation of mechanical equipment for maintenance. The construction has the effect of reducing costs.

In addition, the present invention has the effect of preventing the cracking due to leakage and drying shrinkage is large by the strong connection of the precast concrete blocks constituting the prefabricated storage tank to the differential settlement.

In addition, buoyancy may occur in the storage tank upper slab and the vertical member supporting the storage tank when the water level of the storage tank is increased. According to the present invention, buoyancy generated between the base PC plate and the vertical member forming the bottom surface of the storage tank may be prevented. There is an effect to provide a specific means that can be.

In addition, according to the present invention, the precast concrete block member (PC member) is manufactured in advance in the factory, and thus simple assembly is performed at the site, thereby completing the construction of the structure, thereby significantly reducing the construction period than the site casting method, and the ground condition is soft. Even in the ground, it is possible to combine the pile foundation and the independent foundation concisely and firmly, so that the resistance to cracks of the structure due to uneven settlement can be largely secured.

 In addition, each of the precast concrete block members constituting the storage tank according to the present invention is provided with a shear resistance key on each joint surface, and can be very firmly coupled using an eye bolt, a shear ring, a steel wire, and the like. Since all can be joined within the joint surface, there is no connection member exposed to the outside after assembling, thereby providing a beautiful appearance.

In addition, through the role of the girder member installed between the pillar member and the upper slab after the completion of the construction in the future, it is possible to secure a larger storage space and internal work space due to the long span of the pillar member, so maintenance work such as cleaning work It is easy to work on the equipment, and can also build an arbitrary slope of the floor slab, thereby increasing the efficiency of maintenance work such as cleaning work.

1 is a perspective view of an installation state of the underground buried prefabricated storage tank according to the present invention;
Figure 2 is a plan view of the installation state of the underground buried prefabricated storage tank according to the present invention,
FIG. 3A is a cross-sectional view taken along the line a1-a1 of FIG. 2 and FIG. 3B is a cross-sectional view taken along the line a2-a2 of the display of FIG. 2, showing the combined state of the underground girder, the sidewall block, and the upper slab block, and FIG. Is a plan view showing the assembly process of
FIG. 3D is a cross-sectional view taken along line bb of FIG. 2 and illustrates a combined state of the underground girder, the side wall block, the upper girder member, and the upper slab block;
FIG. 4A is a cross-sectional view taken along the line CC of FIG. 2, showing a combined state of the upper girder member and the upper slab block,
Figure 4b is an assembled state perspective view showing a coupling state of the upper girder member and the upper slab block,
4C and 4D are a plan view and a cross-sectional view showing a modified embodiment of the combined state of the upper girder member and the upper slab block shown in FIG. 2, and FIG. 4E is a cross-sectional view of another modified embodiment,
5A, 5B, and 5C are views illustrating a coupling state of the pillar member and the upper girder member;
6A, 6B, 6C, and 6D are diagrams illustrating one preferred embodiment of a combined state of an independent foundation block and a pillar member, and FIG. 7 is a diagram illustrating another embodiment.
FIG. 8 is a view showing an embodiment of a detailed structure of an independent foundation block used in FIGS. 6A to 6D and 7; and
9 is a block diagram illustrating an embodiment of a method invention in accordance with the present invention.

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

1 is a perspective view of an installation state of the underground buried prefabricated storage tank 100 according to the present invention, FIG. 2 is a plan view of an installation state of the underground buried prefabricated storage tank 100 according to the present invention, and FIG. 3A is a1-a1 of FIG. 2. 3B is a cross-sectional view taken along the line a2-a2 of FIG. 2, showing the combined state of the underground girder 12, the side wall block 10, and the upper slab block 50, and FIG. FIG. 3D is a cross-sectional view taken along the line bb of FIG. 2 and shows the combined state of the underground girder 12, the side wall block 10, the upper girder member 40, and the upper slab block 50. FIG. It is sectional drawing.

As shown in the drawings, the underground buried storage tank 100 according to the present invention is provided with a plurality of precast concrete blocks. These blocks allow the bottom, side walls and top of the reservoir 100 to be assembled on site.

