Center for Mass Spectrometry and Optical Spectroscopy (CeMOS), University of Applied Science Mannheim, 68163 Mannheim, Germany.
Hellma GmbH & Co. KG, 79379 Müllheim, Germany.
Sensors (Basel). 2022 Aug 15;22(16):6098. doi: 10.3390/s22166098.
Quality control and reaction monitoring are necessary to ensure the consistency of any kind of mixing or reaction process. In this context, a novel portable high-sensitivity sensor prototype based on the Raman effect is presented in this study. The elongated probe head is designed for (but not limited to) monitoring high temperature batch processes for quality assurance. Thanks to the highly sensitive special detectors, concentration differences of up to 50 mmol/L can currently be detected, which facilitates compliance with high product quality standards. In addition, seamless reaction tracking is possible. Small individual adjustments through simple, intuitive mechanical components provide a high degree of flexibility in reaction selection by the end user. Specially developed software automates the evaluation process and gives the user visual signals about the current status and progress of the batch as well as an emergency stop if temperature limits could damage individual components. By using all the individual components developed, the problem of the limited integration times of previous spectrometric measuring instruments could be reduced. The prototype was validated using concentration measurements of various substances that occur as standard in batch processes. In addition, this article provides an outlook on the fact that Raman measurements can also be carried out successfully and reliably in explosive environments in the future with the prototype presented.
质量控制和反应监测对于确保任何混合或反应过程的一致性都是必要的。在这种情况下,本研究提出了一种基于拉曼效应的新型便携式高灵敏度传感器原型。细长的探头头专为(但不限于)监测高温批量过程以确保质量而设计。由于高度灵敏的特殊探测器,目前可以检测到高达 50mmol/L 的浓度差异,这有助于符合高产品质量标准。此外,还可以实现无缝的反应跟踪。通过简单直观的机械组件进行小的单独调整,为最终用户在反应选择方面提供了高度的灵活性。专门开发的软件可自动完成评估过程,并为用户提供有关批量当前状态和进度的视觉信号,如果温度限制可能损坏个别组件,则可以进行紧急停止。通过使用所有开发的单个组件,可以减少以前光谱测量仪器集成时间有限的问题。该原型使用在批量过程中作为标准出现的各种物质的浓度测量进行了验证。此外,本文还展望了未来使用所提出的原型在爆炸环境中也可以成功可靠地进行拉曼测量的事实。