KR102444554B1 - Prestressed wale and it's construction method - Google Patents

Abstract

The present invention installs saddles at both ends of the beam, installs a stiffener between the inner flanges of the beam, and installs a trapezoidal arrangement of the strands for introducing the prestress of the PC steel wire between the saddle and the stiffener, thereby simplifying construction as well as An object of the present invention is to provide a prestress wale and a construction method therefor that have a better prestress effect.
The prestressed wale according to the present invention for achieving the above object comprises: an H-beam made of a flange and a web; a saddle that is fixedly installed between the flanges of both ends of the H-beam; at least one stiffener fixed in close contact with the inside of the H-beam at regular intervals; It is characterized in that it is composed of a PC steel wire installed over the saddle and the stiffener.
In addition, the prestress wale construction method according to the present invention for achieving the above object is an H-beam consisting of a flange and a web; a saddle that is fixedly installed between the flanges of both ends of the H-beam; at least one stiffener fixed in close contact with the inside of the H-beam at regular intervals; As a method of constructing a prestressed wale composed of a PC steel wire installed over the saddle and the stiffener, the prestressed wale is installed across the pre-installed H-beam.

Description

Prestressed wale and its construction method {Prestressed wale and it's construction method}

The present invention relates to a prestressed wale and its construction method, in particular, a saddle is installed at both ends of a beam, a stiffener is installed between the inner flanges of the beam, and an arrangement of a strand for introducing prestress of a PC steel wire between the saddle and the stiffener It relates to a pre-stress wale in which a trapezoid is installed and a construction method thereof.

Currently, there are braces and PS retaining methods as retaining methods widely used in the construction field.

Among them, the PS retaining method is a technology that introduces a pre-stress with PS steel to the wale and omits the brace by widening the support span of the wale. A look at the known prior art as a technique that is used externally is as follows.

According to Japanese Utility Model Hei 2-23036 (published on February 15, 1990), in the retaining method in which a wale is installed horizontally on the inside of the retaining wall, and the wale is supported by a brace, the short extension is One vertical member is erected on the inside, and it is reinforced with a truss-shaped retainer installed with PS steel between the upper part of this vertical member and the waving member, and one or more vertical members are erected between the brace and the beam for the long wadding member, and this It is a retaining method, characterized in that it is reinforced with a truss-shaped retaining wall in which PS steel is installed between the upper part of the vertical material and the junction of the wadding material and the brace.

The above method is a method of introducing prestress with PS steel to the wale, tensioning at both ends of the fixing unit, or pushing the PC steel wire upward with a hydraulic jack from the top of the vertical member, and introducing the prestress to the wale with the reaction force. After the first prestress is introduced, The introduction of additional prestress can be introduced by continuously pushing the PS steel upward, but the lengthening of the wale length is limited by the limit of the installed quantity of PS steel, and after introducing the prestress by pushing the PS steel upward, there are difficulties such as immobilization of the PS steel. There is an aspect that is impossible to make a long-span length of a wale jang.

Japanese Unexamined Patent Publication No. 6-57741 (published on March 1. 1994) connects the head of the I-beam inserted into the main heating element constituting the retaining wall with a wale, and inserts an external steel wire-type PS steel material along the surface of the wale between them. It is characterized in that it is made by introducing an initial stress by inserting a vertical material to the arc and fixing both ends thereof.

Such a retaining wall can maintain the displacement within an allowable range by freely adjusting out-of-plane deformation by the arch shape of the tension member spanned in an arc and the amount of initial stress introduced. It is easy to install because it is used, and it can be easily removed after use, and since the tension material is hung along the strip connecting the heads of the retaining wall to each other, it does not become an obstacle during underground construction, which further improves the construction efficiency compared to the brace type. can

However, there is a problem that additional prestress cannot be introduced after the initial prestress is introduced and the construction is somewhat complicated.

Japanese Special Publication Hei 7-56136 (1955. 6. 4. Announcement) discloses a retaining method in which a wale is installed on the inside of the retaining wall and the corner is reinforced with a clipboard, in addition to installing a PS steel material inside the retaining wall, It is a prestress retaining method, characterized in that by installing a hydraulic jack that tensions the PS steel in the vertical direction in the center of the wale, the PS steel as a reaction force, and applying a reverse reaction force to the wale by a hydraulic jack reduces the earth pressure on the wale.

