PDF Publication Title:
Text from PDF Page: 011
Table 1 Test Parameters and Test Methods PARAMETER METHOD Flow rates U.S. EPA Method 1, “Sample and Velocity Traverse for Stationary Sources” or U.S. EPA Method 1A, “Sample and Velocity Traverses for Stationary Sources with Small Stacks or Ducts.” U.S. EPA Method 2, “Determination of Stack Gas Velocity and Volumetric Flow Rate (Type-S Pitot Tube)” and U.S. EPA Method 2C, “Determination of Stack Gas Velocity and Volumetric Flow Rate from Small Stacks or Ducts (Standard Pitot Tube).” Oxygen, carbon dioxide U.S. EPA Method 3A, “Determination of Oxygen and Carbon Dioxide Concentrations in Emission from Stationary Sources.” (Instrumental Analyzer Procedure) Moisture U.S. EPA Method 4, “Determination of Moisture Content in Stack Gases.” Nitrogen Oxides (Nox as NO2) (Outlet Only) U.S. EPA Method 7E, “Determination of Nitrogen Oxides Emissions from Stationary Sources.” (Instrumental Analyzer Procedure) Carbon monoxide (CO) U.S. EPA Method 10, “Determination of Carbon Monoxide Emissions from Stationary Sources” (Instrumental Analyzer Procedure In accordance with the approved stack test protocol, the micro turbine was tested without a heat recovery system. Useful thermal energy was calculated and added to electrical power to provide a net power output for the calculation of pounds per megawatt hour. Stack temperatures were measured every 10 minutes from a thermocouple that was installed in the exhaust duct upstream from the sample test ports. These temperature measurements were used to calculate useful thermal energy (based on a heat recovery system final temperature of 282 oF as agreed by NJDEP during protocol review) and were recorded on the field data sheets. Stack temperatures were also measured during flow traverses at the beginning and end of each test run in accordance with USEPA Methodology. These measurements were also recorded on the field data sheets, along with differential pressures and other information used to calculate volumetric flow rates. Appendix A indicates the stack conditions for the five operational loads tested. Ambient air temperatures were recorded during the test runs to provide intake air temperatures to the micro turbine. These temperatures were used to determine the ambient temperature/pressure de-rated base load (KW) from Figure 7-2 of Capstone’s Technical Reference Manual (Page 7-8). The de-rated base load was used to determine the set point for power output (KWe) of the engine based on targeted percent load. 11PDF Image | NJCAT TECHNOLOGY VERIFICATION CAPSTONE
PDF Search Title:
NJCAT TECHNOLOGY VERIFICATION CAPSTONEOriginal File Name Searched:
NJCAT-TECHNOLOGY-VERIFICATION-Capstone-12710.pdfDIY PDF Search: Google It | Yahoo | Bing
Capstone Turbine and Microturbine: Capstone microturbines used and new surplus for sale listing More Info
Consulting and Strategy Services: Need help with Capstone Turbine, sizing systems, applications, or renewable energy strategy, we are here to assist More Info
Container Lumber Dry Kiln: Since 1991 developing and innovating dry kilns using standard shipping containers More Info
Supercritical CO2 Lumber Dry Kiln: Compact fast drying in 3 days or less for small amounts of wood and lumber drying More Info
BitCoin Mining: Bitcoin Mining and Cryptocurrency... More Info
Publications: Capstone Turbine publications for microturbine and distributed energy More Info
FileMaker Software for Renewable Energy Developing database software for the renewable energy industry More Info
CO2 Gas to Liquids On-Demand Production Cart Developing a supercritical CO2 to alcohol on-demand production system (via Nafion reverse fuel cell) More Info
Stranded Gas for low cost power Bitcoin Mining Using stranded gas for generators may provide breakthrough low power costs for cryptocurrency miners. More Info
CONTACT TEL: 608-238-6001 Email: greg@globalmicroturbine.com (Standard Web Page)