In the early and mid 1990s, car companies typically offered only a few basic models. In today’s competitive market, automakers must sell a wide range of vehicles and derivative versions to suite a wide variety of changing buyer tastes and trends – all while consistently maintaining high quality and minimizing vehicle weight. Keeping up with growing numbers of new designs has stretched durability testing facilities to the limit, and the resulting bottleneck often hampers automakers in launching new designs. To solve this problem the BMW Group have integrated LMS lifetime prediction software into their core development process.
The number of physical prototypes did not increase despite the fact that the range of products is continually growing. System-level durability simulation together with dedicated analysis and visualization capabilities provide an effective communication platform for collaboration between BMW Group engineering, design teams, and key suppliers. As a consequence, the BMW Group observed a shorter vehicle development time, especially for derivative versions.
Reducing the test bottleneck
Virtual simulation in combination with fatigue tests is definitely the only solution to handle the increasing diversity of vehicles, accelerate time to market and safeguard quality standards. In the past, quasi-static strength calculations in the component design phase approximated load levels parts could withstand. Only until much later in development when physical mock-ups were built and tested, precise load data could be obtained and component designs adjusted accordingly.
The danger of evaluating durability solely on the basis of static strength calculations is that the durability impact of cyclic loads is likely to be disregarded. To improve this situation, the BMW Group deployed a systematic approach to early fatigue-life calculation for dynamically stressed parts. Using durability software, BMW Group engineers calculate the strength under cyclic load – representing the true fatigue life of their designs. This puts them in a position to assess durability performance early in development and to deliver clear recommendations for guiding major design choices.
To more precisely predict loads early in development, BMW tested the LMS Hybrid Road approach in combination with multibody simulation. LMS Hybrid Road starts from wheel spindle loads measured on a previous model vehicle and converts these into wheel spindle displacements. The obtained spindle displacements – which are much more dependent on road surfaces than on vehicle characteristics – are used as inputs for full-vehicle multibody simulation. These dynamic motion simulations allow the cascading of vehicle excitations down to cyclic component forces and displacements acting on chassis and body parts. LMS Virtual.Lab Durability automatically multiples these cyclic loads by unit-load stresses determined by finite-element analysis. From this data and structural information such as material properties, fatigue life prediction determines accumulated damage, identifies weak areas, and provides lifetime prediction in terms of the number of duty cycles the structure can undergo.
LMS Lifetime prediction software allows engineers to identify and fix fatigue problems in a few days versus several weeks of physical testing. This compresses the process and enables what-if studies. As a result, the design is refined and most fatigue life problems are corrected before component hardware prototypes are built and assembled. So in the system validation phase, fewer iterations are required. The CAE engineer eliminates time-consuming and expensive test loops, supports consistently lightweight design and provides the required proof-of-durability for vehicles.
The new process was used extensively in the development of new BMW Group cars and showed considerable success in enabling engineers to identify and correct potential problems early. For example, fatigue-life analysis was used to simulate more than 5,000 spot welds so engineers could make design improvements to eliminate any over-stressed areas early in development.
In the future, the BMW Group plans to also use fatigue life simulation extensively in the validation phase of development. Ideally, this approach would require only two hardware prototypes: one at the end of the design process to ensure that the simulation model accurately represents the hardware, and another at the end of the validation phase for final system hardware tests.
At the BMW Group, these tests are critical to confirm the accuracy of the calculations and adjust the simulation models if necessary. In this way, testing and simulation complement one another. Intelligent use of both technologies is essential in developing all the many models and variants at the BMW Group. Moreover, empirical data and simulation models from today’s vehicle programs will be valuable in developing future cars.
Simulation facilitates collaboration
The ability to predict fatigue life and other functional variables such as crash behavior and acoustics serves as a powerful communication platform for the CAE engineer to collaborate with other groups during vehicle development including designers, test engineers, management and key suppliers.
Such communication relies heavily on the ability of software to analyze and visualize results and to deliver the clear engineering insights required to eliminate durability problems.
LMS Virtual.Lab Durability, for example, shows color-coded “hot-spot” damage areas, and graphic representations can be combined with simultaneously displayed load time plots. Animated structural deformations can be displayed next to stress and/or damage results. Accumulated damage, fatigue life, maximum stress amplitudes and safety factors can all be readily displayed in graphical format.
Using such visualization and analysis capabilities, the durability CAE engineer can provide valuable feedback to the design team on improving fatigue strength by using different materials, for example. Likewise, the CAE engineer can provide the test engineer fatigue life simulation results to guide test procedures and identify areas potentially at risk to cracking, so expensive and time-consuming durability test procedures can be focused on eliminating remaining trouble areas. Fatigue life results also can be conveyed to management in a non-technical format to show, for example, the consequences of damage and its progression in the structure. Open systems are extremely beneficial in communicating with suppliers and other external organizations, especially with the trend toward co-development partnering and greater delegation of design responsibility to subcontractors.
Enabled by the ability of simulation to quickly provide results such as fatigue life prediction, close collaboration between various groups accelerates vehicle development. More broadly, simulation-enabled collaboration facilitates the way cross-functional teams can work together synergistically in developing innovative designs of future vehicles that are the key to success for a high-end automaker such as the BMW Group.
