ORIGINAL_ARTICLE
Comprehensive Review of the Effect of Reactor Input Temperature Changes and Unit Capacity on Gasoline Octane Number
As mentioned above, the most important factors and parameters affecting the gasoline product octane number are the input temperature of the reactors and the capacity of the catalytic converter unit. Therefore, considering the importance of these factors and their widespread use in different operating conditions of the operating unit, the study and preparation of information and complete and comprehensive results in this regard for the use of staff at the time of occurrence of each various operating conditions seems necessary and essential. This study was carried out in a fixed mass of 200 gr/hr with a purity of 90% and a stabilization of 3.5% of the coke formed on the catalyst. The main difference between this experiment and the preceding ones is the number and method of introducing and using the variables and their display.
https://www.jeires.com/article_127082_60a5b6a17f1b52403642d785449e7249.pdf
2021-06-01
113
118
10.22034/jeires.2021.269061.1019
Octan Number
Purity
Gasoline
staff at the time
Ali
Esmi Kamal
ali.kamal.iraq2021@gmail.com
1
Department of Environmental Civil Engineering-Water and Wastewater Engineering, Babel University, Iraq
LEAD_AUTHOR
[1]. K. Lo Han, Journal of Engineering in Industrial Research., 2021, 2, 123-133
1
[2]. A. Ahmad, A. Sadrodin Reyazi, Journal of Engineering in Industrial Research., 2021, 2, 134-160.
2
[3]. B. Barmasi, Journal of Engineering in Industrial Research., 2021, 2, 161-169.
3
[4]. M. Amirikoshkeki, Journal of Engineering in Industrial Research., 2021, 2, 170-178.
4
[5]. M. Bagherisadr, Journal of Engineering in Industrial Research., 2021, 2, 179-185.
5
[6]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial cells, nanomedicine, and biotechnology, 2019, 47, 3222-3230.
6
[7]. A. Samimi, M. Samimi, Journal of Engineering in Industrial Research., 2021, 2, 1-6.
7
[8]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Nashrieh Shimi va Mohandesi Shimi Iran, 2009, 27, 59-68.
8
[9]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Iranian Journal of Chemical Engineering, 2009, 6, 73-86.
9
[10]. A. Bozorgian, S. Zarinabadi, A. Samimi, Journal of Chemical Review, 2020, 2, 122-129.
10
[11]. A. Bozorgian, Journal of Engineering in Industrial Research, 2020, 1, 99-110.
11
[12]. M. Bagheri sadr, A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 252-261.
12
[13]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 241-251.
13
[14]. E. Amouzad Mahdiraji, M. Sedghi Amiri, Journal of Engineering in Industrial Research., 2021, 2, 7-16.
14
[15]. R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
15
[16]. R.Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
16
[17]. R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 247-253.
17
[18]. S. Salehi-Kordabadi, S. Karimi, M. Qorbani-Azar, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 21-36.
18
[19]. M.R. Rahnama, M. Ajza Shokouhi, A. Heydari, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 37-49.
19
[20]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 229-240.
20
[21]. A. Bozorgian, N.M. Nasab, H. Mirzazadeh, World Academy of Science, Engineering and Technology International Journal of Materials and Metallurgical Engineering, 2011 ,5, 21-24.
21
[22]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 205-218.
22
[23]. J. Mashhadizadeh, A. Bozorgian, A. Azimi, Eurasian Chemical Communications, 2020, 2, 536-547.
23
[24]. Gabriel A. Ayeni, Journal of Engineering in Industrial Research., 2021, 2,17-21.
24
[25]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
25
[26]. S. Hashem, Journal of Engineering in Industrial Research, 2021, 2, 44-55.
26
[27]. A. Bozorgian, Z. Arab Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Eurasian Chemical Communications, 2020, 2 (3), 420-426.
27
[28]. Akhtarian zand, Journal of Engineering in Industrial Research., 2021, 2, 22-27.
28
[29]. K. Malmal, N. Shiri, Journal of Engineering in Industrial Research., 2021, 2, 28-35.
29
[30]. Z. Torabi, Journal of Engineering in Industrial Research., 2021, 2, 36-43.
30
[31]. Y. Kamyabi, M. Salahinejad, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 50-62.
31
[32]. S. Delavari, H. Mohammadi Nik, N. Mohammadi, A. Samimi, S.Y. Zolfegharifar, F. Antalovits, L. Niedzwiecki, R. Mesbah, Chemical Methodologies, 2021, 5, 178-189.