These blocks, as illustrated in the figure as a member for installing the side wall of the storage tank 100, the side wall block 10 of the cantilever structure having an L-shape, the ground girders 12 supporting it, the storage tank ( An upper slab 50 for installing an upper portion of the upper portion 100, an upper girder member 40 provided as a horizontal beam for supporting the upper slab 50, and a pillar block for supporting it on the bottom surface. 30 and an independent foundation block 20 are provided.

According to an embodiment of the present invention, the L-shaped precast concrete blocks are formed into a plurality of partitions to be installed in the field of the side wall and the upper slab and the column supporting the upper slab buried in the basement in the field It comprises a side wall block 10, the upper slab block 50, and a pillar block 30,

An independent foundation block 20 is provided as a precast concrete product assembled at the bottom of the pillar block 30 to support the pillar block 30,

The independent foundation block 20 is provided with, for example, a dowel bar 26 as a first connection member 26 having one end embedded and the other extended outward.

A lower end of the L-shaped sidewall block 10 is provided with a second connecting member 14, for example, a dowel bar 14, which is embedded at one end and extends inwardly of the storage tank 100.

Assemble the bottom reinforcing bar assembly 62 at the bottom of the ground between the independent foundation block 20 and the bottom of the L-shaped sidewall block 10 and cast concrete on-site; It is characterized in that the bottom slab of the prefabricated storage tank is provided by being integrated with the first connecting member (26), the second connecting member (14) of the L-shaped sidewall block (10), and the bottom reinforcing bar assembly (62). Provide an underground buried prefabricated storage tank.

In addition, the present invention is a preferred embodiment of the underground buried prefabricated storage tank construction method as shown in Figure 9, the site of the side wall portion and the upper slab and the upper slab and the upper slab of the storage tank 100 buried underground Underground prefabricated storage tank using precast concrete blocks including a plurality of L-shaped sidewall blocks 10, an upper slab block 50, an independent foundation block 20, and a pillar block 30 to be assembled and installed in As a construction method,

A trench and a foundation ground processing step of performing a trench and processing the foundation ground (S100);

Side wall member and independent foundation installation for installing the independent foundation block 20 for installing the L-shaped side wall block 10 constituting the side wall of the storage tank and the column block 30 supporting the upper slab block 50 in the field Step S200;

A floor slab reinforcing and concrete placing step of assembling a floor reinforcing bar assembly 62 at the bottom of the ground between the independent foundation block 20 and the bottom of the L-shaped sidewall block 10 and placing concrete on-site;

Assembling a circular pillar block 30 on the top of the independent foundation block 20, and a pillar installation for installing the upper girder member 40 for supporting the upper slab block 50 on the pillar block 30 And girder installation step (S400); And

It provides an underground buried prefabricated storage tank construction method comprising an upper slab installation step (S500) for installing the upper slab block 50 on the upper girder member (40).

Of course, as shown in Figure 9 for the completion of the storage tank 100, the finishing work and the peripheral cleaning work step (S600); And the backfilling and compacting step (S700) is subsequently performed is the same as the construction method of other general buried storage tank.

In this way, by completing the floor slab construction (in-situ construction) and inserting the pillar block 30 member in the independent foundation block 20, the work for preventing the fall of the pillar during construction or the support for the mounting of the pillar Make the work no longer necessary.

In addition, a member such as a dowel bar 26 may be used as the first connection member 26 embedded in the independent foundation block 20, and the bottom may be formed by joining the dowel bar 26 and the bottom slab reinforcement 62. Integral effect of slab and pillar is enhanced.

In the above-described underground buried prefabricated storage tank and its construction method, more preferably, as shown in FIGS. 6A to 7, the size (diameter and height) of the independent foundation block 20 is adapted to the site conditions (ground conditions). You can also obtain a variable support force by adjusting the), when installing on the soft ground to form a groove in the lower portion of the independent foundation block 20 to combine with the upper end of the pile foundation (P) constructed in the soft ground for easier construction This can reduce the cost of ground improvement if the ground is soft ground.

