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Agnès JANÈS, Jérôme LESAGE, Benno WEINBERGER , Douglas CARSON, Bruno DEBRAY

EXPERIMENTAL DETERMINATION OF MINIMUM IGNITION CURRENT (MIC) FOR HYDROGEN /METHANE MIXTURES FOR THE DETERMINATION OF THE EXPLOSION GROUP CORRESPONDING TO IEC 60079-20-1 STANDARD. Agnès JANÈS, Jérôme LESAGE, Benno WEINBERGER , Douglas CARSON, Bruno DEBRAY.

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Agnès JANÈS, Jérôme LESAGE, Benno WEINBERGER , Douglas CARSON, Bruno DEBRAY

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  1. EXPERIMENTAL DETERMINATION OF MINIMUM IGNITION CURRENT (MIC) FOR HYDROGEN /METHANE MIXTURES FOR THE DETERMINATION OF THE EXPLOSION GROUP CORRESPONDING TO IEC 60079-20-1 STANDARD Agnès JANÈS, Jérôme LESAGE, Benno WEINBERGER, Douglas CARSON, Bruno DEBRAY

  2. « Power to Gas » – one flexible solution Value of green electricity as chemicals, H2 or CH4 Mobility Take advantage of low price of electricity on the markets, caused by overproduction of intermittent electricity at low marginal cost, to produce add value gas fuels (hydrogen or methane synthesis) which can be easily stored and transported in the existing natural gas infrastructures. Residential Distribution & Transport network Intermittent electricity Electrolysis & storage Admix NG or Methnation Industry CO2 NG CH4 NG+H2 H2 H2 NG grid stakeholders expect that blends up to 20% seem to be a realistic scenario.

  3. Choice of equipment - ATEX regulation • => The knowledge of the gas group for these hydrogen/NG (H2NG) mixtures is a necessary information for the choice of equipment and protective systems intended for the use in potentially explosive atmospheres

  4. IEC 60079-20-1 standard propose two methods to classify in a gas group • 1st Method: determination of maximum experimental safe gap (MESG) • The MESG of flammable gases and vapors is the lowest value of the safe gap measured according to IEC 60079-20-1 • The MESG is measured in mm Gas

  5. 2nd method: determination of minimum ignition current (MIC) ratio • The experimental device consists of a spark test apparatus and an explosion chamber that is filled continuously with the gas to be tested • The MIC ratio results are dimensionless, obtained by dividing the MIC of gas tested by the value of MIC of pure methane Electrode holder Cadmium disc Used spark test apparatus compliant to Annex B of IEC 60079-11 standard

  6. (1) Criteria used for classification of gases in gas groups according to IEC 60079-20-1

  7. (2) Criteria used for classification of gases in gas groups according to IEC 60079-20-1 • => These criteria indicate that exclusively MIC ratio values are sufficient to assign a gas mixture into a gas group for the following cases: • Group IIA: MIC ratio > 0.9 • Group IIB: 0.5 ≤ MIC ratio ≤ 0.8 • Group IIC: MIC ratio < 0.45 • Concerning the case of methane/hydrogen mixtures, the IEC 60079-20-1 standard gives the following statement to determine the gas group: • Natural gas is classified as Group IIA, for less than 25 vol.% of hydrogen • The threshold of 25 vol.% hydrogen is validated by several MESG measurements in literature, but no so with the MIC ratio. • Therefore the main aim of this work was the experimental determination of MIC and MIC ratios, with respect to the MIC of pure methane, of methane/hydrogen mixtures up to 20 vol.% of hydrogen.

  8. MIC ranges obtained on methane/hydrogen mixtures tested The MIC measurements were performed on each of the 10 methane/hydrogen mixtures containing from 2 to 20 vol.% of hydrogen.

  9. MIC ratio, as a function of hydrogen content in the methane/hydrogen mixtures The linear least squares regression shows a very good correlation between the MIC ratio and the hydrogen content in the methane/hydrogen mixture

  10. Conclusion • The application of gas classification criteria in terms of MIC ratio from IEC 60079-20-1 standard leads to the following classification: • Methane/hydrogen mixtures containing 2, 4 and 6 vol.% of hydrogen: • Group IIA, as MIC ratio is greater than 0.9, • Methane/hydrogen mixtures containing 8, 10, 12 and 14 vol.% of hydrogen: • the determination of MESG is necessary to conclude if these mixtures are classified in Group IIA or IIB, as MIC ratio is comprised between 0.8 and 0.9 • Methane/hydrogen mixtures containing 16, 18 and 20 vol.% of hydrogen: • Group IIB, as MIC ratio is lower than 0.8. • => The last result appears in contradiction with the statement of IEC 60079-20-1, providing a classification in Group IIA up to 25 vol.% of hydrogen. • Therefore the IEC TC 31 decided a campaign of MIC ratio in different labs to adapt the future standard IEC 80079-20-1 replacing the IEC 60079-20-1

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