土木工程毕业设计外文翻译最终中英文

土木工程毕业设计外文翻译最终中英文

-CAL-FENGHAI-(2020YEAR-YICAI)_JINGBIAN

7 Rigid-Frame Structures

A rigid-frame high-rise structure typically comprises parallel or orthogonally arranged bents consisting of columns and girders with moment resistant joints. Resistance to horizontal loading is provided by the bending resistance of the columns, girders, and joints. The continuity of the frame also contributes to resisting gravity loading, by reducing the moments in the girders.

The advantages of a rigid frame are the simplicity and convenience of its rectangular unobstructed arrangement, clear of bracing members and structural walls, allows freedom internally for the layout and externally for the fenestration. Rigid frames are considered economical for buildings of up to' about 25 stories, above which their drift resistance is costly to control. If, however, a rigid frame is combined with shear walls or cores, the resulting structure is very much stiffer so that its height potential may extend up to 50 stories or more. A flat plate structure is very similar to a rigid frame, but with slabs replacing the girders As with a rigid frame, horizontal and vertical loadings are resisted in a flat plate structure by the flexural continuity between the vertical and horizontal components.

As highly redundant structures, rigid frames are designed initially on the basis of approximate analyses, after which more rigorous analyses and checks can be made. The procedure may typically include the following stages:

1. Estimation of gravity load forces in girders and columns by approximate method.

2. Preliminary estimate of member sizes based on gravity load forces with

arbitrary increase in sizes to allow for horizontal loading.

3. Approximate allocation of horizontal loading to bents and preliminary analysis

of member forces in bents.

4. Check on drift and adjustment of member sizes if necessary.

5. Check on strength of members for worst combination of gravity and horizontal

loading, and adjustment of member sizes if necessary.

6. Computer analysis of total structure for more accurate check on member

strengths and drift, with further adjustment of sizes where required. This stage may include the second-order P-Delta effects of gravity loading on the

member forces and drift..

7. Detailed design of members and connections.

This chapter considers methods of analysis for the deflections and forces for both gravity and horizontal loading. The methods are included in roughly the order of the design procedure, with approximate methods initially and computer techniques later. Stability analyses of rigid frames are discussed in Chapter 16.

RIGID FRAME BEHAVIOR

The horizontal stiffness of a rigid frame is governed mainly by the bending resistance of the girders, the columns, and their connections, and, in a tall frame, by the axial rigidity of the columns. The accumulated horizontal shear above any story of a rigid frame is resisted by shear in the columns of that story (Fig. . The shear causes the story-height columns to bend in double curvature with points of contraflexure at approximately mid-story-height levels. The moments applied to a joint from the columns above and below are resisted by the attached girders, which also bend in double curvature, with points of contraflexure at approximately mid-span. These deformations of the columns and girders allow racking of the frame and horizontal deflection in each story. The overall deflected shape of a rigid frame structure due to racking has a shear configuration with concavity upwind, a maximum inclination near the base, and a minimum inclination at the top, as shown in Fig. .

The overall moment of the external horizontal load is resisted in each story level by the couple resulting from the axial tensile and compressive forces in the columns on opposite sides of the structure (Fig. . The extension and shortening of the columns cause overall bending and associated horizontal displacements of the structure. Because of the cumulative rotation up the height, the story drift due to overall bending increases with height, while that due to racking tends to decrease.