JP2007303166A - Caisson method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a caisson method which enables more economical construction. <P>SOLUTION: A diameter-reduced portion 11, the inside-diameter dimension of which is decreased upward, is provided in the cutting edge portion 1 of a caisson A, and a diameter-enlarged portion 12, the inside-diameter dimension of which is increased upward, is provided above the diameter-reduced portion 11. The caisson A is sunk while the inside of the caisson A is excavated. After that, batholith concrete 7 is placed until the diameter-enlarged portion 12 is at least partially buried. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a caisson method, and more particularly, to a caisson method suitable for setting an open caisson.

  At the time of construction by the open caisson method, a blade-shaped blade opening is provided at the lower end of the caisson box. This blade edge mainly cuts the surrounding soil when sinking the caisson box so that the caisson box can sink smoothly, and prevents the caisson box from falling unexpectedly. It has a role to support the load of the body.

As the caisson method, a so-called segment method is known in which a steel split ring obtained by dividing a box in the circumferential direction is manufactured in a factory or the like, and the split ring is connected on site to form a cylindrical side wall. As shown in FIG. 4, the edge portion in this segment construction method includes an outer plate 32 welded to the outside of the skin plate 31 of the split ring and an inner plate 34 welded to the lower main girder 33. Known (for example, Patent Document 1). The outer plate 32 and the inner plate 34 have their tips abutted and joined by welding.
JP-A-9-59994

  When excavating the inner ground of the caisson box, the excavation ground exists in the vicinity of the blade edge, so that an excavator such as a clamshell may collide with the side wall inner surface 35 immediately above the blade edge and damage the box. There is. In particular, in the above-mentioned segment construction method, the strength and rigidity of the split ring are reduced, so that when the excavator collides with the split ring, the degree of damage to the split ring becomes enormous.

  In order to prevent such inconvenience, a steel plate is usually attached to the entire inner surface 35 of the box directly above the blade edge, and the inner surface of the side wall due to the collision with the excavator is prevented with this steel plate.

  By the way, when the bottom plate is constructed by placing concrete on the bottom of the box after caisson installation, the concrete placement height is usually the area protected by the protective steel plate inside the wall body beyond the blade edge. Reach up to. In this case, since the surface of the protective steel plate is smooth, the adhesion with the bottom base concrete is lowered, and the durability against lifting pressure may be insufficient. In order to ensure adhesion, the bottom concrete thickness must be increased, which is uneconomical. In addition, the cost is increased by the amount of use of the protective steel plate.

  Then, this invention aims at provision of the caisson method which can be constructed more economically.

  In order to achieve the above object, in the present invention, in the blade portion, a reduced diameter portion whose inner diameter dimension is reduced toward the upper side, and an enlarged diameter portion which is above the reduced diameter portion and whose inner diameter dimension is increased toward the upper side, The caisson box provided with is sunk while excavating the inside thereof, and then the bottom base concrete is placed until at least a part of the expanded diameter portion is filled.

  In this way, if the bottom base concrete is placed until the reduced diameter portion and the enlarged diameter portion are provided in the blade end portion and at least a part of the enlarged diameter portion is filled, the edge portion in both the upper and lower directions after the placement of the bottom base concrete. And the bottom plate engage. Therefore, the coupling force of the bottom board with respect to the box can be increased. Thereby, the amount of placing concrete can be reduced and the bottom board thickness can be reduced, and more economical construction is possible.

  Moreover, in this invention, since the enlarged diameter part is formed on the reduced diameter part, the full length of a blade edge part can be increased rather than before. In this case, the collision with the excavator will occur at the blade edge, but in general, the blade edge is configured with a higher strength than the side wall, so there is no need to protect it with a protective steel plate, Therefore, the protective steel plate that is essential in the conventional construction method becomes unnecessary. Moreover, the full length of a side wall can be shortened by the extension of a blade edge part.

  As described above, according to the present invention, since a high coupling force can be obtained between the bottom plate of the box and the blade edge portion, the bottom plate can be thinned. In addition, a protective steel plate to be attached to the inner surface of the side wall immediately above the blade opening is not required. From the above, the construction cost can be reduced.