32
[33]. A. Samimi, S. Zarinabadi, A.H. Shahbazi Kootenaei, A. Azimi, M. Mirzaei, South African Journal of Chemical Engineering., 2020, 31, 44-50.
33
[34]. S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
34
[35]. A. Samimi, Progress in Chemical and Biochemical Research, 2020, 3, 140-146.
35
[36] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 239-246.
36
ORIGINAL_ARTICLE
Management of Urban Energy System Based on the Use of Train Model in CHP Systems
Prior to the use of fossil fuels, urban energy was supplied through biomass sources, mainly wood and coal. The sources of these materials had to be located in a certain area around the city. The limitations of these resources, along with the limitations of water and food, limited the size of the city and its potential for expansion. The required electricity was generated regionally and sporadically. The first generators of electricity were steam engines, but gradually they were replaced by internal combustion engines. Over time, with the development of distributed networks, problems arose. Researches and reports were published that expressed the disadvantages of this method and suggested that the national network be constructed and all local networks be connected to it. Cooling of power plants, their construction inside the cities were not cost-effective, so the power plants were moved to areas with easier access to fuel and water, and centralized power plants were developed. Therefore, the electricity reached the end consumer through the global electricity transmission and distribution network. The fuels used for transportation are transported in the same way that they are used today, that is, using tanks and being delivered to the consumer at gas stations. This paper proposes using new technologies to produce power. In this paper, the train method has been used to simulate the energy consumption in cogeneration systems. The results of the analysis indicates that the use of small sized steam boilers reduces the overall cost of small-sized as well as average-sized generators
https://www.jeires.com/article_129819_f5630479d12f7d3a34a88fcc496284e1.pdf
2021-06-01
119
128
10.22034/jeires.2021.281537.1035
energy consumption
Train Model
cogeneration
Fariborz
Ahmadi Daryakenari
fariborz9271@gmail.com
1
Department of Energy Systems Engineering, Mahmood Abad Faculty of Marine Science, Petroleum University of Technology, Iran
LEAD_AUTHOR
Hamidreza
Nasiri
hamidreza.nassirii@gmail.com
2
Department of Energy Systems Engineering, Mahmood Abad Faculty of Marine Science, Petroleum University of Technology, Iran
AUTHOR
[1]. K. Lo Han, Journal of Engineering in Industrial Research., 2021, 2, 123-133
1
[2]. A. Ahmad, A. Sadrodin Reyazi, Journal of Engineering in Industrial Research., 2021, 2, 134-160.
2
[3]. B. Barmasi, Journal of Engineering in Industrial Research., 2021, 2, 161-169.
3
[4]. M. Amirikoshkeki, Journal of Engineering in Industrial Research., 2021, 2, 170-178.
4
[5]. M. Bagherisadr, Journal of Engineering in Industrial Research., 2021, 2, 179-185.
5
[6]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial cells, nanomedicine, and biotechnology, 2019, 47, 3222-3230.
6
[7]. A. Samimi, M. Samimi, Journal of Engineering in Industrial Research., 2021, 2, 1-6.
7
[8]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Nashrieh Shimi va Mohandesi Shimi Iran, 2009, 27, 59-68.
8
[9]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Iranian Journal of Chemical Engineering, 2009, 6, 73-86.
9
[10]. A. Bozorgian, S. Zarinabadi, A. Samimi, Journal of Chemical Review, 2020, 2, 122-129.
10
[11]. S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
11
[12]. A. Samimi, Progress in Chemical and Biochemical Research, 2020, 3, 140-146.
12
[13] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 239-246.
13
[14]. Y. Kamyabi, M. Salahinejad, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 50-62.
14
[15]. R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
15
[16]. R.Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
16
[17]. R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 247-253.
17
[18]. S. Salehi-Kordabadi, S. Karimi, M. Qorbani-Azar, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 21-36.
18
[19]. M.R. Rahnama, M. Ajza Shokouhi, A. Heydari, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 37-49.
19
[20]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 229-240.
20
[21]. A. Bozorgian, N.M. Nasab, H. Mirzazadeh, World Academy of Science, Engineering and Technology International Journal of Materials and Metallurgical Engineering, 2011 ,5, 21-24.
21
[22]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 205-218.
22
[23]. J. Mashhadizadeh, A. Bozorgian, A. Azimi, Eurasian Chemical Communications, 2020, 2, 536-547.
23
[24]. Gabriel A. Ayeni, Journal of Engineering in Industrial Research., 2021, 2,17-21.
