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CPAC Project Overview. Goal is to support NeSSI related development within CPACDeveloping platforms and demo applicationsSupport PI and student use in research programs Promote and support wider NeSSI adoption and useWeb based supportInteraction with NeSSI communityLegal umbrella for cooperative development.
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1. Utilizing NeSSI for Analytical Applications Dave Veltkamp*
Brian Marquardt*
Charlie Branham
*Center for Process Analytical Chemistry (CPAC)
University of Washington, Seattle WA
Grad Student from Bart Kahrs group in Chemistry, UW
2. CPAC Project Overview Goal is to support NeSSI related development within CPAC
Developing platforms and demo applications
Support PI and student use in research programs
Promote and support wider NeSSI adoption and use
Web based support
Interaction with NeSSI community
Legal umbrella for cooperative development
3. Old NeSSI Gas/Vapor System
4. Optical Flow Cell Flow cell is a simple cross fitting
6-around-1 fiber optic for source and collection
Delrin rod with sensing compound coated on end
Multiple crosses can be chained together for screening several compounds at once
Optical detection using simple reflectance optical measurement
Ocean Optics USB2000 VIS spectrometer (350-1000 nm)
405 nm blue LED excitation
Compound fluorescence signal in region 600-900 nm
5. Vapochromatic Response
6. Vapochromic #1 Response
7. Vapochromic #3 Response
8. Bubbler Results (Benzene Conc.)
9. New Gas Sensor Testing System More capability to generate analytical vapors, gas blending, and on-line dilution of vapor streams for method development work
This system delivered by CORCOR Tech to UM last week and will facilitate collaboration with Kent Mann
10. The New CIRCOR NeSSI System Has Arrived in Minnesota
11. Reconfiguration of CPAC NeSSI System Our Swagelok NeSSI system proven to be very easy to change to suit needs
Replaced bubblers with permeation tubes and oven
Changed to look at CO2 in N2 blending
Changed to look at O2 and moisture in air
Investigation of flow, mixing, and dead volumes
Used to evaluated new analytical instruments in CPAC lab
ASI microFast GC 2 column GC with trap injection
Aspectrics EP-IR mid infrared spectrometer with gas cell
LabVIEW software developed to automate experiments
12. Reconfigured NeSSI System
13. Schematic of System Needed to design system with multiple (3) dilution stages
Somewhat complex flow paths to minimize dead volumes
Had to compromise automated vs. manual control of N2 flows in first two stages
Lack of additional MFCs required manual metering valves
14. System Flows By closing valves and using the MFCs as flow meters, all flows can be measured
Closing off the N2 flows (SV2 and MFC2) and waste valves (PV3 and PV4) allows flow thru bubbler to be measured
MFC3 and MFC1 set to valve open setpoint
All flow streams and legs of system can be flushed by N2
15. System Flows (cont.)
16. Dilution Flows 1st dilution of bubbler flow at input to MFC 3
Most of flow goes to waste, MFC setpoint typically 1-5%
N2 flow regulated by waste needle valve
2nd dilution at outlet port of MFC 3
Again most of flow going to waste, MFC 1 set to 1-5%
N2 and 2nd diluted sample flows set by needle valves PV2 and PV4
3rd dilution at output port of MFC 1
N2 flow controlled by MFC 2
Important to balance pressures and flows to avoid unexpected flow conditions some tweaking required!!
17. Aspectrics EP-IR Instrument 128 channels from 2.50 to 5.00 microns (4000-2000 cm-1)
Each channel approx 19.7 nm wide band pass
Also a 256 channel model available
Runs at an acquisition frequency of 100 scans (rotation) per second
Real-time data collection of fast events
High averaging for low LOD applications
Small size and rugged construction
Only moving part is the encoder disk
Suitable for high vibration process environments
No hygroscopic parts
Several optical configuration of sampling cell/accessories possible
Powerful on-line embedded chemometrics software
18. Aspectrics EP-IR Technology
19. Aspectrics EP-IR with Gas Cell
20. ASI microFAST GC System on loan from ASI as part of WTC project with Infometrix
Programmed temperature gas chromatograph using
Syringe or valve inlets to a flash evaporator.
Sample delivery to an adsorbent trap for concentration
Desorbtion and delivery to twin capillary columns
Temperature programmed column elution
Detection by simultaneous flame ionization detectors (FID).
Trace levels down to low parts per billion can be measured.
Compact and easy to setup chromatography
Weight on the order of 12 pounds
Size on the order of a shoe box
Speed of analysis on the order of 10 times faster than competitors
Very easy to use
Trap injection makes it simple to use and automate
Really more like a spectrometer or sensor in operation
Even non-chromatographers can use it!!
21. ASI microFAST GC
22. microFAST GC Column Details
23. microFAST GC Analytical Cycle
24. Interfacing to ASI microFast GC
25. Example Benzene Chromatograms
26. Experiment: Blending CO2 with N2 Goal was to characterize the NeSSI system, software control, and the EP-IR gas cell data collection
Series of step changes in MFC setpoints for CO2 dilution
Different hold times (delay) between setpoint changes
Series repeated 5½ times
Bubbler replaced with CO2 from tank
Results show very good reproducibility and control of the gas blending system
Dynamic response consistent with expectations
No dead volume issues
27. CO2 Blending Experimental Design
28. EP-IR Spectra from CO2 Experiment
29. 1st PC of EP-IR Spectra PCA Model
30. Step times and Spectral Response
31. CO2 Exp. Cycle Reproducibility
32. 2nd PC of EP-IR Spectra PCA Model
33. PCA results showing nonlinear behavior at high CO2 conc.
34. On-line Chemometric Model Results
35. NeSSI Permeation Tubes Used a stainless steel condenser as oven for permeation tubes
Removed condenser core and replaced with permeation tubes
Mounted in single-port ½ adapter to direct N2 up thru oven
Second ¼ adapter block returns flow into NeSSI
Temperature maintained by flowing water thru jacket from heater/chiller
Permeation tubes made in-house
Teflon tubing sealed at both ends
Made different tubes for water, benzene, and toluene vapors
36. Permeation Tube Results Water permeation tube study
Vapochrome compound (Kafty)
Oven temp. set at 50°C
MFC flow rate set at 10%, 20%, 30%, 40%, and 50% for 30 min
Spectra taken at each flow rate
Benzene permeation tube
Vapochrome compound (#4)
Oven temp. set at 30°C
MFC flow rate set at 0%, 10%, 20%, 30%, 40%, and 50% for 30 min
Spectra taken at each flow rate
37. Conclusions and Future Work Setup of NeSSI Vapor Platform complete (for now)
LabVIEW software developed and tested
Flow dynamics tested and characterized
New vapor generation ideas to be tested
New instrumentation interfaced and tested
Both Aspectrics EP-IR and ASI microFAST GC valuable additional tools for monitoring gas mixing and delivery
Additional applications from Sponsors welcome
Vapochromic compound testing continuing
Moisture, CO2, O2 and BTEX sensors testing underway
Additional screening and analytical performance testing planned
Plan to get back to some microreactor work
Parker NeSSI system for reactant and product streams
Microreactor components from Microglass & IMM on hand
Fuel cell studies with Eric Stuve and Chem. E. students planned
WTC Project with Infometrix on Process GC interfaced to NeSSI