KR101450229B1 - girder installation method - Google Patents

Abstract

A girder installation method according to the present invention for installing a girder in an abutment or a pier comprises the steps of constructing the abutment or the pier (SI); installing a lateral direction moving rail (SII); installing a lateral direction moving hydraulic system and a lateral direction moving carriage (SIII); installing a stopper (SIV); installing a girder mounting equipment (SV); installing the girder with a crane (SVI); moving the lateral direction moving carriage (SVII); installing a lateral direction hydraulic jack and lateral direction hydraulic jack reaction force base and moving the girder (SVIII); withdrawing the lateral direction moving carriage and the lateral direction hydraulic system (SIX); mounting the girder in a bridge bearing (SX); and mounting the girder in the lateral direction to the upper surface of the abutment and the pier (SXI).

Description

Girder installation method

More particularly, the present invention relates to a method for installing a girder, and more particularly, to a method of mounting a girder to one side of a pier and a pier by using a small capacity crane, And alternating of one side of the pier and the upper part of the pier, and the girder is moved to the upper part of the other side by transverse movement at the alternation and pier and the girder is seated. And after that, the girder is moved to the target installation point by transverse movement, and then the installation is repeated. Thus, the installation is completed when the girder is finally mounted on the upper part of one side of the bridge where the bridge is installed and the pier .

In general, as shown in FIG. 1, the girder G is lifted by the crane C and the elevation of the crane 10 and the crane 10 is increased. (C) In the case where installation is impossible, a large-scale launching system is constructed and installed in the longitudinal direction.

When the girder G is mounted by the crane C, the stationary capacity of the crane C is calculated by calculating the loadable distance of the girder G in consideration of the load of the girder G and the mount distance of the crane C do.

Generally, when the alternation and pier 10 are on the land side, even if the loading distance of the crane C is short, when the girder G is loaded in both directions of the alternation and pier 10, Is at least possible.

However, when bridges (TB) for construction are installed in a river or sea and bridges (G) are mounted on bridges (TB), bridging (TB) is not generally installed on both sides (TB) is installed only on one side of the girder (G), and the girder (G) is mounted collectively from one side to the other side of the bridge pier (10) by using a large capacity crane (C) .

However, even in this case, since a large-capacity crane (C) is required to be used, a bridge construction (TB) cost is high.

In order to reduce the cost of the crane (C) and reduce the construction cost of the bridge (TB) by using a smaller capacity crane (C), the girder (G) from the one side bridge A construction method that can be installed is required.

Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for constructing a girder by alternately arranging girders and piers using a small crane, The present invention provides a method of mounting a girder to allow the girder to be mounted.

According to another aspect of the present invention, there is provided a method of laying a girder in alternating and piercing directions, comprising the steps of: (S I) constructing the alternation and pier across a whole area; Installing a transverse moving rail (SII) on the alternating and piercing top surfaces; (SIII) of installing a transverse moving hydraulic device and a transverse moving bogie comprising a hydraulic jack reaction force band and a transverse hydraulic jack capable of being extruded and press-fit on the upper surface of one side end of the transverse moving rail; (Iv) installing a stopper on the upper surface of the other end of the lateral movement rail; A step (S V) of installing a girder laying device having upper and lower hydraulic jacks and transverse beams on the alternate and pierched upper surfaces; Installing a girder on the upper part of the transverse movement truck as a crane (S VI); Driving the hydraulic jack reaction force band and the transverse hydraulic jack to move the lateral movement bogie (S VII); (S VIII) of installing the hydraulic jack reaction force band and the transverse hydraulic jack on the upper surface of the transverse movement rail and moving the girder to a target seating point of the transverse movement rail; A step of moving the lateral movement bogie and the lateral movement hydraulic device from the lower side to the side after the transverse beam of the girder positioning device supports the girder by moving the upper and lower hydraulic jacks of the girder positioning device after moving the girder, S IX); Lowering the hydraulic jacks in the vertical direction of the girder nesting device to place the girders in the bridge nest (S X); And repeating the steps (V) through (S X) to alternately and horizontally laying the girders on the upper surface of the bridge pier (S XI).

As described above, the girder holding method according to the present invention has the following effects.

First, the present invention can greatly reduce the cost of bridging bridges in a river or sea.

Second, the present invention can reduce the cost of a crane by mounting a girder using a small-capacity crane.

