KR101242745B1 - Protection cap - Google Patents

Abstract

PURPOSE: A protective cap for an underground anchor with an improved structure is provided to be used for from anchorages with minimum standard tension to anchorages with maximum standard tension through post processing of a female screw unit of a variable process unit. CONSTITUTION: A protective cap(10) for an underground anchor with an improved structure is formed in the inside space(11) of which one side is open, is formed in the outer surface of one end, comprises a flange portion(13) with a plurality of fastening hole(12); a variable process unit(14) which is integrated or separately formed in the internal space; and a female screw unit(15) which is formed in the inner surface of the variable process unit.

Description

Protection cap for underground anchors with improved structure {Protection cap}

The present invention relates to an underground anchor comprising an earth anchor or a lock anchor, and more particularly, a protective cap mounted to protect the re-tensioning anchorage of the underground anchor and the distal end of the wedge and the PC prestressed concrete strand. By improving the structure, the protection cap for underground anchors can be used to cope with the size of re-tensioning fixtures of various sizes by using the protection cap of a single size, and to reduce the mold cost and facilitate the material management and supply. It is about.

Underground anchors are generally classified into earth anchors and rock anchors. In the case of the above-mentioned earth anchors, the purpose of the prestress of the earth wall is to be used at the construction site of the underground structure. It is mainly constructed in a temporary form, the above-mentioned lock anchor is installed in a permanent form on the slope of the roadside, such as a cut slope or fill slope.

In this case, the earth anchor and the rock anchor as described above are generally inserted into the PC strand (101 (PC steel wire, if necessary)) into the perforated part in the state of performing the underground drilling work as shown in FIG. It is fixed to the end of the perforations, and cement cement grout to fix the PC strand (101).

Subsequently, a bearing plate 102 and an anchor head 103 are coupled to the PC strand exposed to the outside, and then the PC strand 101 is tensioned by a tensioner to apply a predetermined compressive stress. As the wedge (Wedge; 104) surrounding the PC strand 101 in one state is inserted into the wedge formed in the retensioning anchorage 103, the fixed installation of the underground anchor is completed.

In addition, as necessary, to protect the distal ends of the re-tensioning anchor 103 and the PC strand 101 by combining a separate protection cap 105 to the outside of the re-tensioning anchor 103 as described above. Of course, the grease is injected into the protection cap through the nipple formed in the protection cap 105 to prevent corrosion of the re-tensioning anchor 103 and the PC strand 101 and the wedge 104. do.

The protective cap 105 as described above is mainly used for lock anchors that are intended for long-term permanent installation, rather than temporary cladding walls, and the lock anchors are weakened in PC strands as they are installed on cut slopes or fill slopes on roadsides. In this case, re-tensioning should be performed to ensure that the proper compressive stress is applied.

That is, in the case of the cut slope or the fill slope as described above, it is to provide a continuous and permanent compressive stress through the underground anchor. When the compressive stress is weakened due to the relaxation of the PC strand to the underground anchor providing the condensation stress, It is necessary to apply the designed compressive stress through retensioning the PC strand.

Accordingly, in order to adjust the retension of the PC strand as described above, after removing and removing the protective cap as described above, a tension force is applied to the PC strand through the tensioner by combining the tensioner with the retensioning anchorage.

That is, the jig of the tensioner separately provided in the re-tensioning anchorage 103 exposed to the outside in the state of removing and removing the protective cap 105 as described above is combined. Subsequently, when the tensioner as described above is pulled to pull the re-tensioning anchor 103, the wedge 104 of the re-tensioning anchor 103 is together with the re-tensioning anchor 103 while holding the PC strand 101 strongly. Because of the flow, the PC strand 101 is given a tensile force of a magnitude proportional to the working amount of the tensioner.

In addition, the re-tensioning anchorage 103 is to be spaced apart from the bearing plate 102 in the state that the desired tensile force is applied to the PC strand 101 as described above, the re-tensioning anchorage 103 And inserting fittings such as iron plates for filling gaps between the bearing plate 102 and stopping the operation of the tensioning machine in the state of inserting the above fittings and removing the tensioning jig from the retensioning fixing unit 103. After removing and fixing the protective cap 105 again, the retension adjustment work for the PC strand is completed.

As described above, the protective cap 105 prevents corrosion of the wedge and the PC strand 101 in the re-tensioning anchorage 103 and the re-tensioning anchorage 103 accommodated therein by corrosion of rain or moisture. , Which serves to prevent contamination by earth and sand from the outside, and by injecting grease into the inner space through the nipple formed in the protective cap 105, the underground can be more effectively solved. It is a necessary component in anchor.