And, according to the present invention in the assembly between the independent foundation block 20 and the pillar block 30 (preferably circular cross-section column) constituting the underground buried storage tank 100, shown in Figures 6a to 6d As can be seen, by using the elastic assembly ring 90 in the assembly section to improve the mutual bonding force between the buoyancy acting on the upper end of the reservoir upper slab block 50 and the column block 30 member when the water level in the reservoir is increased. Increase resistance to

More specifically, as shown in FIG. 6A, an annular elastic ring insertion groove 24 is provided on an inner side surface of the joining groove 22 formed on the independent foundation block 20, and the circular pillar block ( The outer side surface of the insertion auxiliary steel plate 92 is provided with an elastic ring inner end fixing groove 32 in the bottom outer surface of the bottom 30, for example, a circularly rolled elastic assembly ring 90 of the " C " And then the insertion auxiliary steel sheet 92 and the elastic assembly ring 90 are provided in the annular elastic ring insertion groove provided on the inner side of the joining groove 22 formed on the independent foundation block 20. It is installed adjacent to the 24 to maintain the elastic assembly ring 90 pushed into the elastic ring insertion groove 24, and then fixed to the inner end of the elastic ring on the bottom outer surface as shown in Figure 6b The insertion auxiliary steel sheet 92 is removed while pushing the lower end of the circular column block 30 in which the groove 32 is processed. As shown in FIG. 6C, the inner end of the elastic assembly ring 90 is in the elastic ring inner end fixing groove 32 at the bottom of the circular pillar block 30 and the outer side of the elastic assembly ring 90. The stage is connected to the elastic ring insertion groove 24 of the independent foundation block 20 at the same time, so that the annular elasticity on the inner surface of the joining groove 22 formed on the upper portion of the independent foundation block 20 A ring insertion groove 24 is provided, and an elastic ring inner end fixing groove 32 is provided on the bottom outer surface of the circular pillar block 30, and the elastic ring inner side of the circular pillar block 30 bottom is provided. However, the elastic assembly ring 90 is provided in a state in which the fixing groove 32 and the elastic ring insertion groove 24 of the independent foundation block 20 are simultaneously held to provide the independent foundation block 20 and the pillar block 30. ) The bottom connection is made.

Furthermore, as shown in FIG. 6D, the connection may be completed by filling the mortar M with the surrounding space. As such, when the elastic assembly ring 90 is inserted and fixed, shear resistance may be generated when the axial force is applied, thereby reducing the thickness of the independent foundation block 20.

According to another embodiment of the present invention, it is also possible to adopt a connection structure of a simple structure without using the elastic assembly ring 90 as shown in FIG.

On the other hand, according to the present invention can be provided in the floor slab 60 by the cast-in-place concrete shown in Fig. 6d and 7 in accordance with the site conditions can be provided a constant gradient to provide a structure for easier cleaning work. .

In addition, in using the circular pillar block 30 as the pillar block member, the cross section of the upper end portion of the pillar is enlarged to secure the joint section as much as possible within the axial force and the buckling range, and the pillar and the upper girder member 40 thereon. ) Can be more stabilized.

In addition, according to an exemplary embodiment according to FIG. 8, which shows a detailed structure of the independent foundation block 20 used in FIGS. 6A to 6D and 7, the first connection member 26 is disposed outside the independent foundation block 20. Bending applied to the independent foundation block 20 when the cast-in-place slab 60 is constructed and the circular column block 30 is assembled, as a member provided separately or as a substitute for the dowel bar 26 embedded therein). As a reinforcing member resisting the moment, it is preferable to additionally reinforce the reinforcing bar 28 such as a U-shaped stirrup disposed through the outer and bottom surfaces of the independent foundation block 20, and further, the reinforcing bar 28. By connecting with the bottom slab reinforcement 62 to strengthen the hall reinforcement so that the integration effect of the bottom slab 60 and the independent foundation block 20 can be further promoted by punching shear cracking of the reservoir bottom surface (punching shear) Prevent So.

