Fouling at interfaces deteriorates the efficiency and
hygiene of
processes within numerous industrial sectors, including the oil and
gas, biomedical device, and food industries. In the food industry,
the fouling of a complex food matrix to a heated stainless steel surface
reduces production efficiency by increasing heating resistance, pumping
requirements, and the frequency of cleaning operations. In this work,
quartz crystal microbalance with dissipation (QCM-D) was used to study
the interface formed by the fouling of milk on a stainless steel surface
at different flow rates and protein concentrations at high temperatures
(135 °C). Subsequently, the QCM-D response was recorded during
the cleaning of the foulant. Two phases of fouling were identified.
During phase-1, the fouling rate was dependent on the flow rate, while
the fouling rate during phase-2 was dependent on the flow rate and
protein concentration. During cleaning, foulants deposited at the
higher flow rate swelled more than those deposited at the lower flow
rate. The composition of the fouling deposits consisted of both protein
and mineral species. Two crystalline phases of calcium phosphate,
β-tricalcium phosphate and hydroxyapatite, were identified at
both flow rates. Stratification in topography was observed across
the surface of the QCM-D sensor with a brittle and cracked structure
for deposits formed at 0.2 mL/min and a smooth and close-packed structure
for deposits formed at 0.1 mL/min. These stratifications in the composition
and topography were correlated to differences in the reaction time
and flow dynamics at different flow rates. This high-temperature application
of QCM-D to complex food systems illuminates the initial interaction
between proteins and minerals and a stainless steel surface, which
might otherwise be undetectable in low-temperature applications of
QCM-D or at larger bench and industrial scales. The methods and results
presented here have implications for optimizing processing scenarios
that limit fouling formation while also enhancing removal during cleaning.
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