JPH08144224A - Erection method of bridge - Google Patents

Abstract

PURPOSE: To cope with a short-sized erection girder, and to improve workability and profitability by devising the bearing and moving methods of an erection girder in the erection method of a bridge by a method of cantilever erection precast block construction. CONSTITUTION: Blocks 3 are built and joined left and right alternately or simultaneously by utilizing an erection girder 11, and projected gradually while giving prestress. Erection work during a single span is completed, and a front leg is retreated along the erection girder 11, and moved onto a bridge girder 2, which is built perfectly. The erection girder 11 is borne by a rear leg 34 and the front leg 32, and a launching leg 33 is moved up to the place of the front leg 32. The erection girder 11 is borne by the rear leg 34 and the launching leg 33, the erection girder is forwarded, and the front leg 32 is shifted up to a next built pier 1. The launching leg 33 is moved up to the upper section of the pier 1, on which the front leg 32 is fixed temporarily. The erection girder 11 is sent out second.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of a bridge erection method by a cantilever erection precast block construction method in which balance is centered around a bridge pier, and blocks are joined alternately at the same time or at the same time to project while prestressing. It is a thing.

[0002]

2. Description of the Related Art In the precast block method, a structure is manufactured by dividing it into a bridge axis direction or a direction perpendicular to the bridge axis at a factory or a manufacturing yard, and then the structure is carried into the erection site, and prestress is introduced to form an integrated structure. It is a construction method and is used for construction of bridges.

The following are some of the advantages of applying the precast block construction method to bridge construction.

Since the precast block can be manufactured and stocked during the construction of the substructure, the manufacturing process and the erection process can be set separately, and the construction period can be significantly shortened.

The production of the precast block is a repetitive operation in a factory or a production yard, and a structure having stable quality can be produced. Moreover, rationalization and labor saving can be achieved by performing mechanized construction.

By storing the blocks in the stockyard, drying shrinkage after installation and deformation due to creep are reduced.

From the above point of view, the precast block construction method is the construction method which is expected to be the most rapid construction and labor-saving construction in the field of PC bridge construction. The block erection is an advantageous construction method for large-scale bridge construction, assuming that the erection machine is large.

With respect to the introduction of prestress, there are many cases in which foreign cables are used in other countries, which improves workability and economy.

Further, as a typical erection method of the precast block construction method, it is manufactured in a factory or a yard.
The span-by-span construction method, in which blocks for spans are transported onto the erection girder, and after predetermined positioning, they are joined and erected one span at a time while prestressing, the balance is centered around the pier, There is a cantilever erection method in which blocks are alternately or simultaneously joined and overhanged while prestressing. The former is suitable for a PC girder bridge with a span of 40 to 60 m and the latter with a span of 60 to 100 m.

[0010]

In the cantilever precast block construction method, which is the subject of the present invention, there are several types of block erection methods. When an erection girder is used, it is usually used as a support leg. A erected girder with a front leg at the front, a launching leg at the middle, and a rear leg at the rear is used.

In this case, when the block is erected, the erection girder is supported by the rear leg fixed on the bridge girder that has been erected and the intermediate launching leg fixed on the upper part of the pier, which is pre-constructed in the construction direction. While balancing, use the erection girder to erection and join blocks at the same time, either left or right, or at the same time, and overhang while applying prestress.

Regarding the movement of the erection girder, 2
When using a erection girder with a length greater than the span, send out the erection girder when the erection of a single span is completed, and with the rear leg and front leg supporting the erection girder, the launching leg is the pier of the next erection with the front leg. Then, the front leg is sent out while the erection girder is supported by the rear leg and the launching leg.

However, since the conventional method accommodates a large span, the erection girder also becomes large and it is difficult to support and move it.

According to the present invention, in such a bridge erection method by the cantilever erection precast block method, by devising a method of supporting and moving the erection girder, a erection girder shorter than the conventional construction can be dealt with. It is intended to improve economic efficiency.

