KR101292283B1 - Column structure for water-storage tank and method for constructing thereof - Google Patents

Abstract

PURPOSE: A column structure for a water storage tank and a construction method for the same are provided to facilitate construction of a column structure by applying a multi-stage structure to a large deep water storage tank. CONSTITUTION: A column structure (100) for a water storage tank comprises a column main body, an embedding block (150), and an erector. The column main body comprises a support part (110) supporting the end of a concrete slab (CS) and a column part (120). The embedding block is connected to the bottom of the column main body using the erector. The embedding block is mounted on the bottom of the embedding groove (10) of a concrete floor and fixed by mortar. The erector connects the column part to the embedding block.

Description

Column structure for water-storage tank and method for constructing

The present invention relates to a storage tank pillar structure and a construction method thereof, and more particularly, the construction of the storage tank pillar structure for fixing the upright by embedding the lower end on the concrete floor of the storage tank is made easy, and deep and large The present invention relates to a storage tank pillar structure and a construction method thereof, which enables the construction of a column structure simply by applying a multi-stage structure to a storage tank.

In general, as rainwater is not submerged into the basement during heavy rains due to the increase of buildings and the increase of the pavement rate of the surface, the phenomenon of frequent inflow into the sewer or river occurs frequently during the rainy season.

This is because, due to the recent urban development, various structures such as buildings, asphalt, concrete pavement, parking lot facilities, etc. are rapidly increased, and the rainwater is directly discharged to the river through rainwater pipes, and a large amount of rainwater is concentrated at once.

Thus, if the rainy season exceeds the allowable inflow of rainwater, flooding leads to flooding of roads or houses and buildings by rainwater. On the contrary, when the inflow of rainwater decreases, the water quality of the stream deteriorates. In addition, there is a problem that the ground water is also depleted, the storage tank that can store the rainwater in the basement temporarily to adjust the outflow to the river has been developed and used.

Conventional storage tanks as described above are applied to small and medium-sized facilities, and in recent years, large-scale facilities are required due to the rapid increase in various structures such as buildings, asphalt, concrete pavement, and parking facilities according to urban development. Larger storage tank facilities are being applied.

The conventional storage tank as described above forms a concrete floor forming the bottom of the storage tank by digging soil at a certain depth to a certain area to have a constant volume, chopping the bottom and circumferential surface, and then pouring cement and curing the bottom portion. .

In addition, a concrete side wall forming the side wall of the storage tank is formed along the circumference of the concrete floor, the concrete side wall is a construction method for placing concrete by installing a formwork, or through a construction method for installing and fixing the manufactured side wall block A certain height is formed along the circumference of the concrete floor.

Then, pillar structures are formed at regular intervals in the horizontal and vertical directions on the concrete floor, which is widely formed for large-scale construction, and these pillar structures are usually installed with formwork and arranging reinforcing bars in the formwork to place cement concrete on site. It is formed through the process of curing.

In addition, the conventional columnar construction for a storage tank as described above is a situation in which the pre-fabricated PRECAST CONCRETE PILE is used.

The pillars for constructing the conventional storage tank pillars form a mortar filling space in the lower inner portion of the pillars and the connection hole is formed on the bottom of the pillars so as to communicate with the mortar filling space, one side of the pillars filling the mortar The filling hole and the filling confirmation hole for filling the mortar in the space and confirming the filling are formed in communication with the mortar filling space.

In other words, the PC pillar, which is a pillar structure for a conventional storage tank, allows the connecting muscle protruding from the concrete floor forming the bottom of the storage tank to be inserted into the mortar filling space through the connecting hole, and then the filling hole in the mortar filling space. The mortar is charged through, and whether or not charging is completed is possible when the mortar starts to come out through the charging confirmation hole.

As described above, when mortar starts to come out of the charging confirmation hole, the charging of the mortar is stopped to complete the installation and fixing of the PC pillar.

The pillar pillar for the storage tank according to the prior art as described above has a relatively large weight, it is not easy to insert the connecting muscle protruding from the concrete floor through the connection hole formed in the bottom of the pillar pillar, and thus There was a problem that the installation and fixing work on the concrete floor for the lower part of the PC pillar is not easy.

In other words, the conventional columnar construction for the storage tank has a problem that it is not easy to connect the lower end to the concrete floor of the storage tank.

Furthermore, the conventional columnar construction for the storage tank is to apply a pre-fabricated PC pillar, and to a large deep storage tank of deep depth had to be applied to make a separate PC pillar with a long vertical direction.

However, in the case of such a long length of the pillar, there is a problem that it is difficult to manufacture and transport the machine, as well as the construction that the lower end is fixed to the concrete bottom of the storage tank.

Therefore, it is easy to connect the lower part to the concrete floor of the storage tank, and at the same time, the research and development of the column construction for the storage tank that enables the construction of the multistage structure for the large deep storage tank is possible. It is required.

KR 10-1087645 B1 2011.11.22.

