KR101146252B1 - Ankar for distriuting Tensile load - Google Patents

Abstract

The present invention relates to an anchor in which the tensile load is dispersed, and a pedestal in contact with the ground, a lower portion plate coupled to the upper side to the pedestal, and the lower portion is vertically coupled to the primary dispersion plate, the inside is hollow A main pipe, an upper distribution plate formed above the main pipe, a lifting plate coupled vertically to the upper surface of the upper distribution plate, and having a lifting ring hole, and inserted into the main pipe, both ends of which are inserted into the main pipe. Consists of a round bar protruding up and down, and a bushing nut coupled to the bottom of the round bar, the anchor in which the tensile load of the present invention is dispersed, the load is dispersed when tensioning the collecting well, and the position can be adjusted to improve work time and work efficiency. It is possible to reduce the cost according to the conventional field production, and there is an advantage that the precise construction of the indentation of the sump well is possible.
In addition, cracking and damage of the footing concrete is prevented, so safety accidents do not occur, and work satisfaction is increased, thereby increasing the amount of work.

Description

Ankar for distriuting Tensile load

The present invention relates to an anchor in which the tensile load is dispersed, and a plurality of distribution plates are installed in the anchor so that the tensile load is distributed in installing the anchor for indenting the water collecting well, and the tension adjusting width of the anchor is formed. Anchors in which the load is distributed.

In general, a water collecting well (open casing) means a facility for supplying groundwater by installing in a river delta or around the river for use in industrial water.

The water collecting well is formed with a cylindrical or oval concrete wall surface underground, and then presses into the underground one by one to install the target depth of the underground to complete the water collecting facility or to install the foundation open casing for the bridge.

Conventionally, the sump concrete structure is shaken or tensioned using a crane or an excavation bucket equipment, and when natural settlement does not occur, divers are put into the depth of the sump concrete structure to prevent visibility from turbid water. Due to the sixth sense of a diver, explosives are installed under the kerbush, or the manual work is carried out under the slanted opposite blade tip rigid body (kerbush).

As a result, work delays and precision construction accidents have occurred, and there have been cases in which the sump is closed due to cracks and breakages of the concrete.

In addition, due to the fact that the sump concrete structure is not settled precisely, the surrounding plumbing equipment is not constructed according to the original drawing, and thus, the design changes are enormous, which entails the enormous loss of replacing or repairing the surrounding plumbing equipment. It is.

This is the case arises from the problem of the divers installing the catchment well.

Therefore, the method of press-fitting the sump using a press-fit device 120 such as a hydraulic cylinder is not used, but the anchor installed there is a problem that can not distribute the tensile load. For this reason, there was a problem of cracking and cracking of the putting concrete poured during anchor installation.

In addition, since the width is not adjusted when the sump is press-fitted, as described above, the divers directly adjust the position of the sump.

The present invention has been made in order to solve the above problems, the tensile load is dispersed when the water collecting well indented by the indentation device 120, when providing a anchor in which the tension load is freely adjustable width when the water collecting well indentation have.

The present invention for achieving the above object is an anchor installed to install the sump, the pedestal in contact with the ground, the lower partial plate coupled to the upper side to the pedestal, and perpendicular to the primary dispersion plate The main pipe is coupled to the lower communication, the hollow inside, the upper distribution plate formed on the upper side of the main pipe, the upper plate is vertically coupled to the upper surface of the distribution plate, the lifting plate formed with a lifting ring hole, and the main Is inserted into the tube, the end portion is characterized in that consisting of a round bar protruding up and down the main tube, and a bushing nut coupled to the round bar lower side.

In addition, between the lower partial dispersion plate and the upper dispersion plate is characterized in that a plurality of tensile dispersion plate is installed on the outer circumference of the main tube is further formed.

In addition, between the lower dispersion plate and the tensile dispersion plate and the upper dispersion plate is characterized in that the dispersion reinforcing plate is further formed to connect each other.

