Benders, StefanStefanBendersRennebaum, Hannah SophieHannah SophieRennebaumÖzdemir, MelisMelisÖzdemirLenczyk, TillTillLenczykPenn, AlexanderAlexanderPenn2024-11-122024-11-122024-08-2616th International Bologna Conference Magnetic Resonance in Porous Media (MRPM 2024)https://hdl.handle.net/11420/50743Chemical engineering is a crucial field in the production of many essential goods, with its processes undergoing major changes in the transition to a less fossil-dependent product chain. Yet, understanding these processes is often based on modeling and measurements with integral or local invasive sensors. Tomographic techniques such as magnetic resonance imaging (MRI) can overcome these limitations and provide essential information. However, MRI systems are typically not constructed with the needs of (bio)chemical reactors in mind. Most vertical MRI systems feature probe diameters of below 8 cm and maximum sample heights of below 1 meter. On the other end, clinical MRI systems are usually built horizontally and feature bore sizes of bigger than 30 cm and maximum sample lengths of a few meters. However, due to their orientation, processes based on gravity have to conform to the bore size and are therefore limited. The TUHH system combines the advantages of both systems. It is a vertical bore magnet with a 40 cm bore diameter. Sitting on legs at 4 m height, samples of up to 3 meters can be measured. This is especially relevant for reactors based on gravity, such as fluidized beds or bubble columns. The magnet itself is a cryogen-free magnet with a field strength of 3 T. The clinical backend of the system enables the exploitation of the benefits of MRI techniques developed for the medical field, as well as the use of modern techniques such as parallel imaging. The RF body coil is driven by a 2×17 kW amplifier and the gradients are capable of producing up to 125 mT/m with a slew rate of 330 T/m/s. Up to 32 channel receive arrays can be connected to enable high SENSE acceleration factors. The system is freshly commissioned in 2024 and is planned to be used in various projects. In particular, the work of Alexander Penn in ultrafast imaging will be continued and extended in scope[1,2]. A main focus here are fluidized beds and liquid-gas reactors, which can be investigated with temporal resolutions below 30 ms. Furthermore, techniques such as thermometry and chemically resolved imaging will be employed to reveal the processes inside important reactor systems. References [1] H.S. Rennebaum, D.L. Brummerloh, S. Benders, A. Penn, Powder Technol., 432 (2024) 119114. [2] A. Penn, T. Tsuji, D.O. Brunner, C.M. Boyce, K.P. Pruessmann, C.R. Müller, Sci Adv 3(9) (2017) e1701879.enMRI, chemical engineering, magnet, NMRConference Poster not in ProceedingsConference Poster