On the other hand, according to a preferred embodiment of the present invention, a tighter coupling between the upper girder member 40 and the upper end 34 of the pillar block 30 provided as a transverse beam structure supporting the upper slab block 50. To provide a structure, as shown in FIGS. 5A-5C, the connection of steel to the opposite ends of the two upper girder members 40 mounted and connected to the upper end 34 of the circular pillar block 30. Connection aids such as angle plate 42a and bolt and dowel pins 42b are provided for easier connection, and the upper end of the circular pillar block 30 and the bottom surface of the two upper girder members 40. The connection angle plate 44a and the fastener 44b made of steel are also installed on the parts interconnecting the wires so that the fixing is easier, so that the interconnection can be made without the external fastener and the mortar work. It can improve the shear resistance and resistance to torsional forces on the girder.

And in connection with the preferred embodiment of the fastening structure between the upper girder member 40 and the upper slab block 50, cc of the upper girder member 40 and the upper slab block 50 coupling portion in the plan view shown in FIG. As shown in Fig. 4A showing a cross section and Fig. 4B showing this coupling part in a perspective view, an insert 81 having an eye bolt 82 in the upper girder member 40 is used as the fastener 80. As shown in Figs. The joining ends of the two upper slab blocks 50 which are buried and disposed to face each other on the upper surface of the upper girder member 40 are provided with symmetrical semicircular dome-shaped opening grooves 56a, respectively. When the upper slab block 50 is installed to fit, the dome-shaped open groove into which the eye bolt 82 enters is created, and the shear such as a PVC coated steel rod penetrates the inside of the eye bolt 82 in the longitudinal direction. Insert the rod 83 (drawing reference ' Integrating the upper girder member 40 with the two upper slab blocks 50 can be achieved. Of course, as shown in Figure 4a, the mutual bonding surface may be additional finishing treatment by injecting mortar (M).

Here, the lower surface of the upper slab block 50 to be bonded to each other and the upper surface of the upper girder member 40 are formed with interdigitated grooves / jaws 56 and 46 to provide better resistance to lateral shear forces. Can provide.

Meanwhile, as another embodiment of the coupling portion of the upper girder member 40 and the upper slab block 50 in the plan view shown in FIG. 2, the plan view of FIG. 4C and the cross-sectional view of FIG. 4D (C2-C2 cross section of FIG. 4C; The c1-c1 cross-section of 4c is substantially the same as in Fig. 4a, and an additional embodiment may be employed, including an eyebolt 82 and a shear rod 83 embedded in the center of the upper girder member 40. In addition to the above), the insert 81b having the eye bolt 82b installed on the upper surface of the uneven groove / jaw 46 formed on both sides of the upper girder member 40 is additionally embedded as a fastener in two rows. When the dove-shaped open groove 56b is additionally formed on the lower surface of the position spaced apart from the end of the upper slab block 50 and both upper slab blocks 50 are installed to be aligned with each other, the eye bolt 82b is formed. Domed open grooves 56b are created on both sides. , And when passing through the interior of the eye bolt (82b) inserted into the shear bar (83b) in the longitudinal direction is more powerful integrated between the upper girder members 40 and the two upper slab block 50 can be achieved.

On the other hand, as another modified embodiment of the coupling portion of the upper girder member 40 and the upper slab block 50, as shown in the cross-sectional view in Figure 4e, of the two upper slab blocks 50 are mutually bonded The lower surface and the upper surface of the upper girder member 40 are provided with interlocking grooves / jaws 56 and 46 and are symmetrical about the concave-convex grooves / jaw 46 of the upper girder member 40. Two upper slab blocks (50), each of which has an insert (81b) having eye bolts (82b) on both sides of the upper surface, is embedded as two fasteners, and is mounted on the upper surface of the upper girder member (40). The dome-shaped opening groove 56b is provided on the lower surface at a position spaced apart from each other by the mutually opposing joining ends of the joints), and when the upper slab blocks 50 on both sides are installed to be aligned with each other, the eye bolt 82b enters. Opening grooves 56b of each of the two upper slab blocks 50 When the two shear rods 83b are inserted in the longitudinal direction to penetrate through the inside of the eye bolt 82b provided in the upper girder member 40 as a fastener in two rows, the cost reduction effect is achieved. A strong integrated structure between the upper girder member 40 and the two upper slab blocks 50 can be obtained while providing.