In order to solve the above problems, the present invention has a predetermined length between the column portion and the buried block provided on the lower side of the pillar body by connecting the buried block to expose the standing muscles of the storage tank through the buried blocks and the standing standing roots It is an object of the present invention to provide a pillar construction for a storage tank and a construction method thereof so that construction can be easily performed by connecting the lower end of the pillar construction to the concrete floor so as to be fixed upright.

Another object of the technology according to the present invention is to form another groove in the laminated groove by forming a laminated groove recessed downward with a certain area on the upper surface of the base portion extended to the upper portion of the pillar body with respect to any one of the column construction The buried blocks provided at the bottom of the column construction and the standing roots exposed to a certain length from the top of the landfill block are embedded so that the pillar construction can be easily constructed by applying a multi-stage structure to a large deep storage tank.

The present invention for achieving the above-mentioned objects is as follows. In other words, the pillar construction for the storage tank according to the present invention is part of the bottom portion in the buried groove formed with a predetermined interval in the horizontal and vertical direction of the concrete floor formed by the site-pouring concrete on the floor after the trench to form the bottom of the storage tank. In the storage tank pillar construction to be buried to be fixed upright, the upright fixed to protrude upward from the top surface of the concrete floor in a horizontal and vertical direction with a predetermined interval with respect to the concrete floor is formed in a rectangular pillar with a cross section rectangular And a support portion extending outwardly with respect to a predetermined length of the upper end so that an end of the concrete slab sealing the open upper portion of the storage tank on the upper surface is seated and fixed, and having a predetermined downward downward length from the bottom of the support portion. main body; The pillar body is formed into a square pillar corresponding to the pillar body, and is connected to the pillar portion at a predetermined distance from a lower end of the pillar portion of the pillar body. A buried block which is buried and fixed by filling and curing, and has a predetermined area extending outwardly from the pillar portion; The buried block is embedded by a predetermined length from the top inside each corner of the pillar body so as to be connected to a predetermined distance away from the lower end of the pillar body and exposed to the outside by a predetermined length from the lower end of the pillar body of the pillar body. A standing root which protrudes and is buried in each corner of the buried block by a predetermined length upward from a lower end protruding outside the pillar of the pillar body, and is formed by bending a predetermined length outward from the buried block inside; A first reinforcing bar which surrounds the circumference of the standing roots arranged in a plurality of inside of each corner of the column body and is further embedded in the column body in a plurality of longitudinal directions of the standing roots; And a second reinforcing bar further embedded in the buried block so as to surround a circumference of the standing roots arranged in plural inside each corner of the buried block.

Here, the pillar body may be stacked in multiple stages so that the pillar constructions can be constructed in multiple stages, the pillar rescue of any one of the pillar constructions is recessed downward with a certain area on the upper surface of the support portion of the pillar body to further stack the grooves. Preferably formed.

At this time, the buried groove is recessed downward with a predetermined width along the upper circumference to further form a connection groove, the shear reinforcement embedded in the inside of the concrete floor from the side of the connection groove is formed to protrude a predetermined length, Arranging the connecting bars in a horizontal direction with a lattice shape with respect to the exposed upper region of the standing muscles exposed by a predetermined length from the lower end of the column part to secure the connection of the end of the connecting bar and the end of the shear reinforcement It is preferable that the exposed area of the standing muscles exposed by a predetermined length from the lower end of the pillar and the buried block embedded with the lower end of the standing muscles are buried and fixed by on-site mortar filling and curing on the buried grooves.

On the other hand, in the column structure for the storage tank according to the present invention, it is preferable that the pillar portion of the pillar structure is formed with an uneven surface on which the mountain and valley are repeatedly formed in one direction.

In addition, the pillar portion of the pillar construction may further include a protrusion that protrudes downwardly sharply in the center in the shape of a square pyramid on the bottom surface, wherein the protrusion is an uneven surface on which the peaks and valleys are repeatedly formed from the outer end to the inner tip side Can be formed.

In addition, the pillar portion of the pillar construction may be further provided with a curved protrusion in which the central portion convexly protrudes downward in a hemispherical shape on the bottom surface, the curved protrusion may be formed with a concave-convex surface on which the acid and the valley is repeatedly formed.

In addition, the buried block is preferably formed through the filling hole in the cylindrical shape of the upper and lower beams in the center so that the site mortar is in close contact with the inner center and the buried in the buried groove.

