I think the following from the commentary to the Australian Bridge Design Code (AS 5100.2) is relevant here:
"C6.11 Deflection
The specification of limits on live load deflections and span to depth ratios have
traditionally been used in road and railway bridge design codes to attempt to control
vibration, prevent fatigue, limit stresses in secondary members and allow for dynamic
loading. Although this Standard provides specific clauses aimed at addressing these
serviceability limit states, it has also retained limitations on live load deflections.
Relaxed deflection limits have been introduced in this version of the Standard as part of the
transition to designing bridges for SM1600 loading and the uncertainty about appropriate
serviceability limits for controlling vibration.
For bridges with walkways, the criteria for limiting vibration in Clause 12 of the Standard
will generally control.
For other bridges, the magnitude of allowable deflection limits have been increased from
1/800 of the span or 1/400 of the cantilever projection in ABDC-1992 (HB 77.2—1996)
(Ref. 1) to 1/600 and 1/300 respectively and the method of calculation has also been made
less conservative, as per AASHTO LRFD (2004) (Ref. 15).
These limits are similar to the values that have been used for railway bridges for many
years and reflect the magnitude of the SM1600 loading. They are also representative of the
magnitude of live load deflections in typical prestressed concrete bridges designed for
SM1600. These deflection limits, together with the fatigue criteria specified in Clause 6.9
of the Standard, are likely to prove to be controlling serviceability limit states for steel
beam bridges, particularly when high strength steel is used."
Doug Jenkins
Interactive Design Services
