KR101018844B1 - Girder and re-strain construction method - Google Patents

Abstract

PURPOSE: A girder and a re-strain method thereof are provided to securely support the girder by integrally installing tendons between saddles even if the tensed state of the girder is continued for a long time. CONSTITUTION: A girder comprises a section steel, a lifting slider(200), saddles(300), tendons, and a lifting position determination member. The lifting slider is arranged in the section steel to be ascended and descended. The saddles are installed in the bottom of the lifting slider. The tendons are installed in both ends of the section steel and are supported by the saddles. The lifting position determination member determines the lifting position of the lifting slider.

Description

Girder and Re-Strain Construction Method

The present invention relates to a girder and a re-tensioning construction method, in particular, a beam, a lift slider disposed to be liftable to the beam, birds provided on the lower surface of the lift slider, and the beam of the beam while being supported by the saddle A girder including a tension member fixed at both ends, a lifting positioning member for determining a lifting position of the lifting slider, and a step of installing a tension member at a lower part of the lifting slider provided in the steel, and an auxiliary plate installed at a lower portion of the steel. And tightening the lifting positioning bolt of the elevating slider drawn out of the auxiliary plate to the lower portion of the shaped steel, arranging a hydraulic jack between the auxiliary plate and the shaped steel, and actuating the hydraulic jack to move the elevating slider. Retightening the tension member by retightening the lifting positioning nut at a position where the tension member is retensioned; It relates to re-tension construction of the girder comprising the step of determining the tension position method.

[Documentation information of the prior art] Korean Patent Publication No. 10-2007-0111083

In the conventional girder, a moving rod is installed between a hydraulic jack fixed to the top of the girder and an induction cylinder fixed to the bottom of the girder, and the moving rod is installed on the moving rod.

The moving cylinder is installed to be movable up and down along the moving rod by the operation of the hydraulic jack.

The outer surface of the moving cylinder is bent in the transverse direction of the girder, the saddle is installed.

Steel wires are installed at fixed ends 2a and 2b respectively provided at both ends of the saddle and the girder.

Looking at the tension of the girder, the moving cylinder is moved downward along the moving rod by the hydraulic jack, the gap between the top of the girder and the moving cylinder is far apart and the birds push the steel wire downward while the girder Becomes tense.

In the conventional girder, the steel wire is not connected to one, and the steel wire and the birds are connected in a state in which the steel wire is disconnected. Therefore, when the tension is maintained, the pressure of the hydraulic jack is reduced from the top to the bottom. There is a problem that the efficiency of the force acting on the steel wire is lowered because it is applied.

The present invention has been made to solve the above-described problems, and an object thereof is to provide a girder and re-tensioning construction method which lasts a long tension state and increases the efficiency in tension.

Girder of the present invention for achieving the above object, the lifting steel, the elevating slider which is arranged to elevate to the steel beam, the saddle is provided on the lower portion of the elevating slider, and both ends of the shaped steel supported by the saddle And an elevating positioning member for determining an elevating position of the elevating slider and the tension member to be mounted.

A guide rail is installed in the section steel, and a guide groove guided along the guide rail is formed in the elevating slider.

The cross section of the section steel consists of a web formed on both sides between the upper flange and the lower flange, and the upper flange and the lower flange to form a box shape, the both webs are provided with the guide rail, the lower flange is drawn out A ball is formed, and the elevating positioning member is provided with an elevating positioning bolt having an upper end mounted to the elevating slider and a lower end thereof drawn out through the drawing hole, and an elevating positioning nut fastened to the drawn elevating positioning bolt. It is composed.

The upper limit stopper for the slider is provided on the web, and the lower limit stopper for the slider is installed on the lower surface of the elevating slider, wherein the lower limit stopper for the slider is at least lower than the saddle.

Installing a tension member at a lower part of the lifting slider installed in the steel, and installing an auxiliary plate at the lower part of the steel, and fastening the lifting positioning bolt of the lifting slider drawn out of the auxiliary plate to the lower part of the steel, Arranging a hydraulic jack between the auxiliary plate and the section steel; operating the hydraulic jack to re-tension the lifting slider by pressing the tension member; and refastening the lifting positioning nut to a position where the tension member is re-tightened. Retension the girder by determining the tension position.

According to the girder and re-tension construction method of the present invention as described above, there are the following effects.

Since the tension member is connected to one of the elevating slider and the birds installed on the lower portion of the elevating slider, the tension member is not easily broken even if the tension lasts for a long time, so that it can be more firmly supported.

A guide rail is installed in the section steel, and a guide groove guided along the guide rail is formed in the slider, so that the slider can continue vertical movement without shaking.

An upper end of the elevating positioning boat is installed on the elevating slider, and a lower end thereof is drawn out through the drawing hole, and an elevating positioning nut is fastened to the drawn elevating positioning bolt to secure the elevating slider when tensioned. have.