In addition, the pedestal, characterized in that the H beam is made of a pair, spaced apart by a predetermined interval.

In addition, the lower portion between the plate and the pedestal, characterized in that the width adjustment portion larger than the diameter of the main tube to further adjust the width of the round bar.

In addition, the upper dispersion plate is characterized in that the cross-section reinforcing nut is further provided to reinforce the cross section.

In addition, the step of leveling the ground, and digging soil in the horizontal ground to form a seating step of the water collecting well space forming step and the step of producing a formwork larger than the outer diameter of the water collecting well in the excavated soil, Collecting basic work process comprising the step of installing an anchor to distribute the tensile load for indenting, the step of reinforcing the reinforcing bar at the top, bottom, and bolting the plurality of curve shoe units to form a cylindrical curve shoe And bolting the curved shoe to the top of the curve shoe, bolting a plurality of upper connecting foam units to form a cylindrical upper connecting foam, and forming a cylindrical band formwork on the upper connecting foam. After forming, the step of pouring concrete for forming the wall surface, the water collecting well installation step consisting of dismantling the upper connecting form, and the house Using a press-ready water collection classes, the press-fitting apparatus for installing the press-in device for pushing the information to the anchor and the sump, wherein the sump comprises a step of press-fitting the press surface to the lower side.

As described above, the anchor in which the tensile load of the present invention is dispersed, the load is distributed when the water collecting well is tensioned, and the position can be adjusted to improve working time and working efficiency, and according to the conventional field production cost There is an advantage in that it is possible to reduce the cost and precise construction of the indentation of the sump well.

In addition, cracking and damage of the footing concrete is prevented, so safety accidents do not occur, and work satisfaction is increased, thereby increasing the amount of work.

1 is a perspective view illustrating an anchor in which a tensile load is distributed according to an embodiment of the present invention.
2 is another perspective view showing an anchor in which a tensile load is distributed according to an embodiment of the present invention.
3 is a perspective view illustrating a pedestal according to an embodiment of the present invention.
4 is a partial perspective view showing the lower portion of the anchor in which the tensile load is distributed according to an embodiment of the present invention.
5 is a partial perspective view showing the upper portion of the anchor in which the tensile load is distributed according to the embodiment of the present invention.
6 is an exemplary view showing an anchor in which a tensile load is dispersed according to an embodiment of the present invention.
7 is a block diagram for installing the water collecting well using the anchor in which the tensile load is distributed according to the embodiment of the present invention.
8 is an embodiment of the installation of the water collecting well using the anchor in which the tensile load is distributed according to an embodiment of the present invention.

Hereinafter, an anchor in which the tensile load is dispersed will be described with reference to the accompanying drawings.

1 is a perspective view illustrating an anchor in which a tensile load is distributed according to an embodiment of the present invention.

2 is another perspective view showing an anchor in which a tensile load is distributed according to an embodiment of the present invention.

3 is a perspective view illustrating a pedestal according to an embodiment of the present invention.

4 is a partial perspective view showing the lower portion of the anchor in which the tensile load is distributed according to an embodiment of the present invention.

5 is a partial perspective view showing the upper portion of the anchor in which the tensile load is distributed according to the embodiment of the present invention.

6 is an exemplary view showing an anchor in which a tensile load is dispersed according to an embodiment of the present invention.

7 is a block diagram for installing the water collecting well using the anchor in which the tensile load is distributed according to the embodiment of the present invention.

8 is an embodiment of the installation of the water collecting well using the anchor in which the tensile load is distributed according to an embodiment of the present invention.

As shown in Figures 1 to 6, the present invention is a pedestal 10 which is in contact with the ground with an anchor 1 in which the tensile load for installing the sump 110 is distributed, and the upper side to the pedestal 10 Lower part 20 coupled to the lower part, the lower part is coupled to the lower plate 20 in vertical communication, the main tube 30 is hollow inside, and the upper part formed on the main tube 30 The distribution plate 40 is vertically coupled to the upper surface of the upper dispersion plate 40, the lifting plate 50 having the lifting ring hole 52 formed therein, and inserted into the main tube 30. The main pipe 30 is composed of a round bar 60 protruding up and down, and a bushing nut 76 coupled to the lower side of the round bar 60.

