EMRP-projekter - Flowcenter Danmark - Center of … · EMRP-projekter Status på flow ... The...
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EMRP-projekter
Status på flow aktiviteter som FORCE og TI er involveret i
November 2012
Lars Poder, FORCE Technology
Agenda
1) Introduktion til EMRP-programmet
2) Status på flow aktiviteter: a. Metrology for Liquefied Natural Gas (FORCE) b. Novel mathematical and statistical approaches to uncertainty evaluation (FORCE) c. Metrology for Power Plants (TI) d. Metrology for Meteorology (TI) e. Metrology for Drug Delivery (TI)
3) EMRP call 2012
European Metrology Research Programme (EMRP)
The science of measurement - metrology - is important for scientific research, industry and our everyday lives, as the demand for measurements with high accuracies and low uncertainties continues to increase. The European Metrology Research Programme enables European metrology institutes, industrial organisations and academia to collaborate on joint research projects within specified fields. These collaborative efforts will accelerate innovation in areas where shared resources and decision-making processes are desirable due to economic factors and the distribution of expertise across different countries and sectors. The EMRP is implemented by EURAMET, organised by 22 National Metrology Institutes (NMIs), supported by the European Union and has a value of 400 M € over an app. 7 year period. The preceding project iMERA-Plus (implementing Metrology in the European Research Area) had a value of 64.6 M €.
Flow Metrology for Liquefied Natural Gas (LNG)
EMRP Project – Introduction, overview and status
November 2012
Lars Poder, FORCE Technology
About LNG
Liquefied Natural Gas is produced by cooling down natural gas below its dew point (-161 °C)
A unique solution for transporting natural gas to areas far from a pipeline structure
The volume occupied by LNG at atmospheric pressure is about 614 times smaller than its gaseous state – this reduces the space needed to freight an amount of energy
LNG is shipped in carriers from liquefaction plants to large tanks in buyer countries
These wessels can load from 145,000 to more than 200,000 m3
The energy volume of such a consignment corresponds to 1 – 1.4 TWh
One LNG cargo represents the annual power consumption of roughly 200,000 households in Denmark.
Flow Metrology for LNG
Flow Metrology for LNG
Energy = Volume x Density x Gross Calorific Value
Inaccuracies involved in the measurements of the parameters given in the above equation according to the G.I.I.G.N.L. (International group of Liquefied Natural Gas Importers) Handbook (2010):
Element calculated Total accuracy (%)
Volume ± 0.21
Density ± 0.23
Gross calorific value ± 0.30
Overall LNG energy transferred ± 0.43 (Annual power consumption in 86 Danish households)
The Handbook is not a standard but a document providing guidance to the industry by describing common practice. As of yet a thorough metrologically sound uncertainty budget has not been conducted.
The project’s overall objective
To contribute to a significant reduction of uncertainty in the determination of transferred energy in LNG custody transfer processes
(1% uncertainty = 440 M€/year in 2010 and 900 M€/year in 2015)
Static versus dynamic volume measurements
Typically
– Level gauging + gauge table (static)
– Correction tables
– Uncertainty: 0.2 – 0.5 % ?
Alternative
– Volume rate meters (dynamic)
– Uncertainty: 0.2 – 0.3 % ?
– No direct traceable link to SI units
Calibration facility required!
Flow Metrology for LNG
Flow Metrology for LNG
Accuracy + ÷
Pressure loss ÷ +
Price ÷ -
Calibration of flow meters with LIN – which meters?
Coriolis Vortex
Flow Metrology for LNG
Calibration of flow meters with LIN – how?
Temperatur: -165 °C Diameter: 2” Flow range: 130 – 700 l/min Tryk: 2 – 3 bar
Calibration of flow meters with LIN – how?
Flow Metrology for LNG
The mobile test bench "Flowmass”
Preliminary testing of Vortex meter with LIN against the mobile test bench October 23
Project duration: May 2010 – May 2013
Project coordinator: Ir. Oswin Kerkhof, VSL
Funding: Approx. 3 M€ (46% EU/EMRP, 54% Metrology organisations)
Project partners:
VSL , Netherlands ENAGAS, Spain
SP, Sweden ELENGY, France
TUV NEL, United Kingdom E.ON RUHRGAS, Germany
FORCE Technology, Denmark
Justervesenet, Norway
CMI, Czech Republic
Cesame, France
INRiM, Italy
PTB, Germany
Flow Metrology for LNG
Novel mathematical and statistical approaches to uncertainty evaluation EMRP Project – Introduction and overview
November 2012
Lars Poder, FORCE Technology
Better measurement uncertainty analysis
The evaluation of uncertainty in measurement is fundamental to measurement science. Without
it results cannot be compared, and unreliable uncertainty evaluations can have huge negative
economic, health and environmental impacts.
The Guide to Uncertainty in Measurement (GUM) contains existing approaches to uncertainty
evaluation, but these may not be appropriate for modern applications such as biochemical and
nanoscale measurements.
This project will develop new approaches to measurement uncertainty evaluation and enable
their consistent application. It will focus on three areas where new uncertainty analysis methods
are needed:
1) inverse and regression problems,
2) computationally expensive model functions,
3) conformity assessment and reliable decision making.
These new analysis methods will improve product testing, safety regulations, medical diagnosis
and drug testing, and will provide input for future revisions of the GUM.
Uncertainty