  Hereinafter, the case where the caisson method according to the present invention is applied to an open caisson will be described as an example.

  FIG. 1 is an enlarged longitudinal sectional view showing a lower part of a caisson box A according to the present invention. The box A includes a blade edge portion 1 and a side wall 2 formed in a cylindrical shape, for example, above the blade edge portion 1. In the illustrated example, the side wall 2 is formed by a segment method. That is, in a plan view, the cylindrical side wall 2 is constructed by joining the partial arc-shaped steel dividing rings 2a in the circumferential direction into a cylindrical shape, and further stacking them in the axial direction and joining them together. Is done. The blade edge part 1 and the side wall 2 can also be formed in a rectangular tube shape or an elliptical tube shape. In addition, the side wall 2 can also be formed with a reinforced concrete other than forming with the aggregate | assembly of the steel division | segmentation rings 2a as mentioned above.

  The blade edge portion 1 is provided with a reduced diameter portion 11 whose inner diameter dimension is gradually reduced toward the upper side, and a diameter-expanded portion 12 which is disposed above the reduced diameter portion 11 and whose inner diameter dimension is gradually increased toward the upper side. Both the inner surface 11a of the reduced diameter portion 11 and the inner surface 12a of the enlarged diameter portion 12 are formed in a tapered surface shape. The reduced diameter portion 11 and the enlarged diameter portion 12 are integrally formed of concrete, and the outer surfaces thereof are flush with each other. Moreover, these outer surfaces and the outer surface of the side wall 2 are also substantially the same. In the blade edge portion 1, the boundary portion between the reduced diameter portion 11 and the enlarged diameter portion 12 is the maximum thickness of the blade edge portion, and this thickness is larger than the wall thickness of the side wall 2. The boundary portion between the inner surface 11 a of the reduced diameter portion 11 and the inner surface 12 a of the expanded diameter portion 12 is on the inner diameter side of the inner surface of the side wall 2. It is desirable that reinforcing bars are appropriately disposed in the concrete of the blade edge portion 1.

  In the illustrated example, the inner surface 11a of the reduced diameter portion 11 is configured by two tapered surfaces having different inclination angles, and the inner surface 12a of the expanded diameter portion 12 is configured by one tapered surface, but any of the surfaces 11a and 12a The number of taper surfaces can be arbitrarily determined according to construction conditions and the like. For example, the inner surface 11a of the reduced diameter portion 11 can be configured by one taper surface. In FIG. 1, the inner diameters 11 a and 12 a of the reduced diameter portion 11 and the enlarged diameter portion 12 are continuous, but other forms of surfaces such as a cylindrical surface straight in the height direction are interposed between the both surfaces 11 a and 12 a. You may let them.

  In the blade edge portion 1 of the present embodiment, from the boundary portion between the reduced diameter portion 11 and the enlarged diameter portion 12 to the upper surface of the blade edge portion 1 through the inner surface 11a of the reduced diameter portion 11 and the lower end of the blade edge portion 1. The entire region is covered with the steel plate 14. The inner surface 12a of the enlarged diameter portion 12 is not covered with the steel plate 14, and the concrete is exposed. A friction cutter 13 made of a steel plate is attached to the lower end of the outer surface of the blade edge portion 1 covered with the steel plate 14. The friction cutter 13 can be omitted depending on the geology of the subsidence ground.

  The shape and structure of the blade edge portion 1 are arbitrary as long as the diameter-reduced portion 11 and the diameter-increased portion 12 are included, and for example, the blade mouth portion 1 including the friction cutter 13 can be integrally formed with concrete or the like. As the friction cutter 13, a straight cutter as shown in FIG. 1 or a taper cutter can be adopted.

  The caisson box A according to the present invention can be set up according to the following procedure employed in a normal caisson method.