Hereinafter, each configuration will be described in detail.

Pedestal 10 according to the present invention is a part in contact with the ground, the concrete is poured to support the main pipe (30). Therefore, it is better to use a reinforcing material having strong strength and hardness.

Preferably, the pedestal 10 is composed of a pair of H beams (12, 14) spaced apart by a predetermined interval. This is to improve the bearing capacity by increasing the area in which the pedestal 10 is in contact with the ground.

Preferably, the pedestal 10 is further provided on both sides of the pedestal 10, the reinforcing bar 16. This is because the pedestal 10 is made of a pair of H beams 12, 14 in the longitudinal direction, and further provided with a reinforcing bar 16 in a direction perpendicular thereto, so that the force can be distributed in the forward direction.

The lower partial plate 20 according to the present invention is coupled to the upper surface of the pedestal 10, and is a plate in which load is first distributed when a tensile load is generated. Therefore, a material having strong strength and strong shock absorption is formed in the center of the pedestal 10.

In addition, the lower portion plate 20 is opened in the center is in communication with the opened interior of the main tube (30). This is to allow the round bar 60 to protrude into the lower plate 20.

On the other hand, the lower partial plate 20 is coupled by welding when coupled to the pedestal 10, the welding method described later also used welding.

And, the lower partial plate 20 is made of a circular plate shape, it is preferable that the load distribution is made equal in the center of the circle.

The main pipe 30 according to the present invention is coupled to communicate with the opened portion of the lower plate 20 through the pipe through the inside, the rod 60 is inserted into the inside.

The diameter of the main tube 30 is manufactured so that the round bar 60 can move. However, the length and the inner diameter of the main tube 30 can be variously manufactured according to those skilled in the art.

The upper distribution plate 40 according to the present invention is formed of the same material and shape as the lower partial dispersion plate 20 and is formed on the main tube 30.

This is for imparting load distribution by transferring the tensile load generated when the water collecting well is press-fitted to the upper dispersion plate 40 simultaneously with the lower partial dispersion plate 20.

The lifting plate 50 according to the present invention has a rectangular plate shape, the lifting ring hole 52 is formed and is vertically coupled to the upper surface of the upper distribution plate 40. The lifting ring hole 52 is a hole formed to mutually connect to the lifting ring hole 52 of the anchor installed in the other direction.

Round bar (60) according to the present invention is longer than the length of the main pipe 30 as a portion of the thread is coupled to the outer circumference. Therefore, when the round bar 60 is inserted into the main tube 30, both sides protrude upward and downward of the main tube 30.

The upper side of the round bar 60 is coupled to the push rod 92 and the nut 94 is connected to the indentation device 120.

Bushing nut 76 according to the present invention is coupled to the lower side of the round bar 60, to prevent the round bar 60 from falling to the upper side of the main pipe (30).

Preferably, a plurality of tension distribution plates 70 installed on the outer circumference of the main pipe 30 may be further formed between the lower partial dispersion plate 20 and the upper dispersion plate 40. This can prevent the cracking of the footing concrete by distributing the tensile load generated when the water collecting well is press-fitted into the tensile dispersion plate 70 formed in plural in addition to the lower partial dispersion plate 20 and the upper dispersion plate 40. Will be.

In addition, it is obvious that the tensile dispersion plate 70 has the same material and shape as the lower partial dispersion plate 20 or the upper dispersion plate 40.

Preferably, a dispersion reinforcing plate 32 is further formed between the lower partial dispersion plate 20, the tensile dispersion plate 70, and the upper dispersion plate 40.

When the tensile load is concentrated in the lower partial dispersion plate 20, the tensile dispersion plate 70 and the upper dispersion plate 40, the lower partial dispersion plate 20 and the tensile dispersion plate 70 made of a circular shape and Deformation of the upper dispersion plate 40 is generated.

