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1993 | Buch

Isolation for Earthquake Resistance Kapitel lesen Erstes Kapitel lesen

Earthquake-Resistant Design with Rubber

verfasst von: James Marshall Kelly, PhD, BSc, MSc

Verlag: Springer London

Enthalten in: Professional Book Archive

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Über dieses Buch

My involvement in the use of natural rubber as a method for the protec­ 1976. At that time, tion of buildings against earthquake attack began in I was working on the development of energy-dissipating devices for the same purpose and had developed and tested a device that was even­ tually used in a stepping-bridge structure, this being a form of partial isolation. It became clear to me that in order to use these energy devices for the earthquake protection of buildings, it would be best to combine them with an isolation system which would give them the large displace­ ments needed to develop sufficient hysteresis. At this appropriate point in time, I was approached by Dr. C. J. Derham, then of the Malaysian Rubber Producers' Research Association (MRPRA), who asked if I was interested in looking at the possibility of conducting shaking table tests at the Earthquake Simulator Laboratory to see to what extent natural rubber bearings could be used to protect buildings from earthquakes. Very soon after this meeting, we were able to do such a test using a 20-ton model and hand-made isolators. The eady tests were very promising. Accordingly, a further set of tests was done with a more realistic five­ storey model weighing 40 tons with bearings that were commercially made. In both of the test series, the isolators were used both alone and with a number of different types of energy-dissipating devices to en­ hance damping.

Inhaltsverzeichnis

Frontmatter
Chapter 1. Isolation for Earthquake Resistance
Abstract
The idea that a building can be protected from the damaging effects of an earthquake by using some type of support that uncouples it from the ground is an appealing one, and many mechanisms to produce this result have been proposed during the last hundred years. Many of these utilized rollers or layers of sand or similar materials that would allow a building to slide. Some examples of these have been built. A building in Savastopol, Ukraine and a five-storey school in Mexico have been built on rollers and there is at least one building in China with a sand layer between the foundation and the building, specifically intended to let it slide in an earthquake.
James Marshall Kelly
Chapter 2. Vibration Isolation
Abstract
The theory of seismic isolation has many features in common with the better known theory of vibration isolation, but there are some distinct differences between them; these are mainly associated with the degree to which the vibrational disturbance is known and the amplitude of the displacements in the support system.
James Marshall Kelly
Chapter 3. Seismic Isolation
Abstract
Vibration isolation is a very highly developed technical area that has many elements in common with seismic isolation. However, seismic isolation differs from vibration isolation in several ways. The flexibility of the isolated structure must be taken into account and there will be a base slab of some sort on which the building is mounted, the mass of which must be included in the model. In vibration isolation we are concerned with protection against a specified range of frequencies, and displacements in the mounting system are generally negligible. In seismic isolation the input against which the protection is sought is much less well-prescribed, and displacements of the isolation system can be very large.
James Marshall Kelly
Chapter 4. Extension of Theory to Buildings
Abstract
The two-degree-of-freedom analysis of the simple linear model developed in the previous chapter can be applied to the case of a building with several stories. Let us represent the structural system of this building by a mass matrix, M, a damping matrix, C, and stiffness matrix, K.
James Marshall Kelly
Chapter 5. Code Requirements for Isolated Buildings
Abstract
The first building in the USA to use a seismic isolation system was completed in 1985 and was publicized in national engineering magazines and visited by a great many engineers and architects from the USA and around the world. However, it was several years before the second base-isolated building was begun. The acceptance of isolation as an anti-seismic design approach for some classes of buildings has clearly been inhibited in the USA by lack of a code covering base-isolated structures. It was recognized quite early that it was necessary to add isolation design requirements to the existing structural codes and, accordingly, the Structural Engineers Association of Northern California (SEAONC) created a working group in 1980 to develop design guidelines for isolated buildings. A brief document was produced and became the starting point for a sub-committee of the SEAONC Seismology Committee that was formed in early 1985.
James Marshall Kelly
Chapter 6. Coupled Lateral-Torsional Response of Base-Isolated Buildings
Abstract
It is an unusual characteristic of a base-isolated building that its frequencies in lateral, longitudinal and torsional motion are very nearly the same. The fact that the lateral and longitudinal frequencies are the same is clear from the isotropic response of the isolators and their coincidence with the torsional frequency occurs if the isolator stiffness is matched to the carried load. This raises the possibility of a coupling between the three lowest modes if there is an imbalance between the center of mass and the center of rigidity.
James Marshall Kelly
Chapter 7. Behavior of Multilayer Bearings Under Compression and Bending
Abstract
The vertical frequency of an isolated structure can often be an important design criterion and this is controlled by the vertical stiffness of the bearings that comprise the system. To predict the vertical frequency it is the vertical stiffness under a specified dead load that is needed, and for this a linear analysis is adequate. The initial response of a bearing under vertical load depends on several factors and is very non-linear. Bearings usually have a substantial run-in before the full vertical stiffness is developed, and this run-in is generally accepted to be strongly influenced by the alignment of the reinforcing shims and other aspects of the workmanship in the molding process. This run-in cannot be predicted by analysis but is generally of little importance in predicting the vertical response.
James Marshall Kelly
Chapter 8. Buckling Behavior of Elastomeric Bearings
Abstract
A multilayer elastomeric bearing can be susceptible to a buckling type of instability similar to that of an ordinary column, but dominated by the low-shear stiffness of a bearing. The previous analysis of the overall deformation of a single pad can be used in a buckling analysis that treats the bearing as a continuous composite system. In this analysis, the bearing is considered to be a beam and the deformation is assumed to be such that plane sections normal to the undeformed central axis remain plane but not necessarily normal to the deformed axis.
James Marshall Kelly
Chapter 9. Design Process for Multilayer Elastomeric Bearings
Abstract
The design process for elastomeric bridge bearings is governed by a number of code specifications that reflect the fact that the loads to which the bearings are subjected are well defined and happen on a regular basis. If these provisions were to be applied to elastomeric bearings for isolation, they would result in unnecessarily conservative designs. In the design of seismic isolation bearings for buildings, it has to be recognized that codes such as the UBC 1991 require the isolation system to be designed for very severe seismic loading, that this loading may be interpreted as ultimate state loading and that the isolators should be designed to reflect this; conservatism is already incorporated in the specified site seismicity and need not be further increased by over-conservative design of the isolators and, further, the extreme loads to which the isolator may be subjected will occur, if at all, no more than once or twice over the lifetime of the structure.
James Marshall Kelly
Backmatter
Metadaten
Titel
Earthquake-Resistant Design with Rubber
verfasst von
James Marshall Kelly, PhD, BSc, MSc
Copyright-Jahr
1993
Verlag
Springer London
Electronic ISBN
978-1-4471-3359-9
Print ISBN
978-1-4471-3361-2
DOI
https://doi.org/10.1007/978-1-4471-3359-9