On the other hand, the construction method of the pillar construction for the storage tank according to the present invention for the storage tank for standing up and fixed installation of the pillar construction for the storage tank so that the bottom portion is partially buried in the concrete floor formed by the site-pouring concrete on the floor to form the bottom of the storage tank. In the construction method of the column construction, during the curing of the concrete floor recessed grooves are formed with a predetermined interval in the horizontal and vertical direction, and has a predetermined width along the upper circumference of the buried groove and the upper circumference of the buried groove A buried part forming step of forming a connection groove further recessed to have a stage, and protruding shear reinforcement from a side of the connection groove by a predetermined length; A spacer installation step of arranging spacers at a predetermined interval on the bottom of the buried groove and filling the mortar with a predetermined amount to install the spacers after forming the buried portion; A buried block for seating and fixing the bottom surface of the buried block by the primary filled mortar by allowing the bottom surface of the buried block provided in the lower part of the storage tank pillar construction made on the spacer installed through the spacer installation step to be seated Fixing step; The connecting muscles are arranged in a lattice shape with respect to the horizontal direction on the exposed area of the standing roots exposed from the lower end of the pillar to the upper end of the buried block of the column building secured on the buried groove through the buried block fixing step. Fixing and connecting the central portion of the connecting muscle with the exposed area of the standing muscle, and fixing and connecting the end of the connecting muscle with the end of the shear reinforcing bar projecting on the connecting groove. And the buried groove so that the buried block of the pillar structure seated and fixed on the buried groove and the exposed area of the standing muscle exposed from the top of the buried block to the bottom of the pillar part are embedded after the pillar structure bottom fixing step. And a pillar structure buried fixing step of filling and curing the mortar secondary to the connection groove to fix the lower end portion of the pillar structure in the buried portion.

Here, in the buried block fixing step, the column building bottom fixing step and the column building buried fixing step, the column building buried in the buried groove of the concrete floor is the other one of the laminated groove is further formed in the upper surface of the base portion Applied as a pillar structure, a multi-stage lamination step may be further performed in which the pillar structure is further stacked and fixed on the other pillar structure after the pillar structure buried fixing step.

In this case, the multi-stage stacking step is made of a process of stacking and fixing the pillar structure further on the other pillar structure, the laminated groove is recessed in the upper surface of the support portion on the laminated groove of the other pillar structure Filling mortar primarily through spacers in the bottom surface of the buried block through spacers so that the buried block provided at the lower end of the pillar structure which is not formed and the exposed area of the standing roots exposed from the top of the buried block to the bottom of the column part are inserted. After seating, it is preferable that the second step of filling the step of filling and curing the mortar in the laminated groove formed in the upper surface of the pillar structure is preferably made.

Referring to the effect of the storage tank pillar construction and its construction method according to the present invention.

First, by connecting the buried block with a predetermined length between the column and the buried block provided on the lower side of the column body to expose the standing muscle, the bottom of the column construction to the concrete floor of the storage tank through the buried block and the exposed standing root Construction to fix upright can be made easily.

Second, by forming a laminated groove that is recessed downward with a certain area on the upper surface of the base portion extended to the upper portion of the pillar body for any one of the column construction is provided in the bottom of the other storage tank pillar construction in the laminated groove By laying up the standing roots exposed to a certain length from the top of the landfill block and the landfill block, the column structure can be easily constructed by applying a multi-stage structure to a large deep storage tank.

Figures 1a and 1b is a cross-sectional view and a perspective view showing the storage column pillar construction according to the present invention.
Figure 2 is a cross-sectional view of the state of use showing the state in which the column construction for the storage tank according to the present invention is completed in a single-layer structure.
Figure 3 is a main cross-sectional view showing a construction state for the column bottom of the column construction for the storage tank pillar construction according to the present invention constructed in a single-layer structure.
Figure 4 is a main cross-sectional view showing the construction state for the column top of the column construction for the storage tank pillar construction according to the present invention constructed in a single-layer structure.
5a and 5b is a cross-sectional view and a perspective view showing another embodiment of the storage tank pillar construction according to the present invention.
Figure 6 is a cross-sectional view of the use state showing the completed construction in a multi-stage laminated structure by applying another embodiment of the storage column pillar construction according to the present invention.
7 is a construction flowchart showing the construction method of the storage tank pillar construction according to the present invention.
Figure 8 is a cross-sectional view showing another embodiment of the column bottom in the storage tank pillar construction according to the present invention.
Figure 9 is a cross-sectional view showing another embodiment of the column bottom in the storage tank pillar construction according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the storage tank pillar construction and its construction method according to the present invention.

Figure 1a and 1b is a cross-sectional view and a perspective view showing the storage tank pillar construction according to the present invention.

2 is a cross-sectional view showing a state in which the storage tank pillar construction according to the present invention constructed in a single-layer structure, Figure 3 is a storage tank pillar construction according to the present invention in the lower column of the column construction completed in a single-layer structure Fig. 4 is a main sectional configuration diagram showing the construction state of the construction, and FIG. 4 is a sectional construction diagram showing the construction state of the column construction of the column construction in which the storage tank construction according to the present invention is constructed in a single-layer structure.

5a and 5b is a cross-sectional view and a perspective view showing another embodiment of the storage tank pillar construction according to the present invention, Figure 6 is a multi-stage laminated structure by applying another embodiment of the storage tank pillar construction according to the present invention This is a cross-sectional view of the used state showing the completed state.

7 is a construction flowchart showing a construction method of the storage tank pillar construction according to the present invention.