The upper limit stopper for the slider is installed on the web to prevent collision with the upper flange when the slider is moved upward, and the lower limit stopper for the slider which is installed on the lower surface of the slider and at least below the saddle is installed. It can protect the steel wire supported by the saddle.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

2 is a side view of the girder before the tension state according to a preferred embodiment of the present invention, Figure 3 is a side view of the girder after the tension state according to a preferred embodiment of the present invention, Figure 4 is a sectional view of the girder of Figure 2, Figure 5 3 is a cross-sectional view of the girder, Figure 6 is a girder separate view according to a preferred embodiment of the present invention, Figure 7 is a lifting slider installation state of Figure 6, Figure 8 is a perspective view of the lifting slider according to a preferred embodiment of the present invention.

As shown in FIG. 2, the girder G of the present embodiment includes a lifting steel 100, a lifting slider 200 disposed on the lifting steel 100 so as to be liftable, and a lower portion of the lifting slider 200. Saddle 300 is installed, the tension member 400 is fixed to both ends of the section steel 100 while being supported by the saddle 300, and the lifting positioning member for determining the lifting position of the lifting slider 200 ( 500).

The girder (G) is coupled to the two I-shaped section steel, by applying a steel plate to each of the sections to be bonded to each of the steel beams are assembled by bolts.

The shape steel 100 is composed of webs 130a and 130b formed at both sides between the upper flange 110 and the lower flange 120, and the upper flange 110 and the lower flange 120.

A drawing hole 180 is installed in the lower flange 120 to fasten the shaped steel 100 and the lifting slider 200.

The web 130 is formed of a left web 130a and a right web 130b between the upper flange 110 and the lower flange 120.

Guide rails 170 are installed on the left web 130a and the right web 130b, respectively, to assist the vertical movement of the elevating slider 200.

In addition, an upper limit stopper 150 for a slider is installed on the web 130.

The upper limit stopper 150 for the slider is installed at a position higher than the lifting slider 200 to prevent the collision with the upper flange 110 when the lifting slider 200 moves upward to protect the lifting slider 200. do.

The elevating slider 200 is provided on the support plate 290 and the reinforcement member 210 installed in the vertical direction of the support plate 290, the jaw 230 supporting the reinforcement member 210 and the sides 291 of the support plate 290. The guide groove 270 and the lifting slider 200 are formed of a fastening hole (not shown) formed in the support plate 290 to fix the shaped steel 100.

The support plate 290 is formed in a plate shape, the guide groove 270 for guiding the guide rail 170 is installed.

The reinforcement 210 is installed perpendicular to the support plate 290, and is installed at each side 291.

Upper reinforcing material (211a) is installed in parallel to the upper horizontal side 291a of the support plate 290.

The upper reinforcement 211b is installed one more apart by the width w of the jaw.

The left reinforcement 212a is installed in parallel to the left vertical side 291b of the support plate 290.

The lower reinforcement 210c is provided in parallel so as to be close to the lower horizontal side 291c of the support plate 290.

The lower reinforcement 210d is installed one more apart by the width w of the jaw.

The right reinforcement 212b is installed perpendicular to the support plate 290, and is installed in parallel to the right vertical side 291d of the support plate 290.

The jaw 230 is formed on the support plate 290 by the ends of the reinforcing members 212a and 212b and the sides 291 of the support plate 290 to support the reinforcing member 210.

The left first jaw 231 is formed at the upper left side by connecting the end of the left reinforcing member 212a and the left vertical side 291b of the support plate 290.

The left second jaw 232 is connected to the end of the left reinforcing member 212a and the left vertical side 291b of the support plate 290 to surround the guide groove 270.

The left third jaw 233 is connected to the end of the left reinforcing member 212a and the left vertical side 291b of the support plate 290 is formed in the lower left.

The right jaws 234, 235, 236 are symmetrical to the left jaws 231, 232, 233 with respect to the centerline.

The saddle 300 is installed below the elevating slider 200, and both ends of the saddle 300 are fixed to the elevating slider 200 to support the tension member 400.

The tension member 400 is composed of a steel wire 410 and a steel pipe 430 surrounding the steel wire 410.

The steel wire 410 is composed of a bundle of steel wire bundle of several steel wires, a plurality of wire bundles are disposed inside the steel pipe 430.

Since the steel pipe 430 surrounding the steel wire 410 is firmly disposed between the lifting slider 200 and the saddle 300, even when the maximum tension is not easily broken.

The lower limit stopper 250 for the slider is installed at the lower portion of the elevating slider 200 to communicate with a fastening hole (not shown) of the elevating slider 200, and is formed at a distance g from the saddle 300. .