3A to 3D, when the sidewall block 10 is installed, an underground girder 12 which is pre-embedded in the ground is installed at the bottom thereof, and the sidewall block 10 and the underground girder are installed. In the mutual joint surface of (12), uneven grooves or tucks (10a, 12a) are formed to make level (horizontal) installation easier, and improve the resistance to coarse earth pressure while preventing floating settlement of the side walls. Here, it is preferable to install sand (sa) between the side wall block 10 and the underground girder 12 to facilitate the level installation.

In addition, in order to install a multi-stage connection of precast concrete block members such as the sidewall block 10, the steel wire insertion hole is formed in the longitudinal direction of the member, and the steel wire 10b penetrating them is fixed at one end and the other end is tensioned with the steel wire. It can be made easier to connect the block members by pulling it with a force.

In addition, with respect to a preferred embodiment of the fastening structure between the side wall block 10 and the upper slab block 50, a1 of the side wall block 10 and the upper slab block 50 coupling portion in the plan view shown in FIG. 3a shows a cross section of a-a1, FIG. 3b shows a cross section of a2-a2, and FIG. 3c shows a cross section of a3-a3, and the lower surface of the upper slab block 50 joined together. And uneven grooves / jaws 10c and 54 are formed on the upper surface of the sidewall block 10 to provide better resistance to lateral shear forces, and further, the eyebolt 72 is provided on the sidewall block 10. One insert 71 is embedded as a fastener 70, and a domed open groove 54a is dug at the end of the upper slab block 50, and the upper slab block 50 is fitted to the upper surface of the side wall block 10. When installed, a groove into which the eye bolt 72 enters is created, and penetrates the inside of the eye bolt 72. An end fixing nut 74a provided to fix an end of the shear rod 73 as shown in more detail in FIG. 3C by inserting and connecting a shear rod 73 such as a PVC coated steel rod in the longitudinal direction. ) And a plurality of shear bars 73 are stepwise drawn out with a drawer using a coupler 74b interconnecting a plurality of shear rods 73 of a length corresponding to the width of the upper slab block 50. The fixed connection may be such that the integration with the side wall block 10 can also be achieved while integrating the plurality of upper slab blocks 50 together.

On the other hand, in the case of the side wall block 10 and the upper girder member 40 and the upper slab block 50 coupling portion shown in the upper side in the plan view shown in FIG. 2 is separate to orthogonal to the direction of extension of the fastener 70 Since there is no necessity to additionally arrange the fastener of, it may have a structure as shown in FIG.

According to a preferred embodiment of the present invention described above, in addition to the effect described with the configuration of the specific embodiment, as shown in Figs. 1 and 2 it is possible to widen the span (H) between the pillar block 30 member The storage space and the maintenance work space can be expanded.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

100: storage tank
10: L-shaped sidewall block
12: underground girder
20: independent foundation block
30: (round) pillar block
40: upper girder member
50: upper slab block
60: (site pour) floor slab

Claims (15)