First, the storage column pillar construction 100 according to a preferred embodiment of the present invention as shown in Figures 1a to 4 is a horizontal of the concrete floor (C1) formed by the site-pour concrete on the floor after the trench to form the bottom of the storage tank And a lower end portion is partially embedded in the buried groove 10 having a predetermined interval in the vertical direction and recessed to a predetermined depth.

The construction of the storage column pillar construction 100 is usually after the trench for forming the storage tank, the concrete floor (C1) by the construction of the site concrete to form the bottom of the storage tank in the space formed through the trench is constructed, formwork or equipment The construction is performed after the side wall of the storage tank using the manufactured block is formed.

In this case, after the construction of the storage tank pillar construction 100, the concrete storage slab (CS) is seated and fixed to the upper surface of the construction of the storage tank pillar construction 100, the construction of the overall storage tank is finished.

On the other hand, the buried groove 10 formed on the concrete floor (C1) to be partially embedded in the bottom portion of the column construction for the storage tank 100 is recessed downward with a predetermined width along the upper periphery so that the connection groove 20 Further formed, shear reinforcing bar 21 embedded in the inner side of the concrete floor (C1) from the connecting groove 20 side is formed to protrude a predetermined length.

That is, the reinforcement of the shear reinforcement 21 for the reinforcement of the floor to the bottom of the trench to form the storage tank before the site of the concrete for forming the concrete floor (C1) forming the bottom of the storage tank is made of a lattice shape The buried groove 10 and the connecting groove 20 are formed such that some of the shear reinforcing bars 21 protrude a predetermined length from the side of the connecting groove 20.

The storage tank pillar construction 100 having the lower end buried through the buried groove 10 and the connection groove 20 as described above largely includes a pillar body 130, a buried block 150, and a standing root 170. .

Here, the pillar body 130 is fixed upright so as to project a predetermined length upward from the upper surface of the concrete floor (C1) in a horizontal and vertical direction with a predetermined interval with respect to the concrete floor (C1).

The pillar body 130 is provided with a support portion 110 for supporting the end of the concrete slab (CS) for sealing the open top of the storage tank on the top, the pillar portion 120 from the bottom of the support portion 110 Is formed to extend a certain length.

In other words, the pillar body 130 is provided with a support 110 that extends outward with respect to a predetermined length of the upper end so that the end of the concrete slab (CS) for sealing the open top of the storage tank on the upper surface is seated and fixed. The pillar portion 120 has a predetermined length downward from the bottom of the supporting portion 110 is made of a configuration that is formed.

Further, the pillar body 130 is formed of a square pillar having a rectangular cross section, and a plurality of standing roots 170 are arranged inside each corner of the square pillar shape, and the first reinforcing bars surrounding the standing roots 170 ( 173 is preferably buried in a plurality more at a predetermined interval in the longitudinal direction of the standing muscles 170.

On the other hand, the buried block 150 is connected to the pillar portion 120 at a predetermined distance from the lower end of the pillar portion 120 of the pillar body 130, that is, the pillar body 130 through the standing root 170 ) Is connected to the lower portion of the pillar (120).

The buried block 150 is the bottom surface is seated on the bottom of the buried groove 10 of the concrete floor (C1) is buried and fixed by the mortar (M2) filling, curing on the buried groove 10 in the field.

Moreover, the buried block 150 as described above is formed in a square pillar corresponding to the pillar body 130 and the standing root 170 is buried by a predetermined length from the bottom to the upper side inside each corner of the square pillar shape, buried It is preferable that the second reinforcing bar 175 is further buried so as to enclose the circumference of the standing root 170.

In addition, the buried block 150 is preferably formed to extend a predetermined area outward than the pillar portion 120 so that the pillar construction 100 can be stably seated on the bottom of the buried groove (10).

On the other hand, the standing root 170 connecting the pillar portion 120 and the buried block 150 so that the buried block 150 is connected to a predetermined distance from the lower end of the pillar portion 120 of the pillar body 130. It is embedded in the pillar body 130 by a predetermined length from the top and protruding to be exposed to the outside by a predetermined length from the lower end of the pillar portion 120 of the pillar body 130.

In other words, the standing root 170 is buried and fixed inside the buried block 150 by a predetermined length from the lower end protruding to the outside of the pillar portion 120 of the pillar body 130 and the pillar portion 120. And the buried block 150 is to be connected.

In addition, the standing root 170 is preferably fixed to be buried in a predetermined length outward from the inside of the buried block 150, so that the fixing length in the buried block 150 is secured.

The standing root 170 is embedded in the upper body and the lower end of the pillar body 130 and the buried block 150 for a certain length, respectively, the embedding of the standing muscle 170 is fixed of the column building 100 This is done in the manufacturing process.

That is, the pillar structure 100 in which the pillar body 130 and the buried block 150 are connected by the standing roots 170 is pre-made by a precast concrete method and transported to a site for the construction of a storage tank. The lower end is embedded and fixed in the buried groove (10).