This construction method is made by reducing the bending moment and shearing force of the wale by adding a reverse reaction force to the central part of the wale with a hydraulic jack as a reaction force of the PS steel installed on the wale. Thereby, it is possible to reduce the cost of retaining and foundation excavation.

In addition, it can be seen that there are characteristics such as improving the efficiency of underground construction because it is possible to design the support span of the wale according to the size of the earth pressure or the planar scale of the excavated ground, and to secure a wide internal space.

The above method has a problem in that the hydraulic jack must be continuously maintained on the upper part of the vertical member when introducing the first pre-stress or when additional pre-stress is introduced.

In addition, Patent 10-0188465 (registered on Jan. 12, 1999) relates to a retaining method that supports an excavated earth wall at a civil construction site to prevent collapsing. It is a retaining method by pre-stress, in which the earth pressure is supported by joining the section steel to the section, inserting a pre-stressed cable thereto, and tensioning it, thereby allowing the pre-stress moment generated in the section steel to resist the earth pressure.

The above construction method inserts an H-pile or a sheet pile for excavation as in the existing strut method for excavation and excavates, but installs a wale sheet in the horizontal direction on the front of the pile, and the edge of the wale sheet is It is supported by a brace, and the double rib girders are attached and installed again at regular intervals on the surface of the rib girders.

This method is expected to have some effect in widening the spacing of the braces, but since the steel wires are arranged in a straight line, a negative moment of a certain size is generated unlike the parabolic moment distribution that occurs in the wale due to the earth pressure. There is a limit to the length of the reinforcing band because the moment and its distribution are different from each other.

Patent 10-0571102 (registered on April 7, 2006) is a pre-stressed temporary facility that significantly reduces a number of braces and intermediate piles that have caused a lot of trouble in the conventional temporary facility construction by using a number of triangular supports, anchoring devices and steel wires, and its The technique is presented.

This method is effective in reducing the number of braces and intermediate piles, characterized in that prestress is applied to a separate wale installed on the pedestal by tensioning the steel wire in the corner fixing device.

However, since a very large tensile force (100 tons or more) is required to pre-stress the wale in the entire section through the pedestals in the narrow space of the corner where the fixing device is installed. The work is inconvenient and there is a problem with safety during construction.

In addition, due to elastic elongation according to the tension of the steel wire, the work has to be done while cutting the elongated steel wire continuously, so there is a disadvantage in that the working time is long.

Patent 10-0659744 (registered on December 13, 2006) applies a structure that can apply a vertical compression force to a predetermined central portion of the wadding material, so that the compression force applied to both ends is the same, so that the PreStress Moment is exactly at the center. There is an advantage in that it is easy to install with the retaining method against pre-stress, which is easy to install, but there is a disadvantage that it is impossible to make a long span of a wale because the quantity of PS steel is small. .

Patent 10-0778137 (registered on November 14, 2007) horizontally connects a horizontal beam in which a plurality of pedestals are integrally coupled to a vertical pile installed vertically on the ground, and integrates a fixing device on the side or both ends of the horizontal beam. Forming, while fixing the end of the steel wire to the fixing device integrated with the horizontal beam, the steel wire is supported in contact with the end of the pedestal to apply prestressing, and the installation position of the pedestal installed on the horizontal beam is the vertical pile. It is a pre-stressed temporary construction method that combines the position to match the position.

Since it is a combination of existing known technologies, there is a disadvantage in that it is impossible to introduce additional prestress.

Patent 10-812722 (registered on March 5, 2008) connects a wale to which a plurality of pedestals are attached to the side of a vertical pile installed vertically on the ground, and both ends of a steel wire in which the middle part is connected by a coupler to the side of the wale Alternatively, it is fixed to the fixing device installed at both ends, and the steel wire is contacted and supported on the end of the pedestal to tension it.

In addition, a plurality of pedestals capable of height adjustment are combined on the side of a vertical pile installed vertically on the ground, and after adjusting the height of the plurality of pedestals, one or more pedestals installed in the center of the wale are pushed up to apply prestressing. Introducing prestress using a coupler is ineffective in actual construction, and the introduction of prestress by manpower with a screw jack on a pedestal that can be adjusted in height has very little effect and is not practical. something to do.