However, the above-mentioned underground anchor protection cap has to have different outer diameters according to the size of the retensioning anchorage having the multi-cone wedge balls. There is a problem that must be supplied.

That is, the above-mentioned underground anchors are constructed with various lengths and sizes according to the geology, soil layer, rock layer, and soil pressure of the site, and a single individual PC strand may be used, but usually 3 to 12 PC strands Will be used.

Accordingly, since three to twelve PC strands are used as described above, a multi-cone-type retensioning anchorage having a corresponding number of wedge holes will be used. Depending on the number of people will have a different outer diameter.

Therefore, when the outer diameter of the re-tensioning anchorage is small, a small protective cap is used, and when a large number of wedge holes are formed in the re-tensioning anchorage, the large-diameter protective cap must be used. As the outer diameter of the protective cap is to be used, each mold must be provided to produce protective caps of different sizes.

In addition, the protective cap as described above is usually produced in the form of castings using cast iron or aluminum, so all the casting molds of different sizes must be manufactured, so that the initial mold investment cost is enormous, as well as the respective protective caps produced from these casting molds. Since they have to be applied differently according to the site situation or the size of the underground anchor, there are frequent cases of confusion at the site as well as material management and supply and demand.

The present invention is to solve the problems as described above, provided with a protective cap having a flange portion and one side open type inner space and the insertion hole penetrating the inner space to be fixed to the bearing plate, the inner space Forming a variable machining portion of the inward protrusion and the female screw portion formed inside the variable machining portion,

The present invention provides a protective cap for underground anchors having an improved structure of a feature that allows the use of both a retensioning anchorage of the minimum specification and a retensioning anchorage of the maximum specification through a post-processing operation of the female screw portion for the variable processing portion. There is a purpose.

The present invention for achieving the object as described above, in the protective cap for underground anchors having an inner space of one side, protruding to form a flange portion having a fastening hole on the outer side of the open side of the protective cap, An inner space is provided with a variable machining portion protruding inwardly, and an internal thread is formed on an inner surface of the variable processing portion.

According to the present invention, it is possible to manufacture a protective cap that exactly matches the outer diameter of a retension anchorage in which at least three to twelve PC strands are coupled and fixed by cutting the inside of the protective cap of a single object to form a female screw portion. It is very economical to save mold and manufacturing cost because female thread parts of various inner diameters can be used for the protection cap made through a single casting mold or molding mold, and it is very economical. Alternatively, according to the size of the underground anchor, the protective cap of the corresponding size can be manufactured and supplied immediately by female threading, which provides a very advantageous effect in terms of handling, managing and supplying materials.

1 is an overall view showing a construction state for the existing underground anchor
2 is an overall perspective view of a protective cap for underground anchors according to the present invention
Figure 3 is an overall cross-sectional view of the protective cap for underground anchors according to the present invention
Figure 4 is a variable cross-sectional view of the protective cap for underground anchors according to the present invention
Figure 5 is a cross-sectional view of the installed state of the protective cap for underground anchor according to the present invention
Figure 6 is an oil nipple coupling cross section of the protective cap for underground anchors according to the present invention
7 is an enlarged operation view of the oil nipple according to FIG.
8 is a perspective view showing another embodiment of the protective cap for underground anchors according to the present invention
9 is an overall cross-sectional view of the protective cap according to FIG. 8.
FIG. 10 is a cross-sectional view of a separation of a protective cap in the underground anchor according to FIG. 8. FIG.
11 is a perspective view showing another embodiment of the protection cap for underground anchors according to the present invention
12 is an overall cross-sectional view of the protective cap according to FIG. 11.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

In addition, the necessary components of the existing underground anchor for the sake of understanding in the detailed description for carrying out the present invention will be used the same reference numerals in the background except for the protective cap in the present invention.

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

Figure 2 is an overall perspective view of the protective cap for underground anchors according to the present invention, Figure 3 is a full sectional view of the protective cap for underground anchors according to the present invention, Figure 4 is a variable cross-sectional view of the protective cap for underground anchors according to the present invention. .

As shown, the protective cap 10 for underground anchors according to the present invention forms an inner space 11 having one side open, and a plurality of fastening holes 12 at one open side of the outer surface of the protective cap 10 as described above. ) Is formed flange portion 13 is formed in the inner space 11, the variable machining portion 14 of the integral or separate form protrudes inwardly, the inner surface of the variable machining portion 14 female thread ( 15) is formed.