In other words, the storage tank pillar construction 100 according to the present invention as described above in the exposed upper region of the standing root 170 exposed by a predetermined length from the lower end of the pillar portion 120 of the pillar body 130. The pillar portion 120 of the pillar body 130 is fixed by arranging the connecting rod 30 in the horizontal direction with respect to the end portion of the connecting rod 30 and the end of the shear reinforcing bar 21. The buried block 150, in which the exposed area of the standing muscle 170 and the bottom portion of the standing muscle 170, which are exposed by a predetermined length from the lower end, is buried and fixed by on-site mortar filling and curing on the buried groove 10. This is desirable.

In addition, the connecting rod 30 is preferably the end is connected to the end of the shear reinforcing bar 21 through a welding or connecting string (not shown), etc., at the same time the central portion of the connecting rod 30 is the pillar portion It is preferable that the connection is fixed through welding or a connecting string (not shown) with respect to the upper end of the exposed area of the standing muscles 170 exposed between the 120 and the buried block 150.

In addition, the pillar construction 100 according to the present invention is preferably formed on the bottom surface of the pillar portion 120 is further formed with an uneven surface 121 is formed in the mountain and valley in one direction, the uneven surface 121 By providing the contact with the mortar (M2) is filled on the filling groove 10 can be made tight installation of the pillar construction (100).

In other words, even if bubbles are generated on the surface of the mortar (M2) filled on the buried groove 10, the irregularities formed on the surface of the mortar (M2) and the bottom surface of the pillar portion 120 of the column building (100) Curing of the mortar (M2) can be made in a state in which the surface 121 is in close contact.

In addition, the buried block 150 in the column building 100 is filled with a cylindrical shape of upper and lower light in the center so that the site mortar is in close contact with the outside and the center inside the buried in the buried groove (10). Preferably, the hole 151 is formed through.

As described above, since the filling hole 151 is formed at the center of the buried block 150, the lower end of the pillar building 100 may be more stably embedded in the buried groove 10.

Meanwhile, referring further to FIGS. 5A to 6, the pillar construction 100 ′ according to another embodiment of the present invention may further have a stacked groove 111 in addition to the pillar construction 100 referring to FIGS. 1A to 4 as described above. Since only the difference is formed, the detailed description of the configuration having the same reference numerals will be omitted.

The pillar structure 100 ′ according to another embodiment of the present invention has a predetermined area on the upper surface of the base 110 so that the other pillar structure 100 is stacked and stacked in multiple stages. It is preferable that the laminated groove 111 is further formed.

As the stacked groove 111 is formed as described above, the lower end of the other pillar structure 100 is embedded in the stacked groove 111 so that a multi-stage stacking construction may be performed.

Therefore, when the construction of the enlarged storage tank is required, since the height from the concrete floor C1 that is formed by digging the floor is formed relatively high, in consideration of such height, the plurality of pillar constructs 100 and 100 'are multistage. Lamination can be made.

Of course, when the plurality of pillar structures 100 and 100 ′ are applied to be stacked in a plurality of stages, the laminated grooves 111 may have lower ends of the other pillar structures 100, that is, the buried blocks 150 and standing roots ( After the exposure area of 170) is inserted and seated, the mortar is charged and cured in the field to be buried.

Therefore, the end of the concrete slab (CS) for sealing the open upper portion of the storage tank on the upper surface of the base 110 of the column structure 100 is fixed to be secured over the stack.

On the other hand, with respect to the method in which the storage tank pillar construction (100, 100 ') according to the present invention as described above is laminated in one or multiple stages, that is, one stage or multiple stages, Figure 7 is shown in Figures 1a to 6 Reference will be made together.

First, the construction method of the storage tank pillar construction 100 is upright to hold the pillar construction 100 for the storage tank so that the bottom portion is partially buried in the concrete floor (C1) formed by the site-pouring concrete on the floor to form the bottom of the storage tank. By fixed installation, the buried part forming step (S110), the spacer installation step (S120), the buried block fixing step (S130), the column construction of the lower stage fixing step (S140) and the column construction buried fixing step (S150) in order. .

Here, the buried portion forming step (S110) is recessed to form a recess groove 10 having a predetermined interval in the horizontal and vertical direction during the curing curing of the concrete floor (C1), the upper circumference of the buried groove 10 According to the present invention, the recess groove 20 is further recessed to have a predetermined width and a circumference and a top end of the buried groove 10, and the shear reinforcement 21 protrudes from the side surface of the connection groove 20 by a predetermined length. Is done.

In addition, the spacer installation step (S120) is to proceed after the step of forming the buried portion (S110), the spacer (S) is arranged at a predetermined interval on the bottom of the buried groove 10 and the mortar (M1) is primarily It is preferably made of a step of filling a predetermined amount to install the spacer (S).

And the buried block fixing step (S130) is the bottom surface of the buried block 150 provided on the bottom of the storage tank pillar construction 100 made on the spacer (S) installed through the spacer installation step (S120) It is preferably made of a process of seating and fixing the bottom surface of the buried block 150 by the primary filled mortar (M1) to be seated.

