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The devil is in the detailing In the crane design world, how beams are joined together is called connection detailing and getting these details right can literally make or break a crane. Besides reducing a crane’s potential for collapse, proper connection detailing can also extend a crane’s service life by up to 400%. As we know, cranes experience their full rated load much more often than other structures, such as buildings and bridges. While an engineer might not be surprised that cranes see their rated load as often as they do, what is not so obvious is the consequences of millions of cycles at the full rated load. These consequences are known as “fatigue”. Fatigue is the term used to describe the failure of a steel member below its yield stress due to cyclic loading. By understanding fatigue and implementing fatigue design strategies and concepts, the crane engineer can go a long way in removing the “devil” from the detailing. 36
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Poor fatigue detailing increases the risk of cracking, which can lead to sudden connection and member failures. The long-term benefits of good fatigue detailing are longer inspection intervals and less repair work, resulting in reduced maintenance and repair costs. Smooth transfer In the structural crane design world, fatigue detailing is a special class of connection design. Fatigue detailing improves the smooth transfer of loads from one beam to another by reducing stress concentrations. Stress concentrations—also called stress risers—are created when one area of a connection is more highly stressed than adjacent areas. This condition is usually the result of an abrupt change in geometry, especially around sharp corners. Good fatigue detailing reduces
stress concentrations by limiting the effects of geometry changes when connecting one beam to another. Many crane design codes address fatigue detailing by separating connection types into classes based on the severity of their stress concentrations. Historically, stress concentration factors have been found using experimental techniques though advances are being made in finite element analysis (FEA) to approximate the initiation and propagation of fatigue cracks more accurately. This is also true in many of the experimental sensors, such as strain gauges. Modern-day technology is relevant here, as it is with everything else. The improvements of computer chips have been remarkable. They allow engineers to run very computationally demanding calculations that take a computer the same amount of time to complete as it takes for the engineer to grab a cup of coffee from the office kitchen. We can run multiple design iterations and compare results much more quickly than before. This allows engineers to consider more connection details than they could have previously. However, properly setting up and verifying the results of the FEA model is now the bottleneck. An important complement to connection detailing is proper fabrication. On-site inspection during all phases of a crane’s construction is a must to ensure the as-designed fatigue detailing is properly implemented. Inspectors help make sure plates are properly fit-up and clean before welding. Weld inspectors review weld geometry for proper setup and carry out non-destructive testing. Misaligned transfer Good fatigue detailing extends to mechanical components as well. Engineers must maintain proper alignment of machinery for power transfer to occur efficiently and consistently. For a hoist-on-trolley arrangement, if the hoist machinery is not designed for the flexing of the trolley frame as the crane picks up a load, then the hoist machinery is likely to become misaligned during the pick.