In the underground buried prefabricated storage tank,
The L-shaped sidewall block 10 and the upper slab block are precast concrete blocks that are divided into a plurality of sections so that the side wall portion and the upper slab of the storage tank 100 buried underground and the pillars supporting the upper slab are assembled in the field. 50, and a circular pillar block 30,
An independent foundation block 20 is provided as a precast concrete product assembled at the bottom of the circular pillar block 30 to support the circular pillar block 30, and
When the water level is increased in the storage tank, the lower end of the independent foundation block 20 and the pillar block 30 so as to increase the resistance to buoyancy acting on the upper end of the reservoir upper slab block 50 and the pillar block 30 members An elastic assembly ring (90) is provided in the assembly cross-section located between the underground buried prefabricated storage tank, characterized in that to improve the bonding force between the independent foundation block 20 and the pillar block (30). According to claim 1, An annular elastic ring insertion groove 24 is provided in the inner surface of the joining groove 22 formed on the upper portion of the independent foundation block 20, the outer end of the circular column block 30 An elastic ring inner end fixing groove 32 is provided on the side, and
In the state in which the elastic assembly ring 90 is simultaneously caught by the elastic ring inner end fixing groove 32 of the circular column block 30 and the independent ring block 24 of the independent foundation block 20 at the same time. The underground buried prefabricated storage tank is provided so that the connection between the independent foundation block 20 and the lower end of the pillar block 30 is made. According to claim 1, The independent foundation block 20 is provided with a first connection member 26, one end is embedded and the other end is extended to the outside,
The lower end of the L-shaped sidewall block 10 is provided with a second connection member 14 having one end embedded therein and the other end extending inwardly of the storage tank 100.
Assemble the bottom reinforcing bar assembly 62 at the bottom of the ground between the independent foundation block 20 and the bottom of the L-shaped sidewall block 10 and cast concrete on-site; It is integrated with the first connecting member 26, the second connecting member 14 of the L-shaped sidewall block 10, and the bottom reinforcing bar assembly 62 to provide the bottom slab 60 of the prefabricated storage tank Underground embedded prefabricated storage tank. 4. The underground buried prefabricated storage tank according to claim 3, wherein a gradient is provided to said floor slab (60) formed by in-situ concrete. 4. The method of claim 3, wherein the reinforcing bar 28 is additionally reinforced through the outer and bottom surfaces of the independent foundation block 20, and the reinforcing bar 28 is connected to the bottom slab reinforcing bar 62. Underground embedded prefabricated storage tank. The method of claim 1 to provide a fastening structure between the upper girder member 40 and the upper end 34 of the pillar block 30, which serves as a transverse beam structure supporting the upper slab block 50. On the opposite ends of the two upper girder members 40 mounted on and connected to the upper end 34 of the pillar block 30, connection aids such as steel connecting angle plate 42a and bolt and dowel pins 42b are provided. Installing a sphere, and installing the connection angle plate 44a and the fastener 44b of steel in the part which interconnects the upper end part of the said pillar block 30 and the bottom surfaces of the two said upper girder members 40 to Underground embedded prefabricated storage tank. The method of claim 1, in order to provide a fastening structure between the upper girder member 40 and the upper slab block 50,
An insert 81 having an eye bolt 82 is buried in the upper surface of the upper girder member 40 as a fastener 80,
The joining ends of the two upper slab blocks 50 disposed to face each other on the upper surface of the upper girder member 40 are provided with semicircular opening grooves 56a each having a symmetrical shape, so that the upper slab blocks on both sides ( 50) is installed to make a circular opening for the eye bolt (82) is created, and
The underground buried type, characterized in that the upper rod member 40 and the two upper slab block 50 to form an integral fastening structure by inserting the shear bar 83 in the longitudinal direction through the eye bolt 82. Prefabricated storage tank. The method according to claim 7, wherein the lower surface of the upper slab block 50 to be bonded to each other and the upper surface of the upper girder member 40 to form interdigitated grooves / jaws (56, 46). Underground prefabricated storage tank. The method of claim 1, in order to provide a fastening structure between the upper girder member 40 and the upper slab block 50,
The lower surface of the two upper slab blocks 50 joined to each other and the upper surface of the upper girder member 40 are provided with interlocking grooves / jaws 56 and 46,
The insert 81b having the eye bolts 82b on each of both upper surfaces symmetrically about the uneven groove / jaw 46 of the upper girder member 40 is embedded as a fastener in two rows, and the upper girder Dome-shaped grooves 54a are provided on the lower surface at a position spaced a predetermined distance from the mutually opposite joining ends of the two upper slab blocks 50 which are placed on the upper surface of the member 40, thereby providing both upper slabs. When the blocks 50 are installed to be aligned with each other, a domed open groove 56b into which the eye bolt 82b enters is generated in each of the two upper slab blocks 50, and