Third, the present invention can construct a bridge regardless of the topography conditions such as river and sea.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary view showing a conventional girder fixing process;
2A to 2L are process drawings showing a girder holding process according to the present invention.

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

2A to 2L are process drawings showing a girder holding process according to the present invention.

As shown in these drawings, a method of placing a girder G in an alternating and piercing bridge 10 according to the present invention is characterized in that it comprises steps S (S I); Installing a transverse moving rail (12) on the upper surface of the alternating and piercing (10) (SII); A transverse moving hydraulic device 18 and a transverse moving truck 20 constituted by a hydraulic jack reaction force band 14 and a transverse hydraulic jack 16 capable of being pushed out and press-fit are provided on the upper surface of one lateral side of the transverse moving rail 12 Installing step (S III); (Iv) installing a stopper (22) on the upper surface of the other end of the lateral movement rail (12); A step (S V) of installing a girder holding device (28) composed of a vertical hydraulic jack (24) and a transverse beam (26) on the upper surface of the alternating and piercing angle (10); Installing a girder (G) as a crane (C) on the transverse moving bogie (20) (S VI); Driving the hydraulic jack reaction force band 14 and the transverse hydraulic jack 16 to move the transverse moving bogie 20 (S VII); The step of installing the hydraulic jack reaction force band 14 and the lateral hydraulic jack 16 on the upper surface of the transverse movement rail 12 and moving the girder G to a target seating point of the transverse movement rail 12 S VIII); After the girder G is moved, the vertical hydraulic jack 24 of the girder holding device 28 is operated to support the girder G of the girder holding device 28, A step (SIX) of pulling the lateral side moving hydraulic device (18) to the side when the car (20) and the lateral moving hydraulic device (18) are girders (G); Lowering the hydraulic jack 24 in the vertical direction of the girder unit 28 to place the girder G on the bridge support B (S X); (S XI) of transversely loading the girder G on the upper surface of the pier 10 by alternately repeating the above steps (S V) to (S X).

Here, the transverse hydraulic jack 16 shifts the girder G mounted on the pier 10 by the electronic control system E in the lateral direction.

The hydraulic jack 24 in the up and down direction of the girder holding device 28 is alternately raised and lowered by the electronic control system E and the girder G mounted on the bridge 10.

That is, the method for laying a girder according to the present invention is a method of placing a girder G on an alternating and piercing bridge 10, comprising the steps of: alternating between the whole sections and constructing the piers 10; A step (SII) of installing a transverse moving rail (12) on the upper surface of the pier 10 and the alternation of the whole area; A transverse moving hydraulic device (not shown) which is composed of a hydraulic jack reaction force band 14 and a transverse hydraulic jack 16 which can be extruded and press-fit is provided on the upper surface of one side end portion of the transverse moving rail 12 provided on the upper surface of the pier 10 18) and a transverse moving truck (20) (S III); (Iv) installing a stopper (22) on the upper surface of the other side end portion of the transverse movement rail (12) of the entire section; A step (S V) of installing a girder holding device (28) between the front and the rear of the pier to which the girder is ultimately to be installed, and a girder holding device (28) constituted by a vertical direction hydraulic jack (24) and a transverse beam (26) on the upper surface of the pier (10); Lifting the girder G with a crane C or the like and alternately shifting the girder G and installing the girder G over the entire portion of the transverse moving bogie 20 installed at the pier 10; (S VII) of simultaneously moving the transverse moving bogie 20 between the front and rear movable rails 12 by simultaneously driving the hydraulic jack reaction force band 14 and the transverse hydraulic jack 16 installed on the upper side of the transverse moving rail 12, ; The hydraulic jack reaction force band 14 and the transverse hydraulic jack 16 between the entire sections are sequentially moved on the upper surface of the transverse movement rail 12 to move the girders G in the longitudinal direction (S VIII) of repeatedly transversely moving to a point; The upper and lower hydraulic jacks 24 of the girder holding device 28 are simultaneously moved upward to move the transverse beams 26 of the girder holding device 28 to the girders 28, (SIX) of pulling the sidewise portion from the portion when the girder (G) is supported between the transverse moving bogie 20 and the transverse moving hydraulic device 18 between the entire sections after supporting the gimbals G; (S X) simultaneously lowering the hydraulic jacks 24 of the upper and lower direction of the girder holding devices 28 in the entire region to place the girders G on the bridge girder B; (S XI) of transversely mounting the girder (G) in the alternating and pierced angle (10) by repeating the steps (S V) to (S X) The transverse moving rail 12, the transverse moving truck 20, the transverse moving hydraulic device 18, and the stopper 22, which are used in the above-described embodiment.