Therefore, between the lower partial dispersion plate 20, the tensile dispersion plate 70 and the upper dispersion plate 40 is further formed between the dispersion reinforcing plate 32 is connected to each other to suppress the occurrence of deformation, Can be.

Preferably, between the lower portion 20 and the pedestal 10, the width adjusting portion 80 larger than the diameter of the main pipe 30 is further provided to adjust the width of the round bar (60). It is good to be.

The position of the round bar 60 is adjusted through the width adjusting portion 80. This is to move the round bar 60 in a predetermined direction when the position of the catchment well is shifted from the design drawing, and to move the press fitting device 120 to press-fit the catchment well.

The width adjusting part 80 allows one side to move the round bar 60 to an open space.

In other words. As the tolerance of the round bar 60 and the main tube 30 can move the round bar 60 inside the main tube 30, the back and forth the press-fit device 120 coupled to the round bar 60 up to 10mm ~ 120mm You can move from side to side. This makes it possible to adjust the position even if the position of the collecting well is shifted.

Preferably, the upper dispersion plate 40 is preferably further provided with a cross-section reinforcing nut to reinforce the cross section.

This, because the upper distribution plate 40 is formed with a lifting plate 50 on the upper surface, the deformation due to the lifting plate 50 as well as the tensile load is generated. The cross-sectional reinforcing nut is formed inside the lifting plate 50 to effectively support the upper dispersion plate 40.

In summary, when the tension is generated in the round bar 60 and the main pipe 30 by the pressure of the indentation device 120 for press-fitting the collection well when the collection well is installed, the lower tension plate 20 and Multiple dispersion is made to the tensile dispersion plate 70 and the upper dispersion plate 40.

That is, by dispersing the tensile pressure into the lower partial dispersion plate 20, the upper dispersion plate 40 and the tensile dispersion plate 70, it was possible to disperse that the tension pressure acts only on the lower side.

Accordingly, the footing concrete formed on the outer periphery of the pedestal 10 is distributed in multiples to prevent cracking and damage of the footing concrete, and to prevent separation of the press-fit device 120 fastened to the round bar 60.

In detail, after pouring footing concrete, the sedimentation occurs under the footing concrete because the internal soil is scooped out by the excavation bucket equipment inside the sump concrete structure. Since the main pipe 30 receives the up and down repeated load by the indentation apparatus 120, the footing 10 is pulled out as the footing concrete is cracked and broken in the pedestal 10, and is separated from the indentation apparatus 120. Will occur.

Next, the process of installing the water collecting well using the present invention will be described briefly.

As shown in FIG. 7, the process of installing the water collecting well is largely composed of five steps. It consists of a collecting well space forming process, a collecting well basic work process, a collecting well installation process, a collecting well press-in preparation process and a collecting well press-in process.

First, the water collecting well space forming process is to level the ground on which the water collecting well is to be installed, and excavate the soil in the horizontal ground to form a seating portion to be seated.

And, the base of the water collecting well is to produce a formwork larger than the outer diameter of the water collecting well in the space excavated, and install an anchor (1) in which the tensile load for indenting the water collecting well is dispersed. Here, footing concrete is poured around the pedestal 10.

Next, the collecting well installation process is to install the collecting well 110 in the mounting portion. Briefly describing the process of installing the water collecting well, the step of reinforcing the reinforcing bar at the top, bottom, bolt coupling a plurality of curve shoe units to form a cylindrical curve shoe, and the curve shoe on the top of the curve shoe And bolted to each other, bolting a plurality of upper connecting foam units to form a cylindrical upper connecting foam, and after forming a cylindrical band formwork on the upper connecting foam, pouring concrete for wall formation. And dismantling the upper connection form.