In addition, the step of fixing the column construction lower end (S140) is the buried block from the bottom of the column portion 120 of the column construction 100 is fixed on the buried groove 10 through the buried block fixing step (S120). The connecting muscle 30 is arranged in a lattice shape with respect to the horizontal direction on the exposed area of the standing muscle 170 exposed to the upper end of the 150, so that the central portion of the connecting muscle 30 is exposed to the standing muscle 170. It is preferable that the connection is made by welding to the area, and the end of the connecting rod 30 is preferably made of a process of connecting and fixing by welding with the end of the shear reinforcing bar 21 protruding on the connecting groove (20).

And the pillar structure buried fixing step (S150) is the buried block 150 and the buried block (150) of the pillar structure 100 fixed to the landfill groove 10 after the fixing step (S140) of the column structure bottom 150 mortar (M2) secondary on the buried groove 10 and the connecting groove 20 so that the exposed area of the standing root 170 exposed from the upper end to the lower end of the pillar portion 120 is embedded. Filling and curing is made of a process of fixing the lower end portion of the pillar construction 100 embedded in the buried portion.

On the other hand, the construction method of the column construction for the storage tank as described above (100, 100 ') is to be applied to the construction of small and medium-sized storage tank that the depth of the storage tank is not relatively deep, the storage column pillar construction (100, according to the present invention) 100 ') is applied to any one column construction 100 is applied to a single column structure.

On the other hand, the construction method of the storage tank pillar construction (100, 100 ') to which the storage column construction 100 and the other column construction 100' as described above is applied, that is, a multi-stage pillar stacked in multiple layers When applied to the structure, first, the above-described buried portion forming step (S110), spacer installation step (S120), buried block fixing step (S130), the column construction lower stage fixing step (S140) and the column construction buried fixing step (S150) The pillar construction 100 is buried in the buried groove 10 of the concrete floor (C1) is laminated on the upper surface of the support 110 is formed to extend outwardly with a predetermined length from the top of the pillar portion (120) The groove 111 is applied to another pillar structure 100 ′ which is further recessed.

In this case, after the pillar structure buried fixing step S150 to which the other pillar structure 100 'is applied (S150), the pillar structure 100 is further stacked and fixed on the other pillar structure 100'. It is preferable that S151 is further made.

This multi-stage stacking step (S151) can be applied to the construction of a large storage tank of relatively deep depth of the storage tank.

The multi-stage stacking step (S151) as described above is made of a process in which the pillar construction 100 is further laminated fixed on the other pillar construction (100 '), the other of the pillar construction (100') The buried block 150 and the top of the buried block 150 provided at the lower end of the pillar structure 100 in which the laminated groove 111 is not formed on the upper part of the supporting part 110 on the laminated groove 111. The bottom surface of the buried block 150 is first filled with a mortar (M1) through the spacer (S) so that the exposed area of the standing root 170 exposed from to the lower end of the pillar portion 120 is inserted. Afterwards, a second step of filling and curing the mortar (M2) in the laminated groove 111 formed in the upper surface of the other pillar construction (100 ') is made of a process of finishing.

According to the construction method for the storage tank pillar construction (100, 100 ') and its single-layer column or multi-stage column according to the present invention as described above, the pillar portion 120 and the buried block provided on the lower side of the pillar body 130 By forming a connection between the buried block 150 so as to expose the standing root 170 with a predetermined length between the (150) through the buried block 150 and the exposed standing root 170 in the concrete floor (C1) of the storage tank 100, 100 ') can be easily made by connecting the lower end of the construction to be fixed upright.

Furthermore, the supporting portion is formed by forming a laminated groove 111 recessed downwardly with a predetermined area on an upper surface of the supporting portion 110 formed on the upper portion of the pillar body 130 with respect to the other pillar structure 100 ′. The buried block 150 provided at the bottom of the storage tank pillar construction 100 in which the stack groove 111 is not formed at 110 and the standing root 170 exposed to a predetermined length from the top of the buried block 150 are formed. In the deep storage tank with a deep depth of embedding by applying a multi-stage structure, it is possible to simply stack the column construction (100, 100 ') in multiple stages.

On the other hand, Figure 8 is a cross-sectional view showing another embodiment of the bottom of the pillar portion in the storage tank pillar construction according to the present invention.

FIG. 8 is further provided with a pillar structure 100 as described above with reference to FIGS. 1A to 4, and a protrusion 123 having a central pyramid protruding downwardly in a central pyramid shape on a bottom surface of the pillar portion 120. 123 has a difference only in that the concavo-convex surface 124 is formed on the surface from the outer end to the inner tip side to form a peak and the valley is repeated, a detailed description of the configuration having the same reference numerals will be omitted.

As shown in FIG. 8, the pillar construction 100 further includes the protrusion 123, and at the same time, the bubbles are formed on the surface of the mortar M2 filled on the buried groove 10 by forming the uneven surface 124. Even if it occurs, the surface of the mortar (M2) and the bottom surface of the pillar portion 120 is in close contact with the state that the curing of the mortar (M2) can be made.