Two upper ends of the eye girder 82b provided as embedded fasteners in the upper girder member 40 are inserted into the upper girder member 40 and two by inserting the two shear bars 83b in the longitudinal direction, respectively. An underground buried prefabricated storage tank, characterized in that to form an integral fastening structure of the upper upper slab block (50). According to claim 1, Underground side girders (12) are provided in the lower portion of the side wall block 10, the underground girders 12, and the mutual joint surface of the side wall block 10 and the underground girders 12, uneven groove or And forming a jaw (10a, 12a) and disposing sand (sa) between the side wall block (10) and the underground girder (12). The method according to any one of claims 1 to 10, in order to provide a fastening structure between the side wall block 10 and the upper slab block 50,
Uneven grooves / jaws 10c and 54 are formed on the lower surface of the upper slab block 50 and the upper surface of the side wall block 10 which are bonded to each other.
An insert 71 having an eye bolt 72 on the upper surface of the side wall block 10 is embedded as a fastener 70, and a domed open groove 54a is dug at an end of the upper slab block 50. Installing the upper slab block 50 to the upper surface of the side wall block 10 to create a groove into which the eye bolt 72 enters, and
Underground embedded prefabricated storage tank, characterized in that the penetrating through the inside of the eye bolt (72) by inserting the shear rod (73) in the longitudinal direction. In the underground buried prefabricated storage tank construction method,
L-shaped sidewall block 10, upper slab block 50, which are divided into a plurality of sections so that the side wall portion of the storage tank 100 buried underground and the upper slab and the pillar supporting the upper slab can be assembled in the field As the underground buried prefabricated storage tank construction method in which precast concrete blocks including the foundation block 20 and the pillar block 30 are used,
A trench and a foundation ground processing step of performing a trench and processing the foundation ground (S100);
Side wall member and independent foundation installation for installing the independent foundation block 20 for installing the L-shaped side wall block 10 constituting the side wall of the storage tank and the column block 30 supporting the upper slab block 50 in the field Step S200;
A floor slab reinforcing and concrete placing step of assembling a floor reinforcing bar assembly 62 at the bottom of the ground between the independent foundation block 20 and the bottom of the L-shaped sidewall block 10 and placing concrete on-site;
Assembling a circular pillar block 30 on the top of the independent foundation block 20, and a pillar installation for installing the upper girder member 40 for supporting the upper slab block 50 on the pillar block 30 And girder installation step (S400); And
And an upper slab installation step (S500) for installing the upper slab block 50 on the upper girder member 40, and
In assembling between the independent foundation block 20 and the pillar block 30 to perform the pillar installation and girder installation step (S400), the storage tank upper slab block 50 and the pillar block when the water level is increased in the storage tank. (30) The independent using the elastic assembly ring 90 in the assembly cross-section located between the independent foundation block 20 and the lower end of the pillar block 30 to increase the resistance to buoyancy acting on the upper end of the member Underground buried prefabricated storage tank construction method characterized in that to improve the bonding strength between the base block (20) and the pillar block (30). The independent foundation block according to claim 12, wherein in performing the sidewall member and the independent foundation installation step (S200) and the bottom slab reinforcing steel assembly and concrete placing step (S300), the integral effect of the floor slab and the pillar is improved. Method of constructing underground buried prefabricated storage tank, characterized in that the first connecting member (26) embedded in the (20) and the bottom slab reinforcement (62) are bonded to each other. The method according to claim 12 or 13,
Providing an annular elastic ring insertion groove 24 in the inner surface of the bonding groove 22 formed on the upper portion of the independent foundation block,
Providing an elastic ring inner end fixing groove 32 on the bottom outer surface of the circular column block 30,
After the elastic assembly ring 90 is installed on the outer surface of the roll-inserted auxiliary steel sheet 92,
The insertion auxiliary steel sheet 92 and the elastic assembly ring 90 are installed adjacent to the annular elastic ring insertion groove 24 provided on the inner side surface of the joining groove 22 formed on the independent foundation block 20. To maintain the state in which the elastic assembly ring 90 is pushed into the elastic ring insertion groove 24,
When the insertion auxiliary steel sheet 92 is removed while pushing the lower end of the circular column block 30 in which the elastic ring inner end fixing groove 32 is processed on the lower outer surface,
The elastic assembly ring 90 is caught in the elastic ring inner end fixing groove 32 and the elastic ring insertion groove 24 of the independent foundation block 20 at the bottom of the circular column block 30 at the same time. Underground buried prefabricated storage tank construction method characterized in that the connection. delete

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