[0015]

SUMMARY OF THE INVENTION The present invention is an erection girder that uses an erection girder and includes a rear leg that is fixed on the bridge girder that has been erected and an intermediate launching leg that is fixed on the upper part of the pier that has been installed ahead in the construction direction. While maintaining balance around the bridge pier, using the erection girder, the blocks are erected, joined left and right alternately or simultaneously,
In the bridge erection method by the cantilever erection precast block method, which repeats the process of overhanging while applying prestress while sending out the erection girder for each single span, the erection girder is sent out in two steps. is there.

That is, after completion of the erection work of a single diameter, the front leg is retracted along the erection girder, moved to the bridge girder that has been erected, and the launching leg is erected with the rear leg and the front leg supporting the erection girder. Move along the girder near the front leg and secure it on the bridge girder,
With the rear leg and the launching leg supported, send the erection girder (first delivery), move the front leg to the upper part of the pier for the next erection and temporarily fix it, and then with the rear leg and front leg supporting the erection girder. Move the launching leg along the erection girder to the bridge pier where the front leg was temporarily fixed and fix it, and then move the erection girder to the predetermined position for the next erection while supporting the erection girder with the rear leg and the launching leg. It is characterized by (second delivery).

A roof device (canopy) is mounted on the erection girder.
By installing the above, not only can all-weather construction be possible, but the roof device can also be used for the purpose of curing the precast block. As such a roof device, for example, one in which rails are laid outside the erection girder and opened / closed in a bellows manner over the entire length of the construction span can be considered.

[0018]

EXAMPLES Next, the illustrated examples will be described. Note that the embodiment described below is merely an embodiment, and the present invention is not limited to the embodiment.

FIG. 1 shows an outline of the construction and mechanical construction in the cantilever erection precast block method using the erection girder to which the present invention is applied.

(1) The construction policy in this embodiment is as follows.

The construction span is about 60 to 100 m.

The weight of the block 3 alone is up to about 100 t.

The erection is performed by the erection girder 11 centering on the pier 1 while alternately or simultaneously joining the blocks 3
And erection.

The erection girder 11 includes the front leg 3
2. The three legs of the launching leg 33 and the rear leg 34 are used, and they are erected and moved for each single span by a hand girder system.

The erection girder 11 includes the front leg 3
2. It is supported by the three legs of the launching leg 33 and the rear leg 34, and is installed in parallel and in cross slope, longitudinal slope, and plane alignment.

The block 3 is a trailer 2 on the completed bridge girder 2 from the block manufacturing yard to the erection point.
4 In principle, it should be transported using an automated guided vehicle. It is also possible to use a temporary road up to the erection point and to erect directly from below the erection point with the club trolley 16 of the erection girder 11.

As for the construction of the column head, both cast-in-place and precast blocks can be constructed.

(2) The mechanical structure of this embodiment is as follows.

The erection girder 11 is composed of two girders and supports the erection block 3. The upper part of the erection girder 11 is used as a traveling path for the club trolley 16.

The club trolley 16 is a crane for hoisting the block 3 from the carrier and moving it to the erection position, which can travel and traverse in the bridge axis direction.

Front leg 32 The front leg of the erection girder 11 is used for feeding, height adjustment,
There is a function of lateral movement.

Launching leg 33 With the leg in the middle part of the erection girder 11, feeding, height adjustment,
There is a function of lateral movement.

The rear leg 34 is the last leg of the erection girder 11 and has the functions of height adjustment and lateral movement, and is equipped with a traveling device that travels on the girder 2 that has been erected.

Working scaffold 23 (working stage) It is a scaffold for positioning and joining work of the block 3 and is movable along the erection girder 11. The work scaffold 23 can be separated into left and right parts at the center, and can be moved in a separated state.

A support material for temporarily suspending the block 3 carried by the hanger club trolley 16 at a predetermined position.

(3) The erection work of the block 3 in this embodiment is performed as follows.

From the block manufacturing yard to the erection point, the block 3 transported by the trailer 24 or the automated guided vehicle on the bridge girder 2 that has been completely erected is lifted by the club trolley 16 of the erection girder 11, and the pier 1 from both sides
The block 3 is extended and erected while alternately or at the same time joining with each other.