Even if the elevating slider 200 is downwardly in contact with the lower flange 120, the saddle 300 stops at a distance g from the lower flange 120, and thus, the steel wire 410 or the steel pipe 430. ) Is not broken.

The elevating positioning member 500 fixes the beam 100 and the elevating slider 200, and includes an elevating positioning bolt 510 and an elevating positioning nut 520.

The lifting positioning bolt 510 is fastened to the inside of the surface surrounded by the reinforcing material 210, there is no risk of colliding with the upper flange 110 when the lifting slider 200 moves upward.

The length of the lifting positioning bolt 510 is longer than the height (H) between the lifting slider 200 and the lower flange 120 of the steel (100).

The elevating positioning nut 520 fastens the elevating positioning bolt 510 protruding through the outlet hole 180 of the lower flange 120 to fix the elevating slider 200.

The operation of the present embodiment having the above-described configuration will be described below.

A guide rail is attached to the web of the shaped steel, and the guide rail is fitted into the guide groove of the elevating slider. An upper limit stopper for a slider is welded to the web.

A tension member is installed in the lower part of the lifting slider in the steel beam, and an auxiliary plate (not shown) is installed in the lower part of the steel beam.

After fastening the lifting positioning nut to the lifting positioning bolt of the lifting slider drawn out to the lower part of the steel, and fixing the position, and fastening the auxiliary plate (not shown) in the lower portion of the steel to the lifting positioning bolt.

When a hydraulic jack (not shown) is disposed between the auxiliary plate (not shown) and the section steel, the gap is increased between the auxiliary plate (not shown) and the section steel, and the gap between the lower portion of the section steel and the lifting slider is narrowed. The tension material is in a retensioned state.

At this time, the lifting tensioning nut is adjusted and re-fastened to the lifting positioning bolt to determine the retension position so that the tension member is suitable for the retensioned position.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or changes to the present invention without departing from the spirit and scope of the invention described in the claims below It can be modified.

As mentioned above, the girder which concerns on this invention is especially suitable for the girder which lasts a tension state long.

1 is a cross-sectional view of a conventional girder.

Figure 2 is a side view of the girder before the tension state according to a preferred embodiment of the present invention.

Figure 3 is a side view of the girder after the tension state according to a preferred embodiment of the present invention.

4 is a sectional view of the girder of FIG.

5 is a sectional view of the girder of FIG. 3.

6 is an exploded view of the girder in accordance with the preferred embodiment of the present invention.

FIG. 7 is a state diagram of the elevating slider of FIG. 6. FIG.

8 is a perspective view of the elevating slider according to an embodiment of the present invention.

** Description of symbols for the main parts of the drawing **

100: section steel 110: upper flange

120: lower flange 180: drawing hole

130a, 130b: Web 150a, 150b, 150c, 150d: Upper limit stopper

170: guide rail 200: elevating slider

210: reinforcement 230: jaw

250: lower limit stopper 270: guide groove

290: support plate 300: saddle

400: tension member 500: lift positioning member

510: Lifting positioning bolt 520: Lifting positioning nut

Claims (5)

Section steel; An elevating slider arranged to be elevated on the beam; Saddles installed in the lower portion of the lifting slider; A tension member fixed to both ends of the section steel while being supported by the saddle; And including a lifting positioning member for determining the lifting position of the lifting slider, The tension member supports the elevating slider below the elevating slider, The elevating positioning member has an upper end mounted on the elevating slider, and an elevating positioning bolt drawn down through a drawing hole formed at a lower portion of the section steel, and an elevating positioning bolt fastened to the drawn elevating positioning bolt. Girder, characterized by consisting of nuts. The method of claim 1, The girders, characterized in that the guide rail is installed in the section steel, the guide slider is formed in the lifting slider is guided along the guide rail. The method of claim 1 , The cross section of the section steel is composed of a web formed on both sides between the upper flange and the lower flange, the upper flange and the lower flange to form a box shape, Both side webs are provided with guide rails , The drawer hole is characterized in that formed in the lower flange. The method of claim 3, wherein The web is provided with an upper limit stopper for the slider, A lower limit stopper for the slider is installed on a lower surface of the elevating slider, wherein the lower limit stopper for the slider is located at least below the saddle. Installing a tension member on a lower portion of the elevating slider installed in the section steel; Tensioning the tension member while allowing the tension member to support the elevator slider at the bottom of the elevator slider; Installing an auxiliary plate at a lower portion of the section steel; Fastening the elevating positioning bolt of the elevating slider drawn out of the auxiliary plate to the lower portion of the steel and disposing a hydraulic jack between the auxiliary plate and the steel; Actuating the hydraulic jack to cause the elevating slider to press and retension the tension member; And re-fastening the lifting positioning nut to a position where the tension member is re-tensioned to determine the re-tension position.

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