Cristin-prosjekt-ID: 2062237
Sist endret: 5. juni 2020 15:49

Cristin-prosjekt-ID: 2062237
Sist endret: 5. juni 2020 15:49
Prosjekt

Multiphase flow and early fault detection

prosjektleder

Marie Bueie Holstad
ved NORCE Teknologi ved NORCE Norwegian Research Centre AS

prosjekteier / koordinerende forskningsansvarlig enhet

  • NORCE Teknologi ved NORCE Norwegian Research Centre AS

Finansiering

  • TotalbudsjettNOK 7.200.000
  • Norges forskningsråd
    Prosjektkode: 235372

Klassifisering

Vitenskapsdisipliner

Teknologi

Emneord

Akustikk • Dataanalyse • Elektronikk • Flerfasestrømning • Olje og gass

Kategorier

Prosjektkategori

  • Anvendt forskning

Kontaktinformasjon

Tidsramme

Avsluttet
Start: 1. januar 2014 Slutt: 31. desember 2017

Beskrivelse Beskrivelse

Tittel

Multiphase flow and early fault detection

Populærvitenskapelig sammendrag

Xsens AS, with NORCE as the main R&D partner, has developed a non-invasive flow meter challenging the performance of a wide range of invasive technologies, with respect to performance, as well as robustness.

Xsens aim has been to measure complex flow from outside of the pipe, equally good or better than invasive technologies available in the market. The priority challenges defined at the start of the IPN project was flow measurement accuracy at single phase flow and dual phase liquid flow, fraction measurement in dual phase flow and the ability to measure single or dual liquids containing gas, eg.

The Xsens flow meter technology differs from available invasive flow meters by disruptive flow measurement capabilities with respect to both measurement accuracy and fluid quality measurement. Xsens have during the IPN project prototype testing at real conditions in the CMR multiphase flow loop, demonstrated transmission of acoustic beams travelling in a controllable distance outside the center of the pipe. This disruptive innovation allows for flow profile correction hence accuracy levels, until now obtained by multi-sensor invasive technology only. Furthermore, advanced algorithms combining the characteristics of acoustic transmission in both pipe and fluid has been demonstrated, providing accurate information with respect to acoustic time of flight and fluid quality for each sound path transmitted.

During the 2014-2017 IPN a stage-wise prototype development and thorough flow testing between each stage have resulted in a robust flow meter design aiming at industrialization for use in hazardous areas and subsea applications.

Flow test have been carried out on gas, oil, water in single phases, combination of liquids and liquids containing gas and the technology shows potential for a wide range of fluid combinations and industrial applications.

The industrialization process was started in parallel with the conclusion of the IPN project, on the basis of financial investors Investinor and Proventure share capital extension and awarded Forny2020 and Demo2000 project funding.

The project was funded by RCN Petromaks2 and Xsens AS. 

Vitenskapelig sammendrag

Xsens AS, with NORCE as the main R&D partner, has developed a non-invasive flow meter challenging the performance of a wide range of invasive technologies, with respect to performance, as well as robustness.

Xsens aim has been to measure complex flow from outside of the pipe, equally good or better than invasive technologies available in the market. The priority challenges defined at the start of the IPN project was flow measurement accuracy at single phase flow and dual phase liquid flow, fraction measurement in dual phase flow and the ability to measure single or dual liquids containing gas, eg.

The Xsens flow meter technology differs from available invasive flow meters by disruptive flow measurement capabilities with respect to both measurement accuracy and fluid quality measurement. Xsens have during the IPN project prototype testing at real conditions in the CMR multiphase flow loop, demonstrated transmission of acoustic beams travelling in a controllable distance outside the center of the pipe. This disruptive innovation allows for flow profile correction hence accuracy levels, until now obtained by multi-sensor invasive technology only. Furthermore, advanced algorithms combining the characteristics of acoustic transmission in both pipe and fluid has been demonstrated, providing accurate information with respect to acoustic time of flight and fluid quality for each sound path transmitted.

During the 2014-2017 IPN a stage-wise prototype development and thorough flow testing between each stage have resulted in a robust flow meter design aiming at industrialization for use in hazardous areas and subsea applications.

Flow test have been carried out on gas, oil, water in single phases, combination of liquids and liquids containing gas and the technology shows potential for a wide range of fluid combinations and industrial applications.

The industrialization process was started in parallel with the conclusion of the IPN project, on the basis of financial investors Investinor and Proventure share capital extension and awarded Forny2020 and Demo2000 project funding.

The project was funded by RCN Petromaks2 and Xsens AS. 

prosjektdeltakere

prosjektleder

Marie Bueie Holstad

  • Tilknyttet:
    Prosjektleder
    ved NORCE Teknologi ved NORCE Norwegian Research Centre AS

Kjetil Daae Lohne

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Teknologi ved NORCE Norwegian Research Centre AS

Jan Kocbach

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Teknologi ved NORCE Norwegian Research Centre AS

Stian Husevik Stavland

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Teknologi ved NORCE Norwegian Research Centre AS

Peter Thomas

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Teknologi ved NORCE Norwegian Research Centre AS
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Resultater Resultater

Time-of-flight dependency on transducer separation distance in a reflective-path guided-wave ultrasonic flow meter at zero flow conditions.

Aanes, Magne; Kippersund, Remi André; Lohne, Kjetil Daae; Frøysa, Kjell Eivind; Lunde, Per. 2017, Journal of the Acoustical Society of America. NORCE, HVL, DIVNORSK, UIBVitenskapelig artikkel
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