In addition, in the catchment press-fitting preparation process, the pressurizing rod 92 is installed in the press-fitting apparatus 120 for press-fitting the catchment well by coupling the press-fit rod 92 to the annular rod 60 of the anchor in which the tensile load is dispersed. Be sure to

In addition, in the water collecting well press-in process, the water collecting well is press-fitted to the lower side of the ground using the press fitting device 120.

As a result, a tensile load is generated in the anchor in which the tensile load is dispersed, so that the load is distributed to the lower partial dispersion plate 20, the upper dispersion plate 40, and the tensile dispersion plate 70, thereby causing cracks in the footing concrete. Cracking will be prevented.

As described above, it is a basic technical idea to form a dispersion plate for dispersing the tensile load on the outer periphery of the anchor installed to press-in the sump well with the press-fitting device, which is merely exemplary, and has a general knowledge in the art. Those skilled in the art will understand that various modifications and equivalent embodiments are possible from this, and the true technical protection scope of the present invention should be defined only in the appended claims.

10: pedestal
20: bottom mount
30: main tube
40: upper dispersion plate
50: salvage plate
52: salvage ring hall
60: round bar
76: bushing nut

Claims (7)

In anchor installed to install collecting well,
A pedestal 10 in contact with the ground;
A lower partial plate 20 coupled to the pedestal 10 at an upper side thereof;
A main tube 30 having a lower portion communicating vertically with the lower plate 20 and having a hollow inside thereof;
An upper dispersion plate 40 formed above the main pipe 30;
A lifting plate 50 coupled vertically to the upper surface of the upper dispersion plate 40 and having a lifting ring hole 52 formed therein;
An annular rod 60 inserted into the main tube 30 and protruding both ends of the main tube 30 up and down;
An anchor in which the tensile load is dispersed, characterized in that the bushing nut (76) coupled to the lower side of the round bar (60). The method of claim 1,
Between the lower partial dispersion plate 20 and the upper dispersion plate 40,
Anchors in which the tensile load is dispersed, characterized in that the main pipe 30 is further provided with a plurality of tension distribution plate 70 is installed on the outer periphery. The method of claim 2,
An anchor to which the tensile load is dispersed, characterized in that the lower portion of the dispersion plate 20, the tensile dispersion plate 70 and the upper dispersion plate 40 is further distributed dispersion reinforcing plate 32 is connected to each other. The method of claim 1,
The pedestal 10,
Anchors in which the tensile load is dispersed, characterized in that the H beams (12, 14) are made in pairs and spaced at regular intervals. The method of claim 4, wherein
Between the lower partial plate 20 and the pedestal 10,
Anchor to which the tensile load is dispersed, characterized in that the width adjustment portion 80 is further provided larger than the diameter of the main pipe (30) to adjust the width of the round bar (60). The method of claim 1,
Upper dispersion plate 40,
An anchor in which the tensile load is dispersed, characterized in that the cross-section reinforcing nut is further provided to reinforce the cross section. In the method of installing a water collecting well using an anchor in which the tensile load of any one of claims 1 to 6 is dispersed,
A water collecting well space forming process comprising the steps of leveling the ground and digging soil in the horizontal ground to form a seating portion;
A water collecting well foundation work process comprising: manufacturing a formwork larger than an outer diameter of a water collecting well in a space dug up soil, and installing an anchor in which a tensile load for injecting the water collecting well is distributed;
Reinforcing the reinforcing bar at the top, bottom, bolt coupling the plurality of curve shoe units to form a cylindrical curve shoe, and bolted to the curve shoe on the top of the curve shoe, a plurality of upper connecting foam unit Forming a cylindrical upper connection form by bolting, forming a cylindrical band formwork on top of the upper connection form, pouring the concrete for wall formation, and dismantling the upper connection form. A collecting well installation step of installing the collecting well 110 formed in the seating part;
A water collecting well press-preparation step of installing a press-fitting device (120) for press-fitting the water collecting well into the anchor;
An anchor in which the tensile load is dispersed, comprising: a water collecting well pressurizing process of press-fitting the water collecting well to the lower side of the ground using the press-fitting device (120).

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