Time period for buildings with structural walls as per IS 1893 (Part 1):2016
I have received many queries related to time period calculations for buildings with shear wall in accordance with cl no. 7.6.2 of IS 1893 (Part 1) : 2016. Time period is very sensitive parameter with respect to earthquake resistant design. In the article, I have shared my understanding related to the clause for further comments/suggestions.
Background:
In the IS 1893 (Part 1):2016, empirical formula for calculation of time period is defined in cl no. 7.6.2. In the clause, formulae are defined for three different types of structural systems:
(only part details are shown in the below content. Please refer the code for complete details).
a) Bare MRF buildings (without any masonry infills)
· RC MRF buildings
· RC-Steel composite MRF building
· For steel MRF building
b) Buildings with RC structural walls
c) All other buildings
For buildings with RC structural walls, the following formula was included in the code when it was published:
Wherein Aw can be calculated using the following formula,
Thereafter, the amendment no. 1 was released in 2017 and in the amendment, the above mentioned formula for Aw was updated as under:
Opinion of the engineers :
I believe that the majority of engineers are of the opinion that the earlier formula which was mentioned in IS 1893 (Part 1):2016 was correct and there is error in the revised formula (amendment no. 1).
My observations on the formula for time period:
1) In case of open storey, as per cl no. 7.10.4 of the code, when the RC structural walls are provided, the RC structural wall plan density of the building shall be at least 2 percent along each principal direction in seismic zones III, IV and V. RC structural walls of this measure can be adopted even in regular buildings that do not have open storey(s).
2) As per cl. no. 7.6.2, the time period for buildings with structural walls need not be less than 0.09*h/SQRT (d). Based on few worked out examples, I observed that the time period derived from earlier Aw formula of the code along with 2% of shear wall in each principal direction was generally near to 0.09*h/SQRT (d).
However, with the amendment formula of Aw, the time period considering 2% of shear wall, was significantly higher than the time period which is derived from 0.09*h/SQRT (d).
With this anomaly, I believe that the majority of engineers are of the opinion that the earlier formula of Aw was appropriate.
3) In my opinion, the structures with RC structural walls (shear walls) will be the most rigid one as compared to the Bare MRF buildings and the other buildings, as defined in cl no. 7.6.2. I think the upper limit of time period for buildings with RC structural walls may be defined as 0.09*h/SQRT (d). The upper cap limit may be defined or altered for range of height of the building.
4) I think that the more examples may be worked out for checking appropriateness of the above mentioned formulas.
Live Technical Discussion on next Sunday ( 11-Oct-20 at 11:00am):
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I have shared my views on the subject. Your valuable comments/suggestions are welcome for further improvement in this article. The suggested points may be taken up during the live technical discussion of 11-Oct-20 at 11:00am.
Structural Engineer.
4 年Thanks for sharing your insight. To be precise the cited formula relates Building’s height with the Fundamental time period, which is indeed a consistent methodology across many a country specific codes [ASCE, NBC just to name a few]. Apart from the above, fundamental period of vibration can also semi-empirically estimated with due diligence on Number of Stories [0.1*N]. * In reality for a cost-effective earthquake resistant structural design, not only height of the building/number of stories [not to be addressed simultaneously] but also several other parameters [for instance soil parameters, storey wise Load distribution, storey height etc] play pivotal role, which principally drives the Force Estimation. * The difference in time period from structure to structure should be best evaluated by performing an Eigen Solution with due emphasis on the appropriate mass matrix and stiffness matrix, as well as modal participation factor. The best part of Eigen Value analysis is that :- it provides a fairly accurate estimate of time period at the same time eradicates the misnomer Fundamental period of vibrations varies from code to code. Hope I am making sense. With vast Respect.
In fact when the code first came there was a formula: T = 0.1 N where N is the no of stories. Interestingly this simple formula gives much better results
I think there was another amendment saying that the earlier formula is correct
Engineer-Civil /Structural at Maxpro Engineers Pvt. Ltd.
4 年Nice topic Mr Bhavin.