24
[25]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
25
[26]. S. Hashem, Journal of Engineering in Industrial Research, 2021, 2, 44-55.
26
[27]. A. Bozorgian, Z. Arab Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Eurasian Chemical Communications, 2020, 2 (3), 420-426.
27
[28]. Akhtarian zand, Journal of Engineering in Industrial Research., 2021, 2, 22-27.
28
[29]. K. Malmal, N. Shiri, Journal of Engineering in Industrial Research., 2021, 2, 28-35.
29
[30]. Z. Torabi, Journal of Engineering in Industrial Research., 2021, 2, 36-43.
30
ORIGINAL_ARTICLE
Simulation and Optimization of the Urban Energy System based on the Combination of Technologies and Energy Production and Distribution Network
Cogeneration systems have potential limitations: Because the heat recycled in these systems is a function of mechanical load (electricity), mismatch between power and heat consumption can lead to energy loss and reduced efficiency. On the other hand, partial loading of the engine or turbine reduces its mechanical efficiency and exergy of the exhaust gas. Therefore, meeting a specific consumer demand, requires optimization of the system in order to maximize the efficiency of the entire energy system of the city as well as a system management model. The performance of the cogeneration system in cities is limited for several reasons. For example, restrictions on the release of air pollutants and noise pollution may allow equipment to be installed in the suburbs instead of city centers, or to use smaller, more limited-capacity equipment. Similarly, the lack of space (land for installation of equipment) creates constraints in areas where the population and building texture is dense. Such restrictions may lead to the use of smaller power plants and equipment, which are less efficient than large equipment and require more initial investment (cost relative to MW output). In this paper, the effect of such constraints on the urban energy system is quantitatively investigated and the optimal model for the sample city is presented.
https://www.jeires.com/article_129850_74d7cedafd3b375dec856a4bbfa932c2.pdf
2021-06-01
129
148
10.22034/jeires.2021.281603.1036
Cogeneration Systems
Urban Energy Consumption
Air pollution
Hamidreza
Nasiri
hamidreza.nassirii@gmail.com
1
Department of Energy Systems Engineering, Mahmood Abad Faculty of Marine Science, Petroleum University of Technology, Iran
LEAD_AUTHOR
Fariborz
Ahmadi Daryakenari
fariborz9271@gmail.com
2
Department of Energy Systems Engineering, Mahmood Abad Faculty of Marine Science, Petroleum University of Technology, Iran
AUTHOR
[1]. K. Lo Han, Journal of Engineering in Industrial Research., 2021, 2, 123-133
1
[2]. A. Ahmad, A. Sadrodin Reyazi, Journal of Engineering in Industrial Research., 2021, 2, 134-160.
2
[3]. B. Barmasi, Journal of Engineering in Industrial Research., 2021, 2, 161-169.
3
[4]. M. Amirikoshkeki, Journal of Engineering in Industrial Research., 2021, 2, 170-178.
4
[5]. M. Bagherisadr, Journal of Engineering in Industrial Research., 2021, 2, 179-185.
5
[6]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial cells, nanomedicine, and biotechnology, 2019, 47, 3222-3230.
6
[7]. A. Samimi, M. Samimi, Journal of Engineering in Industrial Research., 2021, 2, 1-6.
7
[8]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Nashrieh Shimi va Mohandesi Shimi Iran, 2009, 27, 59-68.
8
[9]. A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Iranian Journal of Chemical Engineering, 2009, 6, 73-86.
9
[10]. A. Bozorgian, S. Zarinabadi, A. Samimi, Journal of Chemical Review, 2020, 2, 122-129.
10
[11]. S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
11
[12]. A. Samimi, Progress in Chemical and Biochemical Research, 2020, 3, 140-146.
12
[13] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 239-246.
13
[14]. Y. Kamyabi, M. Salahinejad, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 50-62.
14
[15]. R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
15
[16]. R.Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
16
[17]. R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 247-253.
17
[18]. S. Salehi-Kordabadi, S. Karimi, M. Qorbani-Azar, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 21-36.
18
[19]. M.R. Rahnama, M. Ajza Shokouhi, A. Heydari, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 37-49.
19
[20]. A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 229-240.
20
[24]. Gabriel A. Ayeni, Journal of Engineering in Industrial Research., 2021, 2,17-21.
21
[25]. F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
22
[26]. S. Hashem, Journal of Engineering in Industrial Research, 2021, 2, 44-55.