  First, the blade edge portion 1 is built on the ground, and a plurality of split rings 2 a are connected in the circumferential direction to fix the cylindrical first-stage side wall 2 to the upper end of the blade edge portion 1. As shown in FIG. 1, by slightly embedding the lower end of the side wall 2 in the upper end of the blade edge portion 1, the side wall 2 and the blade edge portion 1 can be firmly connected. Next, a pressure girder is placed on the side wall 2 and, for example, center hole type press-fitting jacks having earth anchors are attached to a plurality of locations on the pressure girder. In this state, while pressing the earth and sand at the bottom of the box with an appropriate excavator, the press-in jack is operated, the pressure input is transmitted to the blade edge part 1 through the side wall 2, and the box A is pressed into the ground. .

  Next, the pressure girder 4 and the press-fitting jack 5 are removed, and the second-stage side wall 2 is stacked on the first-stage side wall 2, and then the press-fitting girder and the press-fitting jack are reset and press-fitting is performed. . Thereafter, this operation is repeated, and the box A is laid down to a predetermined depth as shown in FIG. In addition, the box A may be press-fitted after the entire side wall 2 is preliminarily constructed on the blade portion 1.

  Thereafter, concrete (underwater concrete) is placed on the bottom of the box to construct the bottom board 7.

  If the entire blade edge part 1 is embedded in the concrete of the bottom board 7 during the placement of the bottom board concrete, the bottom board 7 is located with respect to the blade edge part 1 due to the presence of the reduced diameter part 11 and the enlarged diameter part 12 having different inclination directions. Engage in the vertical direction. Therefore, the strength of the bottom board 7 can be increased, and the concrete thickness can be reduced. In FIG. 2, a case where the concrete placement height T (planned placement height: see FIG. 1) is made to coincide with the upper end of the blade edge portion 1 is illustrated, but the same effect is at least the diameter-expanded portion 12. Can be obtained if a part of is embedded in the concrete of the bottom board 7. Therefore, as long as this condition is satisfied, it is possible to shift the concrete placement height T on the bottom board up and down from the example shown in FIG.

  Further, by providing not only the reduced diameter portion 11 but also the enlarged diameter portion 12 in the blade edge portion 1, the length of the blade edge portion 1 can be increased as compared with the conventional method. Thereby, since the distance from the excavation ground to the upper end of the blade edge part 1 increases, the protective steel plate which protects the inner surface of the split ring 2a just above the blade edge part 1 becomes unnecessary. On the other hand, since the blade edge portion 1 has an RC (or SRC) structure and has high strength, it is not necessary to protect it with a protective steel plate. Therefore, the use amount of the protective steel plate can be reduced or completely eliminated in the entire caisson box A, and the construction cost can be reduced. Furthermore, by extending the length of the blade edge portion 1, the split ring 2a is not required by the extension, so that an increase in construction cost can be suppressed. When the excavator is suspended, there is a possibility that the excavator collides with the enlarged diameter portion 12 of the blade portion 1. The excavator that collided is pushed inward by the taper surface 12a, so that the excavator is securely attached to the excavation ground. Can be reached.

  In addition, in order to increase the adhesive force of the blade edge part 1 and the bottom board 7, as shown in FIG. 3, especially the inner surface 12a (in the range of the concrete placement height T) of the enlarged diameter part 12 among the blade edge parts 1. Further, the convex portion 16 or the concave portion 17 (or both of them) can be provided.

It is a longitudinal cross-sectional view which shows the blade opening part of the caisson box concerning this invention. It is a longitudinal cross-sectional view which shows the caisson box which was laid. It is a longitudinal cross-sectional view which expands and shows a blade edge part. It is a perspective view which illustrates the conventional case box.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Blade edge part 2 Side wall 2a Split ring 11 Reduced diameter part 11a Inner surface 12 Expanded diameter part 12a Inner surface 13 Friction cutter 16 Convex part 17 Concave part

Claims (1)

  A caisson box provided with a reduced diameter portion whose inner diameter is reduced toward the upper edge and an enlarged diameter portion which is located above the reduced diameter portion and whose inner diameter is increased toward the upper portion. A caisson method characterized by laying while excavating, and then pouring bottom base concrete until at least a portion of the expanded portion is filled.

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