PDF Publication Title:
Text from PDF Page: 027
SRI/USEPA-GHG-VR-27 September 2003 pressure and temperature sensors for flow rate compensation to provide mass flow output at standard conditions (60 oF, 14.696 psia). Note that the Rosemount was located upstream of the gas compressor, and, therefore, the measured gas pressures and temperatures were not indicative of fuel conditions entering the microturbine. Gas pressure into the microturbine were not independently verified, but indicated by a pressure gauge to be 75 psig. The meter was configured to continuously monitor the average flow rate at one-minute intervals. The meter components (orifice plate and differential pressure sensors) were calibrated prior to testing using NIST-traceable instruments. Additional QA/QC checks for this meter were performed routinely in the field, including reasonableness and zero checks. Natural Gas Supply Air Intake J Exhaust Gas To Atmosphere I G H A Microturbine Exhaust B C E F PG Supply PG Return Gas Compressor Capstone 60 Microturbine D AC Power A Fuel Gas Flow and Pressure E Power Consumed By Compressor H PG Return Temperature B Gas Samples for LHV C Fuel Gas Temperature D Power Production And Power Quality F PG Flow Rate PG Supply G Temperature I Emissions Testing Ambient Temperature, Measurement Locations J Pressure, and Humidity Figure 1-4. Schematic of Measurement System Natural gas samples were collected and analyzed to determine gas composition and heating value. A total of six samples were collected—four during the control test periods and another two during the extended monitoring. The collected samples were submitted to Empact Analytical Systems, Inc., of Brighton, CO, for compositional analysis in accordance with ASTM Specification D1945 for quantification of methane (C1) to hexane plus (C6+), nitrogen, oxygen, and carbon dioxide [7]. The compositional data were then used in conjunction with ASTM Specification D3588 to calculate LHV and the relative density of the gas [8]. Duplicate analyses were performed by the laboratory on two of the samples to determine the repeatability of the LHV results. 1-11 Unifin Heat ExchangerPDF Image | Environmental Technology Verification Report
PDF Search Title:
Environmental Technology Verification ReportOriginal File Name Searched:
Capstone-ETV-Report.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)