23
[27]. A. Bozorgian, Z. Arab Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Eurasian Chemical Communications, 2020, 2 (3), 420-426.
24
[28]. Akhtarian zand, Journal of Engineering in Industrial Research., 2021, 2, 22-27.
25
[29]. K. Malmal, N. Shiri, Journal of Engineering in Industrial Research., 2021, 2, 28-35.
26
[30]. Z. Torabi, Journal of Engineering in Industrial Research., 2021, 2, 36-43.
27
ORIGINAL_ARTICLE
Optimization of corrosion information in oil and gas wells using electrochemical experiments
Corrosion reactions are often complex heterogeneous reactions that are accelerated by the interaction of factors such as a) ordinary kinetic considerations (such as activation energy), b) the chemical composition of the electrolyte, c) the mass transfer between the electrolyte and the metal surface. D) Different surface effects such as surface adsorption, repellency and surface hardness are identified. The interactions between these factors make it difficult to reproduce electrochemical data or the exact conditions that cause a metal to be eaten. These are experimental factors that should be considered when testing corrosion (measurements) and test batteries. Ignoring these factors can produce data that do not provide the true corrosion behavior of the test metal under study. In this paper, the relationship between inherent corrosion measurement errors and suggestions on how to handle the variability of electro data A chemical solution is provided.
https://www.jeires.com/article_130040_026d6c0b4775a28d6e5a976a9ef4ff01.pdf
2021-06-01
149
155
10.22034/jeires.2021.278003.1032
Corrosion reactions
Interaction rate
activation energy
Electrochemical data
Minoo
Akhtarian zand
minoo.akhzand1983@gmail.com
1
Department of Environmental Engineering-Water and Wastewater Engineering, Qatar University, Qatar
LEAD_AUTHOR
[1] K. Lo Han, Journal of Engineering in Industrial Research. 2021, 2, 123-133.
1
[2] A. Ahmad, A. Sadrodin Reyazi, Journal of Engineering in Industrial Research. 2021, 2, 134-160.
2
[3] M. Amirikoshkeki, Journal of Engineering in Industrial Research. 2021, 2, 170-178.
3
[4] M. Bagherisadr, Journal of Engineering in Industrial Research. 2021, 2, 179-185.
4
[5] A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Iranian Journal of Chemical Engineering, 2009, 6, 73-86.
5
[6] K. Malmal, N. Shiri, Journal of Engineering in Industrial Research. 2021, 2, 28-35.
6
[7] Z. Torabi, Journal of Engineering in Industrial Research. 2021, 2, 36-43.
7
[8] J. Mashhadizadeh, A. Bozorgian, A. Azimi, Eurasian Chem. Commun., 2020, 2, 536-547.
8
[9] A. Bozorgian, N.M. Nasab, H. Mirzazadeh, World Academy of Science, Engineering and Technology International Journal of Materials and Metallurgical Engineering, 2011 ,5, 21-24.
9
[10] A. Samimi, S. Zarinabadi, A.H. Shahbazi Kootenaei, A. Azimi, M. Mirzaei, South African Journal of Chemical Engineering., 2020, 31, 44-50.
10
[11] M.E. Bidhendi, Z. Asadi, A. Bozorgian, A. Shahhoseini, M.A. Gabris, Environmental Progress & Sustainable Energy., 2020, 39, 13306.
11
[12] A. Samimi, S. Zarinabadi, A.H. Shahbazi Kootenaei, A. Azimi, M. Mirzaei, Eurasian Chemical Communications., 2020, 2, 150-161.
12
[13] A. Samimi, Progress in Chemical and Biochemical Research. 2020, 3, 140-146.
13
[14] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial cells, nanomedicine, and biotechnology, 2019, 47, 3222-3230.
14
[15] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
15
[16] S. M. S. Mirnezami, F. Zare Kazemabadi, A. Heydarinasab, Progress in Chemical and Biochemical Research, 2021, 4, 191-206.
16
[17] M. Torkaman, F. Z. Kazemabadi, Oriental Journal of Chemistry, 2017, 33, 1976-1984.
17
[18] R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
18
[19] R. Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
19
[20] S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
20
[21] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 247-253.
21
[22] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 239-246.
22
[23] R. Rahimiyan, Journal of Engineering in Industrial Research, 2021, 2, 95-112.
23
[24] K.K. Dolisgan, Y. Razisni, Journal of Critical Reviews, 2020, 7 (19), 9899-9906
24
[25] Y. Raziani, S. Raziani, Journal of Chemical Reviews, 2021, 3 (1), 83-96.
