Determining reaction endpoint in polymer/resin reactors is critical to achieve desired product properties, such as molecular weight. Knowing exactly when the reaction is complete saves residence time and batch conversion time, and lowers the overall manufacturing cost. Having real-time information leads to signiﬁcant improvements in process control because you see activity with continuous readout that less frequent grab sampling may miss. Continuous monitoring allows you to go beyond “in-spec” to “on-target”! Online monitoring delivers a number of beneﬁts including:
NIR (near-infrared) spectroscopy is effective in providing one of the key parameters used to determine molecular weight, acid value. Another key parameter is viscosity, also measured in the reactor. Both parameters are used together to monitor the path of the reaction and to accurately determine the end point. Different products can be distinguished by these paths, as shown for hypothetical products A and B in Figure 1.
Isocyante is commonly added near the end of the reaction to modify the ﬁnal viscosity and as an end-blocker to achieve certain physical properties, such as wear resistance and electrical properties. Isocyanate may be measured accurately with our low cost ClearView® db photometer.
Color is a good indicator of oxidation where air might be brought into the reactor under vacuum from a leaky seal. Guided Wave’s ClearView db photometer is powerful in that it simultaneously analyzes chemical properties in the NIR range and color in the VIS range.
A ﬁber optic insertion probe may be directly inserted into the reactor. This is where light interacts with your sample. The Guided Wave SST probe is designed to withstand the frequent heating/cooling cycles in batch reactors at temperatures up to 300°C. Insertion probes can also be placed in transfer pipes in continuous processes.
Insertion probes are not the only means to make continuous measurements. If your polymers/resins are routed through a bypass loop (side stream) at temperatures < 150°C, you can use one of our many ﬂow cell designs. It is important that your material does not freeze up or solidify and block sample ﬂow. The sample can be valved off from the cell and drained. The ﬂow cell has a cleaning port that provides you with access to the optics for easy cleaning. Our insertion probes and ﬂow cells can be connected to our analyzers up to 100 meters away using reinforced process ready optical fiber cables. Fiber optic cables are routed to the analyzer in the control room or to a suitable enclosure that meets your local safety requirements, such as ATEX.
We offer two types of analyzer technologies for these measurements: our GUIDED WAVE™ ClearView® db photometer or the GUIDED WAVE NIR-O™ full-spectrum process spectrometer.
For simple reaction systems the ClearView db photometer is a lower cost option. The ClearView db may be used when fewer than 6 wavelengths are required for analysis. Linear calibrations may be developed on the analyzer or absorbances may be output directly to a control system for analysis. For more complex systems requiring full spectrum data or multiple calibration models for signiﬁcantly different reactions, a NIR-O full-spectrum spectrometer offers more powerful data analysis and greater versatility.
Our comprehensive GUIDED WAVE NIR UV-VIS process and lab analyzer spectrometers offer optically matched components and a meticulously planned calibration approach, ensuring long-term efficiency and cost savings. Our advanced systems are engineered for continuous online operation, delivering real-time data of laboratory-grade quality, even in the harshest processing plant conditions.
Terms and Conditions of Sale - Extrel
Sellers-Agreement-Purchasing-Terms-PUR-0026-FR-rev3 - Extrel
Terms and Conditions – Process Insights Swiss AG - MBW
Terms and Conditions – Tiger Optics
Terms and Conditions – Process Insights AG - LAR
Terms and Conditions – Guided Wave
Terms and Conditions of Sale – COSA Xentaur
Terms and Conditions – Alpha Omega Instruments
Copyright © 2023 Process Insights, Inc. All Rights Reserved.