Here, the transverse hydraulic jack 16 is constructed such that the electronic control system E alternately shifts the entire portion of the girder G mounted on the pier 10, Direction.

The upper and lower hydraulic jacks 24 of the girder elevator apparatus 28 are alternately moved by the electronic control system E and temporarily move the whole area of the girder G mounted on the pier 10 to form girders G) at the same time.

The operation of the transverse hydraulic jack 16 is carried out by temporarily and temporarily moving the whole area of the girder G mounted in the entire area by the electronic control system E so as to move the girders G The upper and lower hydraulic jacks 24 of the girder positioning device 28 can also be mounted on the girders G mounted in the entire area by the electronic control system E in the lateral direction And the girders G between the entire sections can be raised and lowered at a time to be precisely constructed.

The method of the present invention having the above-described structure is characterized in that a bridge (TB) is installed only on one side of the alternating and piercing rods (10) The girder G is mounted to the upper portion of the pier 10 by the crane C while the girder G is mounted from the side to the other side, In the alternating and piercing angle 10, the girder G is moved transversely to the upper portion of the other side portion to seat the girder G and successively moved to the upper portion of one side of the pier 10 by the crane C, (G), and thereafter, the girder G is moved to a target installation point by transverse movement and is repeatedly moved to install a bridge (TB) and a crane (10) C), the girder (G) is completely fixed when the girder (G) is finally placed, Because it uses the (C) cross-linking (TB) while reducing the cost of construction and crane (C) there is a cost function that can be mounted to inexpensively girder (G) in the river or sea effects.

10: Alternating and piercing 12: Rail for lateral movement
14: Hydraulic jack reaction force band 16: Lateral hydraulic jack
18: Hydraulic device for lateral movement 20: Bogie for lateral movement
22: Stopper 24: Up and down hydraulic jack
26: transverse beam 28: girder arrangement
B: Bridge support C: Crane
E: Electronic control system G: Girder

Claims (3)

In a method for placing a girder (G) in an alternating and piercing angle (10)
(S I) of constructing said alternating and piercing angle (10) over a whole area;
Installing a transverse moving rail (12) on the upper surface of the alternating and piercing (10) (SII);
A transverse moving hydraulic device 18 and a transverse moving truck 20 constituted by a hydraulic jack reaction force band 14 and a transverse hydraulic jack 16 capable of being pushed out and press-fit are provided on the upper surface of one lateral side of the transverse moving rail 12 Installing step (S III);
(Iv) installing a stopper (22) on the upper surface of the other end of the lateral movement rail (12);
A step (S V) of installing a girder holding device (28) composed of a vertical hydraulic jack (24) and a transverse beam (26) on the upper surface of the alternating and piercing angle (10);
Installing a girder (G) as a crane (C) on the transverse moving bogie (20) (S VI);
Driving the hydraulic jack reaction force band 14 and the transverse hydraulic jack 16 to move the transverse moving bogie 20 (S VII);
The step of installing the hydraulic jack reaction force band 14 and the lateral hydraulic jack 16 on the upper surface of the transverse movement rail 12 and moving the girder G to a target seating point of the transverse movement rail 12 S VIII);
After the girder G is moved, the vertical hydraulic jack 24 of the girder holding device 28 is operated to support the girder G of the girder holding device 28, A step (SIX) of pulling the lateral side moving hydraulic device (18) to the side when the car (20) and the lateral moving hydraulic device (18) are girders (G);
Lowering the hydraulic jack 24 in the vertical direction of the girder unit 28 to place the girder G on the bridge support B (S X);
And a step (S XI) of alternately mounting the girder (G) in the transverse direction on the upper surface of the bridge pier (10) by repeating the steps (S V) to (S X). The method according to claim 1,
Characterized in that the transverse hydraulic jack (16) shifts the girder (G) mounted in the bridge and pierce (10) transversely by the electronic control system (E). The method according to claim 1,
Characterized in that the hydraulic jacks (24) of the girder elevator device (28) are alternately elevated and lowered by the electronic control system (E) and the girders (G) mounted on the bridgehead (10).

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