Here, the inner space 11 corresponds to a space for accommodating the re-tensioning anchor 103 and the wedge 104 and the distal end portion of the PC strand 101 located on the bearing plate 102, the plan Branch portion 13 is to be fixed in close contact with the bearing plate 102, the fastening hole 12 formed in the flange portion 13 is a protective cap 10 to the bearing plate 102 by using a fastening bolt or the like It is intended to be firmly fixed.

In addition, the variable machining portion 14 is formed by inserting an integral or separate component having a sufficient thickness from the inner surface of the protective cap 10 to the inside, the inner diameter by the variable machining portion 14 is the minimum outer diameter of the material The inner diameter of the protective cap 10 should be formed with a smaller inner diameter than the long anchorage 103, and the inner diameter of the protective cap 10 should be formed with an inner diameter larger than that of the retension anchorage 103 having the maximum outer diameter.

Here, the re-tensioning anchorage 103 having the minimum outer diameter refers to the re-tensioning anchorage 103 having an outer diameter to which three PC strands, which are the smallest objects, in the re-tensioning anchorage of the multi-cone type may be combined. The outer tension re-tensioning fixture 103 refers to the re-tensioning anchorage 103 having an outer diameter to which 12 PC strands, which are the largest individuals, in the re-tensioning anchorage of the multi-cone type can be combined. Although the PC strand 101 is defined as three to twelve, but if necessary, the re-tension anchorage 103 is enough to be combined with more than 12 PC strands 101, as well as single or two. This may be the case.

Therefore, since the variable machining portion 14 has an inner diameter smaller than the outer diameter of the recognized fixing unit 103 having the minimum outer diameter, the female screw portion 15 is formed on the inner surface of the variable machining portion 14 as described above. The inner working diameter of the female screw portion 15 may be cut to match the outer diameter of the re-tensioning anchorage 103 of the underground anchor to be mounted.

In addition, since the variable machining portion 14 has a range width that can accommodate both the retracting anchorage of the minimum outer diameter and the retraction anchorage of the maximum outer diameter, the female thread is cut by cutting to match the outer diameter of the corresponding retensioning anchorage. When the part 15 is formed, the protective cap 10 may have a screw coupling form to the retensioning anchor 103 as shown in FIG. 5.

In particular, the conventional re-tensioning anchorage 103 is generally formed with a male threaded portion on the outer surface, such a male threaded portion when the re-tensioning adjustment to the PC strand using the re-tensioning anchorage 103 It is to have a purpose to be able to couple the jig of the tensioner by using the male screw portion, in the present invention, the female screw portion 15 to be screwed to the male screw portion of the re-tensioning anchor 103 as described above is formed As a result, the protective cap 10 of the present invention can be fastened in a screwing manner to the retensioning anchorage 103 by using the internal threaded portion 15 therein.

In addition, the protective cap 10 screwed to the re-tensioning anchor 103 as described above, when the flange portion 14 of one side is in contact with the bearing plate 102, using a protective cap 10 using a separate fastening bolt 10 And the bearing plate 102 to be firmly fixed to each other, the protective cap 10 of the fixed state as described above is the end of the PC strand (101) and the retensioning anchorage 103 and the wedge 104 inwards. Will be accommodated and protected.

In particular, one side of the protective cap 10 as described above forms a coupling hole 19 penetrating through the inner space 11, as shown in Figure 6, the coupling hole 19 is a nipple made of a soft elastic material 30 is coupled to form, but the nipple 30 is formed with a cut line 31 penetrating along the direction of the coupling hole 19.

Here, the nipple 30 is ideally a material having excellent strain and elastic restoring force such as silicon, and as described above, the grease inside the protective cap 10 in a state where the protective cap 10 is coupled and mounted. It is to prevent the corrosion of the end of the PC strand and the re-tension anchorage and the wedge accommodated by the injection. In the prior art, the oil injection nipple is made of a metal bolt, so in order to inject oil, the bolt is separated and then removed. Since oil had to be injected into the joint hole, the work was very cumbersome and there was a high risk of loss when the bolt was dropped.

Accordingly, in the present invention, the nipple 30 as described above is formed of a soft elastic material and forcedly inserted and fixed into the coupling hole 19, and the cut nipple 31 through the center is formed in the nipple 30 as described above. As a result, when the incision line 31 is kept in close contact with the sealing line 31 due to the forced insertion of the nipple 30, and when oil or grease is to be injected, the oil injector 32 of FIG. As the incision line 31 is expanded due to the forced insertion, the oil injector 32 may be inserted into the protection cap 10, so that the oil or grease may be easily injected and refilled without removing the nipple 30 as described above. This would be possible.

