EFFECT OF HYDROGEN BLENDING INTO THE THERMOPHYSICAL PROPERTIES OF NATURAL GAS

Today, renewable energy can be stored as hydrogen thanks to technology.
Further, natural gas networks can be used to transport and end-use hydrogen without building
special infrastructure. However, changes in the thermos physical properties of the mixture of
hydrogen and NG can affect the operation of measuring devices, accessories and final equipment.
Therefore, in this paper, we study the effect of hydrogen addition on the thermophysical
properties of SGs from gas fields of various compositions. According to calculations, the
maximum allowable concentration of hydrogen is 10%. The study of the most important
characteristics of the mixture was carried out, and it was found that the injection of hydrogen
into SG increases the upper and lower ignition limits and the compressibility coefficient, as well as
lower and higher heating values, lower and higher Wobbe indices, and the relative density
decreases with increasing hydrogen concentration.

Jurnal nomiTechnical science and innovation
Nashr soni2023, №1(15)
Ko'rishlar soni 99

Internet havola

DOI

UzSCI tizimida yaratilgan sana 25-04-2023

O'qishlar soni 99

Nashr sanasi 20-04-2023

Asosiy tilIngliz

Sahifalar121-128

Kalit so'z

gas network

hydrogen blending

compressible

higher heating value

lower heating value

English

Today, renewable energy can be stored as hydrogen thanks to technology.
Further, natural gas networks can be used to transport and end-use hydrogen without building
special infrastructure. However, changes in the thermos physical properties of the mixture of
hydrogen and NG can affect the operation of measuring devices, accessories and final equipment.
Therefore, in this paper, we study the effect of hydrogen addition on the thermophysical
properties of SGs from gas fields of various compositions. According to calculations, the
maximum allowable concentration of hydrogen is 10%. The study of the most important
characteristics of the mixture was carried out, and it was found that the injection of hydrogen
into SG increases the upper and lower ignition limits and the compressibility coefficient, as well as
lower and higher heating values, lower and higher Wobbe indices, and the relative density
decreases with increasing hydrogen concentration.

Kalit so'z

gas network

hydrogen blending

compressible

higher heating value

lower heating value

№ Muallifning F.I.Sh. Lavozimi Tashkilot nomi

1 Abdivakhidova N.A. researcher 1Turin Polytechnic University in Tashkent

№ Havola nomi

1 European Commission. Energy roadmap 2050. COM/2011/0885; 2011

2 IEA (International Energy Agency). “World energy outlook. Paris, France”, 2012.

3 IEA (International Energy Agency). ETP – Energy technology perspectives. “Paris, France: OECD/IEA”, 2012.

4 IEA (International Energy Agency). “Technology roadmap bioenergy for heat and power”, 2012.

5 A. Bull. “Bio methane regions EU project – final report. www.biomethaneregions.eu/”, 2014

6 F. van Foreest. Perspectives for biogas in Europe. http://www. oxfordenergy.org/wpcms/wp-content/uploads/2012/12/NG-70.pdf”, 2015.

7 IEA (International Energy Agency). “Harnessing variable renewables: a guide to the balancing challenge”, 2011.

8 IEA (International Energy Agency). “Gas medium-term market report”, 2012.

9 O. Florisson. Natural Hy – Preparing for the hydrogen economy by using the existing natural gas system. “The European gas research group (www.gerg.eu) tem as a catalyst; an integrated project, final publishable activity report”, http://www.naturalhy.net/

10 M. Lehner., R. Tichler., H. Steinmüller., M. Koppe. Power-to-gas: technology and business models. “Springer International Publishing”, doi: https://doi.org/10.1007/978-3-319- 03995-4. 2014.

11 S. Schiebahn., T. Grube., M. Robinius., L. Zhao., A. Otto., B. Kumar., D. Stolten., V. Scherer Power to Gas Transit. “To renew energy system. Wenham, Germany”, 2013. 813. doi:10.1002/9783527673872.ch39.

12 M. Pourramezan., S.I. Pishbin., S. Pakseresht. “Improved hydrogen-natural gas combustion: a technical review. Tenth mediterr. Combust. Sump”, Napoli, Italy. 2017.

13 M. Schmidt., M.C. Steinbach., B.M. Willert. “High detail stationary optimization models for gas networks”, 2015. 131.

14 J. Kralik., E.B. Wylie., V.L. Streeter. Dynamic modelling of large scale networks with application to gas distribution. “Elsevier. Fluid transients, New York”, 1978.

15 M. Schmidt., M.C. Steinbach., B.M. Willert. “High detail stationary optimization models for gas networks”, 2015. 131.

16 Standard practice for calculating heat value. “Compressibility factor and relative density of gaseous fuels. Philadelphia”, 2017.

17 D. Haeseldonckx., W. D’haeseleer. The use of the natural-gas pipeline infrastructure for hydrogen transport in a changing market structure. “International journal hydrogen energy”, 2007. doi:https://doi.org/10.1016/j.ijhydene.2006.10.018.

18 K.S. Chapman., A. Patil. Performance efficiency and emissions characterization of reciprocating internal combustion engines fueled with hydrogen. “Natural gas blends”, 2008.