Laid-Open Patent Publication No. 10-2004-0031451 (published on April 13, 2004) uses a number of pedestals, anchoring devices, and steel wires to apply prestressing to vertical piles, horizontal beams, and cast beams, thereby greatly hindering conventional temporary facility construction. Because it is possible to significantly reduce the number of braces and intermediate piles that caused The constructability of reinforcing reinforcement and formwork of the structure becomes very convenient, and it has the effect of significantly improving the waterproofness and durability of the completed structure. did.

Therefore, the retaining method of introducing prestress to the wale made of PS steel can increase the length of the wader rather than the retaining supported by pure bracing, thereby increasing the spacing of the struts. In terms of economic feasibility, the cost required to increase the spacing of the braces by making the length of the band longer than the cost of the braces is reduced. There is a problem in that the accompanying cost is not reduced.

In other words, although prestress was introduced into the wale to reduce the amount of steel material for the brace, it is not the same as or significantly different from the cost of the brace, which reduces the cost of manufacturing and construction, as well as all materials added to increase the spacing of the brace.

In this reality, there is no choice but to find a way to reduce the overall cost by improving the construction efficiency rather than judging the efficiency by analyzing the cost.

On the other hand, registered patent 10-0908321 (July 10, 2009, registered), a plurality of vertical files arranged at regular intervals; A wale in which a plurality of pieces are fixedly installed across the vertical piles; In the temporary retaining system consisting of braces fixedly installed between the wales at a right angle, the central part of the wale between 02L to 06L is added to a general I-beam with a high-strength I-beam, and pre-stress is applied to it to introduce prestress. And, at both ends of the prestressed synthetic wale, I-beams having a higher shape than the general I-beam are connected and installed, and a large block PS steel fixing unit is installed in the I-beam having a high shape, and a small block PS is placed on both ends of the high-strength I-beam. A steel fixing unit is installed, and a prestress control device is vertically attached at regular intervals to the upper end of the entire length of the prestress synthetic band, and PS steel is inserted into the large block PS steel fixing unit and the prestress control device, and the small block PS After inserting PS steel into the steel fixing part, it is a hydraulic system that can control the hydraulic jack by load and displacement to introduce prestress by pulling PS steel at both ends of the fixing part, or by adjusting the prestress adjusting device upwards to introduce prestress. And, it is characterized in that additional prestress can be controlled by additionally tensioning and releasing PS steel at both ends of the fixing unit in response to changes in earth pressure during construction, or by additionally adjusting the prestress control device upward and downward.

Therefore, the above-described conventional prestress synthetic wale for temporary retaining facilities has the advantage of improving the construction efficiency, but has a problem in that it is inferior to the conventional brace wale in terms of economical efficiency.

Japanese Utility Model Hei 2-23036 (published on February 15, 1990) Japanese Unexamined Patent Publication No. 6-57741 (published on March 1, 1994) Japan Special Hei 7-56136 (1955. 6. 4. Announced) Registered Patent 10-0188465 (Registered on Jan. 12, 1999) Registered Patent 10-0571102 (2006. 4. 7. Registered) Registered Patent 10-0659744 (Registered on December 13, 2006) Registered Patent 10-0778137 (Registered on November 14, 2007) Registered Patent 10-010722 (Registered on March 5, 2008) Laid-Open Patent Publication No. 10-2004-0031451 (published on April 13, 2004) Registered Patent 10-0908321 (Registered on Jul. 10, 2009)

Accordingly, the present invention has been devised to solve the above problems, by installing saddles at both ends of the beam, installing a stiffener between the inner flanges of the beam, and introducing prestress of a PC steel wire between the saddle and the stiffener. An object of the present invention is to provide a pre-stress wale and its construction method, which is not only simple in construction but also more excellent in pre-stress effect by installing the arrangement of the strands in a trapezoidal shape.

The prestressed wale according to the present invention for achieving the above object comprises: an H-beam made of a flange and a web; a saddle that is fixedly installed between the flanges of both ends of the H-beam; at least one stiffener fixed in close contact with the inside of the H-beam at regular intervals; It is characterized in that it is composed of a PC steel wire installed over the saddle and the stiffener.

