Design of floors for vibration quiz

From SteelConstruction.info
Revision as of 12:11, 12 March 2019 by Chris.dolling@steelconstruction.org (talk | contribs) (Created page with "Please answer the following 10 multiple choice questions, then click 'submit' to check the result. The pass mark for a CPD certificate is 8 out of 10, and you may retake the quiz...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

Please answer the following 10 multiple choice questions, then click 'submit' to check the result. The pass mark for a CPD certificate is 8 out of 10, and you may retake the quiz as many times as you wish, but the questions will vary! Please note that one, two, three or all of the possible answers presented for each question may be right, and to gain a mark for that question all correct answers must be identified.

Good luck

Design of floors for vibration

Which of the following statements is incorrect?

If the beams of a floor have a natural frequency of 4Hz or higher, then the floor performance is satisfactory for vibration
The frequency of the system (composed of primary and secondary beams plus slab) should be higher than 3Hz
Both primary and secondary beam mode shapes should be investigated and the mode which gives the higher deflection is more critical
If component frequencies are known then Dunkerley’s equation may be used to calculate the frequency of the system

Which of the following statements is incorrect? Human perception to vibration:

Depends on the frequency of the vibration
Depends on the direction of vibration relative to the spine
Is higher for intermittent vibrations
Is higher with vibrations having a frequency between of 4 and 8 Hz

The response factor of a floor is:

The peak acceleration of the floor
The peak acceleration of the floor divided by the base value
The root mean square (rms) acceleration of the floor
The rms acceleration of the floor divided by the base value (0.005 for z-axis vibrations)

Which of the following statements are true?

The response factors or multiplying factors given in BS 6472 are “for a low probability of adverse comment”
Multiplying factors are for exposure to continuous vibration
Multiplying factors are for a 16 hour exposure period during the day
Multiplying factors are for an 8 hour exposure period during the night

When assessing vibrations in a floor, appropriate acceptance criteria can be referenced from where (more than one may apply)?

BS 5950: Structural use of steelwork in building
BS 6472: Guide to evaluation of human exposure to vibration in buildings
SCI publication P354 “Design of Floors for Vibration: a New Approach”
BS 6399: Loadings for buildings

Which of the following descriptions accurately describes primary beam mode?

The primary beams form nodal lines about which the secondary beams vibrate as simply supported members. The slab is assumed to be continuous over the secondary beams and so a fixed-ended boundary condition is used.
The primary beams vibrate about the columns as simply supported members, and the secondary beams and slab are taken to be simply supported
The primary beams vibrate about the columns as simply supported members, and the secondary beams and slab are taken to be fixed-ended
The primary beams vibrate about the columns as fixed-ended members, and the secondary beams and slab are taken to be simply supported

An engineer has designed a floor plate to a response factor of 7. The floor comprises secondary beams at 3m centres acting compositely with a 140mm composite deck. The secondary beam has a frequency of 4.5Hz. The main contractor is having difficulty in getting materials into what is a congested site, and has asked if it would be acceptable to replace the composite deck with a lightweight timber joist floor. He submits calculations that demonstrate that the same beam acting non-compositely is perfectly adequate in terms of strength, and achieves the same frequency of 4.5Hz due to a reduction in dead load of 75%. How should the engineer respond?

As long as the beam is satisfactory in terms of strength and the beam frequency remains the same or higher, then that proposal is perfectly acceptable.
Whilst your calculations demonstrate that the beam can support the change in loads, and that both the beam and system frequency are satisfactory, I have concerns about the vibration performance of the floor. The dead load of the floor construction has been reduced by 75%. Newton’s second law (acceleration = Force/Mass) suggests a four fold increase in the accelerations due to this significant reduction in dead load. The response factor has gone up from 7 to 28, which is well in excess of current practice.
No, the drawings clearly state the form of construction required.
Your proposal is acceptable provided you can offer a saving to the Client and accept design liability for your proposals.

A designer has conservatively assessed a floor plate for an office of 18m x 30m. The structural grid is 9m x 7.5m and the plans show a central corridor running the length of the building. The target response factor is 8, but initial calculations indicate a response factor of 9. Which of the following strategies could the designer use to potentially reduce the initial response factor calculated?

The source of excitation (the corridor) is close to the column line, and so a µe value less than 1 is possible
Replace normal weight concrete for the composite slab with lightweight concrete
Reduce the walking path and resonance build-up by introducing doors in the corridor
If the axis of vibration is known use the appropriate frequency weighting curve

When assessing the frequency of a floor, which elements of the floor must the designer check?

The slab
The secondary beam
The primary beam
All of the above, both individually and collectively

No floor structure, and no single element within that floor structure, should have a fundamental frequency less than what?

8.4hz
5hz
4hz
3hz

Retrieved from ‘https://steelconstruction.info/index.php?title=Design_of_floors_for_vibration_quiz&oldid=4074