As such, as the curing of the mortar (M2) occurs in a state in which the surface of the mortar (M2) and the bottom surface of the pillar portion (120) are closely adhered to each other, more firmly fixed installation of the pillar construction (100) is achieved. Can be done.

Figure 9 is a cross-sectional view showing another embodiment of the bottom of the pillar portion in the storage column pillar construction according to the present invention.

9 is further provided with a curved protrusion 125 at the bottom of the pillar portion 120 and the pillar structure 100 as described above with reference to FIGS. 1A to 4, wherein the curved protrusion 125 has a peak and a valley on the surface thereof. Only having a difference in that the uneven surface 126 is formed repeatedly, a detailed description of the configuration having the same reference numerals will be omitted.

As shown in FIG. 9, the pillar construct 100 is further provided with the curved protrusion 125 and at the same time, the convex and concave surface 126 is formed to bubble the surface of the mortar M2 filled in the buried groove 10. Even if the occurrence of the mortar (M2) can be made in a state in which the surface of the mortar (M2) and the bottom surface of the pillar portion 120 is more closely in close contact.

As such, as the curing of the mortar (M2) is made, a more robust fixed installation of the pillar structure 100 may be achieved.

Of course, the bottom structure of the pillar portion 120 described above with reference to FIGS. 8 and 9 may be applied to the bottom portion structure of the pillar portion 120 in the pillar construction 100 described with reference to FIGS. 5A through 6.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, the invention is not limited thereto. Various modifications may be made by those skilled in the art. Are included in the scope of the present invention.

C1: concrete floor
10: landfill groove 20: connection groove
21: Shear rebar 30: Connecting rod
CS: Concrete Slab
100, 100 ': Column construct
110: base 111: lamination groove
120: pillar part 121, 124, 126: uneven surface
123: protrusion 125: curved protrusion
130: pillar body 150: buried block
151: charging hole 170: standing muscle
173: first rebar 175: second rebar
S: spacer M1, M2: mortar

Claims (10)