In addition, the prestress wale construction method according to the present invention for achieving the above object is an H-beam consisting of a flange and a web; a saddle that is fixedly installed between the flanges of both ends of the H-beam; at least one stiffener fixed in close contact with the inside of the H-beam at regular intervals; As a method of constructing a prestressed wale composed of a PC steel wire installed over the saddle and the stiffener, the prestressed wale is installed across the pre-installed H-beam.

As described above, in the prestressed wale and its construction method according to the present invention, saddles are installed at both ends of a beam, a stiffener is installed between the inner flanges of the beam, and a stranded wire for introducing prestress of a PC steel wire between the saddle and the stiffener. It has the advantage of not only simple construction but also excellent pre-stress effect by installing the trapezoidal arrangement.

1 is a perspective view showing a pre-stress wale according to the present invention;
2 is a front view showing a pre-stressed wale according to the present invention;
Figure 3 is an exemplary view showing a state in which the pre-stress band according to the present invention is installed.

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

Figure 1 is a perspective view showing a prestress wale according to the present invention, Figure 2 is a front view showing the prestress wale according to the present invention.

As shown in these figures, the prestressed wale (W) according to the present invention includes an H-beam 100 consisting of a flange 110 and a web 120; a saddle 200 fixedly installed between the upper and lower flanges 120 of both ends of the H-beam 100; a stiffener 300 to which at least one or more are closely fixed to the inside of the H-beam 100 at regular intervals; It is composed of a PC steel wire 400 installed over the saddle 200 and the stiffener 300 .

That is, the pre-stress wale (W) according to the present invention is a member formed by organically combining the H-beam 100, the saddle 200, the stiffener 300 and the PC steel wire.

Here, the H-beam 100 is a section steel composed of upper and lower flanges 110 and a web 120 .

In particular, the saddle 200 is composed of a lattice-shaped rectangular steel material, and the grid-shaped rectangular steel material is fixedly installed in the upper and lower flanges 110 at both ends of the H-beam 100 with high tension bolts.
In addition, the saddle 200 also performs the anchoring function of the PC steel wire (400).

In addition, the stiffener 300 includes a rectangular receiving plate 310 attached to the upper and lower flanges 120 of the H-beam 100 by magnetic force, respectively, and a jack for length adjustment between the rectangular receiving plate 310 ( 320) is fixedly installed.

In particular, the receiving plate 310 is made of a magnetic material as a rectangular steel plate 320 thin in thickness compared to the width, and a plurality of through holes 330 are formed from one side of the steel plate 320 to the other.

Here, the receiving plate 310 is attached to the upper and lower flanges 110 as a magnetic material, and then is closely attached using a jack 320 for adjusting the length.

The stiffener 300 is installed to prevent buckling of the flange 110 or the web 120 of the H-beam 100 .

In addition, the length adjustment jack 320 is configured as a turnbuckle or hydraulic jack.

In particular, after the jack 320 for adjusting the length is attached to the receiving plate 310, it is possible to adhere to and detach from the receiving plate 310 according to the rotation direction of the jack 320 for adjusting the length.

And, the PC steel wire 400 is a stranded wire between the saddle 200 and the stiffener 300 and between the stiffener 300 and the stiffener 300 and between the stiffener 300 and the saddle 200 is fixedly installed in a trapezoidal shape. .

Hereinafter, the construction of the pre-stress wale according to the present invention having the configuration as described above will be described.

3 is an exemplary view showing a state in which the pre-stress wale according to the present invention is installed.

As shown in this figure, the prestress wale construction method according to the present invention includes an H-beam 100 consisting of a flange 110 and a web 120; a saddle 200 fixedly installed between the flanges 120 at both ends of the H-beam 100; a stiffener 300 to which at least one or more are closely fixed to the inside of the H-beam 100 at regular intervals; As a method of constructing a prestress wale (W) composed of a PC steel wire 400 installed over the saddle 200 and the stiffener 300, a prestress wale (W) is installed across the pre-installed H beam (H) do.

As described above, in the prestress wale and its construction method according to the present invention, the saddles 200 are installed at both ends of the H-beam 100 , and the stiffener between the inner upper and lower flanges 110 of the H-beam 100 . By installing the 300, installing the PC steel wire 400 in a trapezoidal shape between the saddle 200 and the stiffener 300, and introducing the prestress into the PC steel wire 400, the construction of the prestress wale W is simple. Not only that, but the pre-stress effect is also more effective.