In addition, in the present invention, the variable machining portion 14 and the female screw portion 15 formed in the inner space 11 of the protective cap 10 may be integrally formed with respect to the protective cap 10 as in the above embodiment. 8 and 9, a separate object may be inserted into the inner space 11 of the protective cap 10 to form the variable machining part 14 and the female screw part 15 in the object. will be.

That is, the inner space 11 of the protective cap 10 forms a settled groove portion 16 in the inner space 11 in a state of having a sufficient inner diameter, and is provided separately into the settled groove portion 16. Formed to form the engaging strip 20, the protective cap 10 of the detachable structure can be completed by forming the female screw portion 15 of the inner diameter required to the inside of the engaging strip 20.

In this case, a plurality of fitting grooves 17 are formed on the inner surface of the settlement groove part 16, and fitting fittings 21 corresponding to the fitting grooves 17 are formed on the outer surface of the locking zone 20. By the mutual coupling of the groove 17 and the fitting port 21, the protective cap 10 and the locking device 20 can be rotated equally to each other, the locking device 20 in accordance with the rotation of the protective cap 10 The female screw portion 15 is to be screwed to the male screw portion formed on the outer surface of the re-tensioning anchor 103.

In particular, the gage region 20 as described above will have a variable processing portion 14 of sufficient thickness to be manufactured in the form of a plate rather than the hollow form, the re-tensioning anchorage is constructed using such a variable processing portion 14 ( By forming the female screw portion 15 having the same inner diameter as the outer diameter of 103, it is possible to make a protective cap 10 having the female screw portion 15 of the desired inner diameter. In addition, the locking zone 20 as described above may be formed in the form of a plate to form a female screw portion 15 through a separate processing, but more preferably, the locking zone in the form of the female screw portion 15 of various standards ( It would be ideal to separately fabricate 20) and insert it into the protective cap 10 for use.

In addition, the protective cap 10 of the separation structure as described above is a separate protective cap 10 in a state in which the screw 20 is screwed ahead of the male screw portion of the re-tensioning anchor 103 as shown in FIG. It is to produce a feature that can be mounted and fixed in the manner to be inserted into the gage earth (20), in this case free adjustment of the insertion height of the gage (20) as well as a protective cap having a screw coupling method ( 10) More convenient and easy mounting installation is possible.

In addition, as another embodiment of the protective cap 10 having the detachable locking region 20 as described above, as shown in FIGS. 11 and 12, the multi-faceted groove 18 is formed in the inner space 11 of the protective cap 10. And forming a multi-faceted portion 22 corresponding to the multi-faceted groove 18 on the outer surface of the interlocking portion 20, when the interlocking portion 20 is inserted into the protective cap 10 at the same time. In the case of forming the female threaded portion 15 of various inner diameters with respect to the locking zone 20 as described above, various outer diameters may be obtained by replacing and applying the locking zone 20 from a protective cap 10 of a single standard. It can be used corresponding to the re-tension anchorage 103 having a.

Accordingly, since the protective cap 10 of the present invention can be used in common for the re-tensioning anchorage 103 of various sizes using the protective cap 10 of a single standard, it is possible to innovatively reduce initial mold investment and manufacturing costs. Of course, the handling and management and supply and demand for the protective cap 10 will produce a simple effect.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the present invention as defined by the appended claims. Examples should be understood.

10: protective cap 11: inner space
12: fastening hole 13: flange
14 variable processing part 15 female thread part
16: settled groove 17: fitting groove
18: multi-faceted groove 19: coupling hole
20: Gye district 21: fitting
22: multifaceted part
30: nipple 31: incision
32: oil injector

Claims (5)

One side is open and has an internal space 11, and has an improved structure formed by protruding the flange portion 13 having a fastening hole 12 on the open one outer surface and the settled groove portion 16 in the inner space In the underground anchor protection cap 10,
In the settling groove portion 16 of the protective cap 10 is formed to form a coupling region 20 having a variable machining portion 14 and the female screw portion 15 separately, the inner groove of the settle groove portion 16, the fitting groove ( 17) and a protective cap for underground anchors having an improved structure, characterized in that the fitting groove (21) corresponding to the fitting groove (17) protrudingly formed on the outer surface of the locking earth (20).
The method of claim 1,
The inner space 11 of the protective cap 10 is formed with a multi-faceted groove 18 for inserting the locking zone 20, the outer surface of the locking zone 20 is a polygonal angle corresponding to the multi-faceted groove 18 A protective cap for underground anchors having an improved structure, characterized in that the surface portion 22 is formed.
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