JPH0417264B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a filled steel pipe concrete structure used for, for example, columns and piles of building structures.

"Prior Art" The applicant previously provided an unbonded type filled steel pipe concrete structure (Japanese Patent Application No. 42979/1986).

In this unbonded type filled steel pipe concrete structure, an unbonded layer is formed by applying a separation material such as paraffin, grease, asphalt, etc. to the inner surface of the steel pipe in advance, and concrete is filled in the unbonded layer.

Therefore, according to the unbonded filled steel pipe concrete structure, the steel pipe and the internal concrete are separated and behave as separate bodies. That is,
Even if the concrete is distorted in the axial direction, the steel pipe will not be compressed accordingly. Furthermore, when the concrete is compressed and its strength exceeds a predetermined strength, the concrete undergoes axial strain as well as rapid radial transverse strain. However, since almost no stress in the axial direction is generated in the steel pipe, only the ring tension acting as a reaction that gives a confining effect acts on the steel pipe. Therefore,
By applying the Mises yield condition, the confining effect of the steel pipe due to circumferential stress can be fully exhibited, and as a result, the strength against compressive loads can be significantly improved, and the cross-sectional area can be reduced.

``Problems to be Solved by the Invention'' However, in the conventional unbonded treatment layer, paraffin, grease, asphalt, etc. are provided between the steel pipe and the concrete as separating materials, so they are susceptible to damage caused by aging or fire. There was a problem that it was undesirable as a main structural member of a structure expected to be semi-permanent because it could be affected by thermal deterioration.

The present invention was made in view of the above problems, and
The purpose of the present invention is to provide a method for manufacturing an unbonded layer in a filled steel pipe concrete structure that is not affected by aging or thermal deterioration due to fire.

"Means for Solving the Problems" In order to solve the above problems, the present invention provides an active layer containing a lime decomposing agent inside a steel pipe, and then pours concrete into the steel pipe. The method is characterized in that the steel pipe surface side of the concrete is decomposed to a certain thickness using the lime decomposing agent to form an unbonded layer.

``Operation'' When concrete is placed inside a steel pipe, the active layer containing a lime decomposer provided inside the steel pipe decomposes the lime on the surface of the poured concrete by a short reaction, causing the concrete to decompose. An unbonding layer is formed by changing the surface to a non-strength material by a small amount required for unbonding.

``Example'' Figures 1 and 2 show examples of the present invention, and in the figures, reference numeral A indicates a column of unbonded type filled steel pipe concrete structure (hereinafter simply referred to as "column"). be. The column A is composed of a steel pipe 1, concrete 2 filled inside the steel pipe 1, and an unbonding layer 3 provided at the interface between the steel pipe 1 and the concrete 2. Note that a space 4 for grouting when connecting the steel pipe 1 to another steel pipe may be provided at the end of the steel pipe 1.

The method for producing the unbonded layer 3 is to provide an active layer containing a certain amount of lime-decomposing agent inside the steel pipe 1, and then pouring the concrete 2 into the active layer, which allows the concrete 2 to become a lime-decomposing agent for a short period of time. A method is adopted in which the lime content on the surface of the steel pipe side of the concrete 2 is decomposed by a small amount and transformed into a non-strength substance.

The lime decomposing agent used in this example is a type of chelating agent, and is a polymeric compound consisting of water-soluble esters. When oxygen is added to limestone, the reaction is accelerated and it becomes a gas.
It has the effect of decomposing the calcareous material of concrete 2 and turning it into fine powder of lime.

Therefore, in the column A, the steel pipe 1 and the concrete 2 inside are separated by the unbonding layer 3 and behave as separate bodies. That is, even if the concrete 2 is distorted in the axial direction, the steel pipe 1 will not be compressed accordingly. Further, when the concrete 2 is compressed and its strength exceeds a predetermined strength, the concrete 2 undergoes axial strain and sudden transverse strain in the radial direction. However, since almost no stress in the axial direction is generated in the steel pipe 1, only the ring tension acting as a reaction that gives a confining effect acts on the steel pipe 1. Therefore, by applying the Mises yield condition, the confining effect of the steel pipe 1 due to circumferential stress can be fully exhibited, and as a result, the strength against compressive loads can be significantly improved, and the cross-sectional area can be reduced. . Furthermore, since the unbonded layer 3 is formed by decomposing the calcareous material on the surface of the concrete 2 to a small size and turning it into fine lime powder, it is not affected by aging or thermal deterioration due to fire. It is possible to reliably maintain the unbonded state between the steel pipe 1 and the concrete 2 without any problems.

Next, a method for providing an active layer containing a lime decomposing agent inside the steel pipe 1 in order to form the unbonded layer 3 will be specifically described.

First, since the lime decomposing agent is a liquid, the first method is to apply it to the inside of the steel pipe 1 in a constant thickness (film state) to form an active layer. As an example, the circular force method is suitable.

Next, the second method is to make the inner surface of the steel pipe 1 porous with a certain thickness and impregnate it with the lime decomposer to provide an active layer, since the steel pipe 1 does not react with the lime decomposer.

Furthermore, as a third method, there is a method of providing an active layer by impregnating an impregnating material with a lime decomposing agent and pasting it on the inside of the steel pipe 1.

In addition, in consideration of the fact that a considerable amount of time is required between the provision of an active layer containing a lime-decomposing agent in the steel pipe and the placing of concrete inside the steel pipe, a binder is added in addition to the lime-decomposing agent in the active layer. Materials may be provided.

By the method described above, the active layer provided inside the steel pipe 1 reacts with the concrete 2 placed inside the steel pipe 1 for a short period of time, decomposing the calcareous material on the surface of the concrete 2 on the steel pipe side, and converting it into lime. By making it a fine powder, an unbonded layer 3 is formed between the steel pipe 1 and the concrete 2.

Note that it is optional to insert reinforcing bars into the concrete 2 of column A or to arrange prestressed steel to increase the strength of the concrete.

"Effects of the Invention" As explained above, the present invention provides an active layer containing a lime decomposing agent inside a steel pipe, then pours concrete into the steel pipe, and removes the lime content on the surface of the poured concrete. The unbonded layer is formed by decomposing the concrete by reacting with the lime decomposing agent for a short period of time, changing the concrete surface into a non-strength material by a small amount required for unbonding, so it is resistant to thermal deterioration due to aging or fire. It is possible to form an unbond layer that is not affected by the above conditions.

[Brief explanation of drawings]

Figures 1 and 2 show an embodiment of the present invention. Figure 1 is a side sectional view of an unbonded filled steel pipe concrete structure, and Figure 2 is a sectional view taken along line XX in Figure 1. . A... Unbonded type filled steel pipe concrete structure, 1... Steel pipe, 2... Concrete, 3... Unbonded treatment layer.

Claims (1)

[Claims] 1. In a filled steel pipe concrete structure in which a steel pipe is filled with concrete, an active layer containing a lime decomposing agent is provided inside the steel pipe, and then concrete is placed inside the steel pipe, and the surface side of the steel pipe of the poured concrete is covered with the lime. A method for producing an unbonded layer in a filled steel pipe concrete structure, characterized by forming an unbonded layer by decomposing a certain thickness with a decomposing agent.