At the erection point, the block 3 is turned, adjusted, and positioned by the club trolley 16 at predetermined intervals,
Temporarily fixed by a hanger.

In a state where the work scaffold 23 is temporarily fixed by a hanger, an adhesive is applied on the work scaffold 23 and the blocks 3 are pulled together and joined. After the tension of the block 3 is completed, the hanger is released to complete the erection of the block 3.

For the construction of the column head, both precast and in-situ construction methods can be adopted.

For the purpose of curing the precast block 3, a bellows type shed (moving on a rail laid outside the erection girder) is equipped over the entire construction span of the erection girder 11.

(4) The erection girder 11 in this embodiment is moved as follows.

The feeding of the erection girder 11 in one cycle of construction for a single diameter is carried out in two steps.

First, the front leg 32 is moved so as to be pulled back onto the block 3 which has been installed, and is temporarily supported on the bridge girder 2. The front leg 32 is fixed to the bridge girder 2 and is connected to the erection girder 11 via a feeding device. Further, the leg portion of the rear leg 34 serves as a girder traveling device (or a girder feeding device), and the erection girder 11 is supported at the upper part.

The support of the launching leg 33 is released (raised to a height that does not give rise to curling when moving), and the erection girder 11 is supported by the front leg 32 and the rear leg 34,
After feeding the launching leg 33 to the same position as the front leg 32 (The launching leg 33 can be moved to the position of the front leg 32 by itself with the attached feeding device, and consider the balance and workability of the erection girder 11. While sending), the launching leg 33 is temporarily fixed on the bridge girder 2.

The traveling girder mounted on the leg of the rear leg 34 is used to feed the erection girder 11 for the first time.
The erection girder 11 using the moving device provided at the joint between the launching leg 33 and the erection girder 11 as a guide.
Moves. When the front leg 32 supporting position at the tip of the erection girder 11 reaches the upper part of the pier 1 of the next next erection by sending out the erection girder 11, the front leg 3
2 is temporarily fixed on the pier 1.

Again, the support of the launching leg 33 is released, the erection girder 11 is supported by the front leg 32 and the rear leg 34, and the launching leg 33 is moved to the front leg 3.
Send it to the same position as 2 and fix the launching leg 33 on the pier.

The support of the front leg 32 is released, and the erection girder is fed out for the second time.

(5) Next, the construction procedure in this embodiment is
2 (a) to 2 (d) and 3 (e) to 3 (h).

Start of erection of the block 3 (see FIG. 2 (a)) The erection of the block 3 is alternately performed from both sides of the column head previously constructed. The block 3 is hoisted by the club trolley 16 mounted on the erection girder 11, and after being turned by 90 degrees, transported to the erection site for positioning and joining.

The left side portion in the figure is a portion where scaffolding is assembled and the bridge girder 2 is erected using a mobile crane or the like.

Construction and Joining of Block 3 (See FIG. 2B) The block 3 is positioned and adjusted by being lifted by the club trolley 16. Application of an adhesive, drawing using a drawing steel rod, and joining are performed on the work scaffold 23.

Laying of external cables and tension (see FIG. 2 (c)) After erection of the required number of blocks and completion of temporary tension, the filling concrete is applied. At the same time, after laying the outer cable, the outer cable is tensioned to complete the construction of the single span.

Preparation for moving the erection girder 11 (see FIG. 2
(See (d)) The front leg 32 is moved onto the block 3 on which the installation has been completed, is temporarily supported, and the launching leg 33 is attached to the front leg 32.
When moving to a nearby fulcrum, fix it on the bridge girder 2. At this time, the club trolley 16 is fixed and the work scaffold 23 is prepared for movement.

Sending out the erection girder 11 (see FIG.
(Refer to (e)) The erection girder 11 is sent out using the traveling device equipped on the leg of the rear leg 34. The erection girder 11 is moved by using a moving device provided at a connecting portion between the launching leg 33 and the erection girder 11 as a guide. The front leg 32 is temporarily fixed onto the pier 1 when the front leg 32 support position at the tip of the erection girder 11 reaches the upper part of the pier 1 of the next next erection by sending out the erection girder 11.