The preferred embodiments described in the description of the present invention are illustrative and not restrictive, the scope of the present invention is indicated by the appended claims, and all modifications falling within the meaning of those claims are included in the present invention. will become

100: H-beam 110: flange
120: web 200: saddle
300: stiffener 310: receiving plate
320: jack for length adjustment 400: PC steel wire
H: H-beam W: Pre-stressed braid

Claims (5)

H-beam 100 consisting of a flange 110 and a web 120 and; a saddle 200 fixedly installed between the flanges 120 at both ends of the H-beam 100; a stiffener 300 to which at least one or more are closely fixed to the inside of the H-beam 100 at regular intervals; It consists of a PC steel wire 400 installed over the saddle 200 and the stiffener 300, and the saddle 200 is made of a grid-type rectangular steel, and upper and lower flanges at both ends of the H-beam 100. A grid-shaped rectangular steel material is fixedly installed with a high-tensile bolt in the 110, the saddle 200 also performs the anchoring function of the PC steel wire 400, and the stiffener 300 is the upper and lower flanges 120 of the H-beam. ), a rectangular receiving plate 310 attached by magnetic force, and a jack 320 for adjusting the length between the rectangular receiving plate 310 is fixedly installed, and the receiving plate 310 has a thin thickness compared to the width. The steel plate 320 is made of a magnetic material, and a plurality of through-holes 330 are formed from one side of the steel plate 320 to the other side, and the receiving plate 310 is a magnetic material and is formed on the upper and lower flanges 110. After attachment, it is closely attached using a jack 320 for length adjustment, and the stiffener 300 is installed to prevent buckling of the flange 110 or web 120 of the H-beam 100, and the length adjustment jack ( 320) is composed of a turnbuckle or hydraulic jack, and after the jack 320 for length adjustment is attached to the receiving plate 310, it is possible to adhere and separate to the receiving plate 310 according to the rotation direction of the length adjustment jack 320. And, the PC steel wire 400 is a stranded wire between the saddle 200 and the stiffener 300, between the stiffener 300 and the stiffener 300, and between the stiffener 300 and the saddle 200. It is fixedly installed in a trapezoidal shape. Features a pre-stress wale. delete delete delete H-beam 100 consisting of a flange 110 and a web 120 and; a saddle 200 fixedly installed between the flanges 120 at both ends of the H-beam 100; a stiffener 300 to which at least one or more are closely fixed to the inside of the H-beam 100 at regular intervals; It is composed of a PC steel wire 400 installed over the saddle 200 and the stiffener 300, and the saddle 200 is composed of a grid-type rectangular steel, and upper and lower flanges at both ends of the H-beam 100. A grid-shaped rectangular steel material is fixedly installed with a high-tensile bolt in the 110, the saddle 200 also performs the anchoring function of the PC steel wire 400, and the stiffener 300 is the upper and lower flanges 120 of the H-beam. ), a rectangular receiving plate 310 attached by magnetic force, and a jack 320 for adjusting the length between the rectangular receiving plate 310 is fixedly installed, and the receiving plate 310 has a thin thickness compared to the width. The steel plate 320 is made of a magnetic material, and a plurality of through-holes 330 are formed from one side of the steel plate 320 to the other side, and the receiving plate 310 is a magnetic material and is formed on the upper and lower flanges 110. After attachment, it is closely attached using a jack 320 for length adjustment, and the stiffener 300 is installed to prevent buckling of the flange 110 or web 120 of the H-beam 100, and the length adjustment jack ( 320) is composed of a turnbuckle or hydraulic jack, and after the jack 320 for length adjustment is attached to the receiving plate 310, it is possible to adhere to and separate from the receiving plate 310 according to the rotation direction of the length adjustment jack 320. and the PC steel wire 400 is a stranded wire between the saddle 200 and the stiffener 300, between the stiffener 300 and the stiffener 300, and between the stiffener 300 and the saddle 200, and is fixedly installed in a trapezoidal shape. As a method of constructing a wale (W),
A pre-stress wale construction method, characterized in that the pre-stress wale (W) is installed across the pre-installed H-beam (H).

Images