The bottom portion is partially embedded in the buried groove 10 formed in a predetermined depth in the horizontal and vertical directions of the concrete floor C1 formed by the site-pouring concrete on the floor after the trench is formed to form the bottom of the storage tank. In the storage tank pillar construction (100, 100 ') to be constructed,
It is formed as a square pillar having a rectangular cross section and is fixed upright so as to protrude upward a predetermined length from the upper surface of the concrete floor (C1) in a horizontal and vertical direction with a predetermined interval with respect to the concrete floor (C1), the storage tank is opened A support 110 is formed to extend outward with respect to a predetermined length of the upper end so that the end of the concrete slab CS sealing the upper part is seated and fixed, and has a predetermined downward downward length from the lower end of the support 110. 120 is a pillar body 130 is extended;
Corrugated with the pillar body 130 is formed in a square pillar and is connected to the pillar portion 120 at a predetermined distance from the lower end of the pillar portion 120 of the pillar body 130, the bottom surface is the concrete floor (C1) A buried block 150 that is seated on the bottom of the buried groove 10 and is buried by on-site mortar filling and curing on the buried groove 10, and has a predetermined area extended outwardly than the pillar part 120;
The buried block 150 is embedded by a predetermined length from the top inside each corner of the pillar body 130 so that the pillar block 130 is connected to a predetermined distance away from the lower end of the pillar portion 120. 130 is projected to be exposed to the outside by a predetermined length from the lower end of the pillar portion 120, the buried block 150 by a predetermined length upward from the bottom protruding to the outside of the pillar portion 120 of the pillar body 130 A buried root (170) fixed to the inside of each corner of the buried, buried in a predetermined length bent outward from the buried block (150);
The first reinforcement is surrounded by a plurality of the standing roots 170 arranged in a plurality of inner corners of the pillar body 130 and further embedded in the pillar body 130 in the longitudinal direction of the standing roots 170 (173); And
And a second reinforcing bar 175 further embedded in the buried block 150 so as to surround a circumference of the standing roots 170 which is arranged in a plurality in each corner of the buried block 150. Reservoir column construction. The method of claim 1,
The pillar construction 100 ′ of any one of the pillar constructions 100 and 100 ′ may be stacked on the support portion of the pillar body 130 so that the pillar constructions 100 and 100 ′ may be stacked and constructed in multiple stages. 110) Storage tank pillar construction characterized in that the recessed downward having a certain area on the upper surface is further formed a laminated groove (111). The method according to claim 1 or 2,
The buried groove 10 is recessed downward with a predetermined width along the upper circumference to further form a connection groove 20, the shear reinforcing bar embedded inside the concrete floor (C1) from the side of the connection groove (20) 21) is formed to protrude a certain length,
The connecting muscle 30 is arranged in a horizontal direction with a lattice shape in a horizontal direction with respect to the exposed upper region of the standing muscle 170 exposed by a predetermined length from the lower end of the pillar part 120 of the pillar body 130. The end of the 30 is fixed to the end of the shear reinforcing bar 21, the exposed area of the standing root 170 and the standing root (170) exposed by a predetermined length from the lower end of the pillar portion 120 of the pillar body 130 ( 170. The pillar block for the storage tank, characterized in that the buried block 150 is embedded in the bottom of the buried mortar filling, curing on the buried groove (10). Storage tank pillar construction (100, upright) fixed installation of the storage tank pillar construction (100, 100 ') so that the bottom portion is partially buried in the concrete floor (C1) formed by the site-pouring concrete on the floor to form the bottom of the storage tank 100 ') construction method,
During the curing of the concrete floor (C1) to form a recess groove 10 having a predetermined interval in the horizontal and longitudinal direction, the buried groove 10 having a predetermined width along the upper circumference of the buried groove 10 Forming a connection groove 20 indented to have a top circumference and an end of the buried part, and forming a buried portion S110 to protrude a predetermined length from the side of the connection groove 20;
After the buried part forming step (S110), the spacer (S) is arranged on the bottom of the buried groove 10 at a predetermined interval and the spacer is installed to install the spacer (S) by filling a predetermined amount of mortar (M1) first Step S120;
The primary filled mortar by allowing the bottom surface of the buried block 150 provided in the lower portion of the storage tank pillar construction 100 prepared on the spacer (S) installed through the spacer installation step (S120) to be seated ( A buried block fixing step (S130) for seating and fixing the bottom of the buried block 150 by M1);
Standing roots exposed from the lower end of the pillar portion 120 of the pillar building 100 fixed to the buried groove 10 through the buried block fixing step (S120) to the upper end of the buried block 150 ( The connecting muscles 30 are arranged in a lattice shape with respect to the horizontal direction on the exposed area of the 170, and the center portion of the connecting muscles 30 is welded and fixed to the exposed areas of the standing muscles 170. A column structure lower end fixing step (S140) of fixing the end of the 30 by welding the connection with the end of the shear reinforcing bar (21) protruding on the connection groove (20); And
After the pillar structure lower end fixing step (S140), the pillar block 120 of the pillar block 120 and the buried block 150 of the pillar block 100 fixed and seated on the buried groove 10 may be formed. The pillar construct 100 may be filled and cured by secondary filling the mortar M2 on the buried groove 10 and the connecting groove 20 so that the exposed area of the standing root 170 exposed to the lower end is buried. Construction method of the pillar construction for the storage tank, characterized in that the lower portion of the buried in the buried part to bury the buried fixed step (S150) made. 5. The method of claim 4,
In the buried block fixing step (S130), the column construction bottom fixing step (S140) and the pillar construction buried fixing step (S150), the column construction 100 is buried on the buried groove 10 of the concrete floor (C1). ) Is applied to another pillar structure 100 ′ formed by further recessing the stacked groove 111 on the upper surface of the base 110 having a predetermined length from the upper end of the pillar part 120. After the buried fixing step (S150) the construction method of the pillar construction for the storage tank further characterized in that the multi-stage stacking step (S151) is further made to stack and fix the pillar structure 100 on top of the other pillar structure (100 '). . The method of claim 5,
The multi-stage stacking step (S151) is made of a process in which the pillar construction 100 is further stacked and fixed on top of the other pillar construction 100 ',
A buried portion provided in the lower end of the pillar structure 100 in which the laminated groove 111 is not formed in the upper surface of the supporting part 110 on the laminated groove 111 of the other pillar structure 100 ′. The bottom surface of the buried block 150 is inserted through the spacer S so that the exposed area of the standing root 170 exposed from the top of the block 150 and the buried block 150 to the bottom of the column 120 is inserted. After filling and seating the mortar (M1) primarily, the process of secondly filling and curing the mortar (M2) in the laminated groove 111 formed in the upper surface of the other pillar construction (100 '). Construction method of the storage tank pillar construction, characterized in that consisting of. The method of claim 1,
The pillar portion 120 of the pillar construction (100, 100 ') is a storage tank pillar structure, characterized in that the bottom surface is formed with an uneven surface 121 is formed in the mountain and valley repeatedly in one direction. The method of claim 1,
The pillar portion 120 of the pillar construction 100 is further provided with a protrusion 123 protruding downwardly sharply in the center in the shape of a square pyramid on the bottom, the protrusion 123 is a mountain from the outer end to the inner tip side on the surface Reservoir pillar construction, characterized in that the irregular surface 124 is formed is repeated bone. The method of claim 1,
The pillar portion 120 of the pillar construction 100 is further provided with a curved protrusion 125 having a hemispherical shape on the bottom and convexly protruding downward from the central portion, wherein the curved protrusion 125 has a peak and a valley formed on the surface. Storage tank pillar construction, characterized in that the uneven surface 126 is formed. The method of claim 1,
The buried block 150 is characterized in that the filling hole 151 is formed through the cylindrical shape of the upper and lower light beams in the center so that the site mortar is in close contact with the inner and the center inside the buried block 150 to be buried in the buried groove 10. Storage column pillar construction.

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