Modelling of structures

Today’s structural engineers have a wide range of tools available that allow fast and detailed analysis of different structural forms. However, it is important to clearly understand the assumptions, simplifications and the basis of any software being used for modelling the structure. As the reporter points out, the software used for structural analysis is based on an idealised mathematical model of the structure. There are limits to how accurately the models can represent the real structure in its real environment.

When correctly used, structural modelling can provide the engineer with a solid grasp of the upper and lower bounds to any design on which they are working. Simple models can be used to understand the results of more complex models and all modelling should be considerate of likely construction tolerances, secondary effects, and serviceability implications (vibrations, accelerations, line of sight, etc.). It is also important to consider the effect on structural behaviour from temperature changes, concrete shrinkage, and the possibility of unexpected loads (robustness). If the material response is ductile the consequences of overlooking such effects may be limited, but if the material response is brittle, these effects may lead to failure. 

As noted by the reporter, engineers should be aware of the inherent inaccuracy of modelling deflections in materials such as concrete.  Informing a client that a reinforced concrete beam will deflect 21.7mm in the long term would provide a false degree of precision, whereas a more realistic statement would be that the long-term deflection of the beam is likely to be in the range 10 to 30mm.

It is important to verify the results from the model and for the more experienced engineer this may be by “gut feel” and a review of the deflected shape produced by the model. For the less experienced, the very minimum should be self-checking by simple hand calculations to check that the results (e.g. span/depth ratios) are of the right order, and that the total support reactions are equal to the overall loads applied. For complex structures, a very simplified model may be used as a comparison to check the expected load path and to provide a “sense check” for the more complicated model with all elements included.

It is well established that human errors are the cause of most structural failures and a European research project - The human factor in structural engineering: A source of uncertainty and reduced structural safety - has studied how subjective decisions, individual knowledge and the use of advanced tools and codes affect structural safety and structural design. This research revealed a large variation (around 300%) in results when a common design task was carried out by different engineers and introduces the term Engineering Modelling Uncertainty (EMU).

Further examples of incorrect modelling of structures that may go undetected are outlined in two investigations of existing bridge capacities that make sobering reading:

• The UK Highways Agency Contract 2/419 Technical Audit of the Application of BA79 A Review of Bridge Assessment Failures on the Motorway and Trunk Road Network. This audit of 249 desk-top bridge assessments that had been carried out by a range of consultants was undertaken to determine why there was an unexpectedly large number of assessment failures. Disturbingly, two of the eight reasons for assessment failures were failures in the desk-top assessment process itself through “inappropriate or too conservative analysis for assessment” and “misinterpretation or inappropriate application of the assessment code”.
• The Queensland Department of Transport and Main Roads (TMR) had a similar experience as presented in the paper by Shaw, Pritchard and Heywood: Bridge Analysis: are we data managers or engineers? TMR conducted an audit of around 500 desk-top bridge assessments that had been carried out by different consultants. This found a range of errors including errors in the use of 3D models, inappropriate software defaults and incorrect load application.

The CROSS Topic Paper Reflective thinking discusses similar concerns. Reflective thinking is a constant drive to ask questions and to make appropriate responses to them. It is characterised by a healthy scepticism about all inputs to processes, the processes themselves and about the outcomes from processes.

To summarise, the risks associated with inadequate modelling include:

• models with assumptions about boundary conditions, element interaction and unrealistic structural behaviour;
• designers not understanding the limitations of software;
• inadequate time assigned to checking of models and independent rudimentary first principle checking for logical output; and
• standards and guidelines may not be suitable to cover the developments in software or communications between designer, detailer, fabricator or builder etc. 

These risks can be mitigated as follows:

• ensure the competency level of the modelling and analysis software operator is adequate for the task;
• undertake suitable quality control based on level of risk;
• undertake independent verification and validation based on the level of risk; and
• having a quality control system in place that incorporates the modelling, analysis and model transfers.

The CROSS database contains other examples of the problems associated with incorrect modelling. Attention is drawn to the recent report 1073 Concern over modelling of concrete frame building for construction stage. This report stresses the importance of considering the effect that the construction sequence may have on the design and the need to design the structure through all stages of its life. Failure to ensure that the design and proposed construction methodology are compatible may lead to a structure which is unsafe to build or indeed unsafe in use.