Fixing the launching leg 33 (FIG. 3 (f)
(See) After temporarily fixing the front leg 32, the front leg 32,
The erection girder 11 is supported by the rear leg 34, the launching leg 33 is released, the moving device mounted on the launching leg 33 is driven, and the launching leg 33 is reached up to the destination pier 1.
Move, position and fix. The reference block on the pier 1 is installed by the mobile crane 13 in advance.

Removing the erection girder 11 (Fig. 3 (g)
With reference to the launching leg 33 as a support point and a guide at the time of movement, the traveling device of the rear leg 34 is driven to move the erection girder 11 again. After moving the erection girder 11 to the fulcrum fixing position of the rear leg 34, the positioning of the launching leg 33 and the rear leg 34 is adjusted and then fixed.

Completion of movement of the erection girder 11 (preparation for block erection) (see FIG. 3 (h)) After the movement of the erection girder 11 is completed, the parts of the erection girder 11 are inspected and the surroundings of the fixed part are reconfirmed to make sure that the position is correct Make sure it is installed. Club trolley 16,
The work scaffold 23 is moved to a predetermined position, and the block 3 is prepared for installation.

[0059]

According to the invention of the present application, the length of the erection girder can be increased by moving the erection girder in two steps while relocating and moving the fulcrum by the front leg, the launching leg, and the rear leg when the erection girder is sent out. Can be substantially suppressed to 2 or less.

That is, since the bridge erection work can be performed with the erection girder shorter than before, not only the length of the erection girder is shortened, but also the self-weight and the moment acting on the erection girder are reduced. The cross-sectional size of the erection girder can be reduced, the weight of the erection girder can be further reduced, and the stress of each part related to the support of the erection girder can be reduced. As a result, the workability and economy can be greatly improved.

The above-mentioned effect is great especially in the construction of a bridge having a large span.

[Brief description of drawings]

FIG. 1 shows an outline of a cantilever erection precast block construction method which is the subject of the present invention. (A) is a side view of a bridge being erected, (b) is a sectional view taken along line AA, (c) Is a sectional view taken along line BB, and (d) is a sectional view taken along line CC.

2 (a) to 2 (d) are side views showing a construction procedure in one embodiment of a cantilever erection precast block construction method which is an object of the present invention.

3 (e) to (h) are side views showing a construction procedure following FIG. 2 (d).

[Explanation of symbols]

1 ... Bridge pier, 2 ... Bridge girder, 3 ... Block, 11 ... Erection girder, 16 ... Club trolley, 23 ... Work scaffolding, 24 ... Trailer, 32 ... Front leg, 33 ... Launching leg, 34 ... Rear leg

Claims (2)

[Claims] 1. A front leg of a front portion as a supporting leg,
Using the erection girder that has the launching leg in the middle part and the rear leg in the rearmost part, the above-mentioned erection with the rear leg fixed on the bridge girder that has been erected and the intermediate launching leg fixed on the upper part of the bridge pier that was constructed ahead in the construction direction. While supporting the girder and balancing around the bridge pier, using the erection girder, the blocks are erected and joined alternately left and right or at the same time, and the process of overhanging with prestressing is carried out for each single span girder. In the bridge erection method using the cantilever precast block method, the front leg is retracted along the erection girder after the erection work of a single span is completed, and the rear leg and front leg are moved. Support the erection girder with the launching leg along the erection girder. Move to the vicinity of the bridge and fix it on the bridge girder, send out the erection girder while being supported by the rear leg and the launching leg, move the front leg to the upper part of the pier for the next erection and temporarily fix it, and then erect it with the rear leg and front leg. While supporting the girder, move the launching leg along the erection girder to the bridge pier where the front leg was temporarily fixed and fix it, and then, while supporting the erection girder with the rear leg and the launching leg, for the next erection A method of constructing a bridge, characterized by moving the bridge to a predetermined position. 2. A front leg and a launching leg are connected to the erection girder via respective delivery devices for moving the erection girder in the longitudinal direction, and a traveling device or a delivery device for moving on the bridge girder to the lower part of the rear leg. The method of constructing a bridge according to claim 1, wherein a device is provided.