19 T. Parameswaran., P. Gogolek., P. Hughes. “Estimation of combustion air requirement and heating value of fuel gas mixtures from flame spectra”, doi:https://doi.org/10.1016/j.applthermaleng. 2014

20 J.A. Schouten., J.P. Michels., J. van Rosmalen. Effect of H2-injection on the thermodynamic and transportation properties of natural gas. “International journal hydrogen energy”, doi:https://doi.org/10.1016/j.ijhydene.2003.

21 H. de Vries., A.V. Mokhov., H.B. Levinsky. The impact of natural gas/hydrogen mixtures on the performance of end-use equipment: Interchangeability analysis for domestic appliances. “Apply Energy”, 2017. doi: https://doi.org/10.1016/j.apenergy.2017.09.049.

22 D. Haeseldonckx., W. D’haeseleer. The use of the natural-gas pipeline infrastructure for hydrogen transport in a changing market structure. “International journal hydrogen energy”, 2007. 32:1381–6. doi:https://doi.org/10.1016/j.ijhydene.2006.10.018.

23 Y. Zhao., V. McDonnell., S. Samuelsen. Influence of hydrogen addition to pipeline natural gas on the combustion performance of a cooktop burner. “International journal of hydrogen energy”, 2019. 44. 10.1016/j.ijhydene.2019.03.100.

Kutilmoqda

№	Havola nomi
1	European Commission. Energy roadmap 2050. COM/2011/0885; 2011
2	IEA (International Energy Agency). “World energy outlook. Paris, France”, 2012.
3	IEA (International Energy Agency). ETP – Energy technology perspectives. “Paris, France: OECD/IEA”, 2012.
4	IEA (International Energy Agency). “Technology roadmap bioenergy for heat and power”, 2012.
5	A. Bull. “Bio methane regions EU project – final report. www.biomethaneregions.eu/”, 2014
6	F. van Foreest. Perspectives for biogas in Europe. http://www. oxfordenergy.org/wpcms/wp-content/uploads/2012/12/NG-70.pdf”, 2015.
7	IEA (International Energy Agency). “Harnessing variable renewables: a guide to the balancing challenge”, 2011.
8	IEA (International Energy Agency). “Gas medium-term market report”, 2012.
9	O. Florisson. Natural Hy – Preparing for the hydrogen economy by using the existing natural gas system. “The European gas research group (www.gerg.eu) tem as a catalyst; an integrated project, final publishable activity report”, http://www.naturalhy.net/
10	M. Lehner., R. Tichler., H. Steinmüller., M. Koppe. Power-to-gas: technology and business models. “Springer International Publishing”, doi: https://doi.org/10.1007/978-3-319- 03995-4. 2014.
11	S. Schiebahn., T. Grube., M. Robinius., L. Zhao., A. Otto., B. Kumar., D. Stolten., V. Scherer Power to Gas Transit. “To renew energy system. Wenham, Germany”, 2013. 813. doi:10.1002/9783527673872.ch39.
12	M. Pourramezan., S.I. Pishbin., S. Pakseresht. “Improved hydrogen-natural gas combustion: a technical review. Tenth mediterr. Combust. Sump”, Napoli, Italy. 2017.
13	M. Schmidt., M.C. Steinbach., B.M. Willert. “High detail stationary optimization models for gas networks”, 2015. 131.
14	J. Kralik., E.B. Wylie., V.L. Streeter. Dynamic modelling of large scale networks with application to gas distribution. “Elsevier. Fluid transients, New York”, 1978.
15	M. Schmidt., M.C. Steinbach., B.M. Willert. “High detail stationary optimization models for gas networks”, 2015. 131.
16	Standard practice for calculating heat value. “Compressibility factor and relative density of gaseous fuels. Philadelphia”, 2017.
17	D. Haeseldonckx., W. D’haeseleer. The use of the natural-gas pipeline infrastructure for hydrogen transport in a changing market structure. “International journal hydrogen energy”, 2007. doi:https://doi.org/10.1016/j.ijhydene.2006.10.018.
18	K.S. Chapman., A. Patil. Performance efficiency and emissions characterization of reciprocating internal combustion engines fueled with hydrogen. “Natural gas blends”, 2008.
19	T. Parameswaran., P. Gogolek., P. Hughes. “Estimation of combustion air requirement and heating value of fuel gas mixtures from flame spectra”, doi:https://doi.org/10.1016/j.applthermaleng. 2014
20	J.A. Schouten., J.P. Michels., J. van Rosmalen. Effect of H2-injection on the thermodynamic and transportation properties of natural gas. “International journal hydrogen energy”, doi:https://doi.org/10.1016/j.ijhydene.2003.
21	H. de Vries., A.V. Mokhov., H.B. Levinsky. The impact of natural gas/hydrogen mixtures on the performance of end-use equipment: Interchangeability analysis for domestic appliances. “Apply Energy”, 2017. doi: https://doi.org/10.1016/j.apenergy.2017.09.049.
22	D. Haeseldonckx., W. D’haeseleer. The use of the natural-gas pipeline infrastructure for hydrogen transport in a changing market structure. “International journal hydrogen energy”, 2007. 32:1381–6. doi:https://doi.org/10.1016/j.ijhydene.2006.10.018.
23	Y. Zhao., V. McDonnell., S. Samuelsen. Influence of hydrogen addition to pipeline natural gas on the combustion performance of a cooktop burner. “International journal of hydrogen energy”, 2019. 44. 10.1016/j.ijhydene.2019.03.100.