25
[26] Y. Raziani, S. Raziani, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9(4), 262-280.
26
ORIGINAL_ARTICLE
Investigation and Evaluation of Executive Quality of Drilling Machines in Iran's Oil Industry
With the advancement of science and progress in the construction of drilling machines, the widespread use of drilling machines instead of fire operations for underground drilling has become widely used. In mechanized drilling, tools and machines are used to dig underground spaces and its main goal is to achieve high speed in the construction and digging of these spaces. Drilling operation is one of the costliest operations in underground excavations. On the other hand, there is a lot of limitation in choosing a drilling machine, or in other words, there is no flexibility in choosing a drilling machine, i.e. in one project, using several drilling machines is less used due to economic discussion and high cost of drilling machines. Therefore, the type of machine and drilling machinery must be specified before the operation. In choosing the type of drilling machine, its study and efficiency is one of the most important factors. As a result, studying the performance and efficiency of each drilling machine is one of the most vital factors in underground excavations. Here, the discussion is not about the determining factors in choosing the type of device, but the performance of intestinal drilling rig and TBM has been studied separately.
https://www.jeires.com/article_130063_f6a896abe2ad42c2ba8026e9b6de720c.pdf
2021-06-01
156
165
10.22034/jeires.2021.278113.1033
drilling machine
Oil Industry
performance
TBM
Economics
Minoo
Akhtarian zand
minoo.akhzand1983@gmail.com
1
Department of Environmental Engineering-Water and Wastewater Engineering, Qatar University, Qatar
LEAD_AUTHOR
Sergey
Brindred
sergay.uop@gmail.com
2
Department of Environmental Engineering-Water and Wastewater Engineering, Moscow University, Russia
AUTHOR
[1] G. Korshin, H. Liu, Environmental Science: Water Research and Technology, 2019, 5, 1262-1269.
1
[2] R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
2
[3] A. Schreiner-McGraw, H. Ajami, Water Resources Research, 2020, 56, e2020WR027639.
3
[4] Y. Jeong, S. Hermanowicz, C. Park, Water Research, 2017, 123, 86-95.
4
[5] H. Klammler, J. Jawitz, M. Annable1, J. Yaquian, K. Hatfield, P. Burger, Journal of Hydrology, 2020, 582, 124514.
5
[6] W. Wang, N. Themelis, K. Sun, A. Bourtsalas, Q. Huang, Y. Zhang, Z. Wu, Waste Disposal & Sustainable Energy, 2019, 1, 67-78.
6
[7] D. Ford, C. Wolf, Journal of Management in Engineering, 2020, 36, 04020027.
7
[8] J. Wang, D. Schlenk, J. Gan, Environmental Science and Technology Letters, 2019, 6, 148-152.
8
[9] H. Klammler, P. Rao, K. Hatfield, Environment Systems and Decisions, 2018, 38, 140-159.
9
[10] N. Gupta, M. Kluge, P. Chadik, T. Townsend, Waste Management, 2018, 72, 354-361.
10
[11] R. Anderson, X. Zhang, T. Skaggs, Vadose Zone Journal, 2017,16, 1-9.
11
[12] R. Rodriguez, D. Contrino, D. Mazyck. Industrial and Engineering Chemistry Research, 2020, 59, 17740-17747.
12
[13] A. Edalat, E. Hoek, Water (Switzerland), 2020, 12, 1850.
13
[14] R. Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
14
[15] Y. Yoon, M. Dodd, Y. Lee, Environmental Science: Water Research and Technology, 2018, 4, 1239-1251.
15
[16] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial cells, nanomedicine, and biotechnology, 2019, 47, 3222-3230.
16
[17] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
17
[18] S. M. S. Mirnezami, F. Zare Kazemabadi, A. Heydarinasab, Progress in Chemical and Biochemical Research, 2021, 4, 191-206.
18
[19] R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
19
[20] R. Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
20
[21] S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
21
[22] M. Torkaman, F. Z. Kazemabadi, Oriental Journal of Chemistry, 2017, 33, 1976-1984.
22
[23] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 247-253.
23
[24] R. Rahimiyan, Advanced Journal of Chemistry, 2020, 2, 239-246.
24
[25] R. Rahimiyan, Journal of Engineering in Industrial Research, 2021, 2, 95-112.
25
[26] K.K. Dolisgan, Y. Razisni, Journal of Critical Reviews, 2020, 7 (19), 9899-9906
26
[27] Y. Raziani, S. Raziani, Journal of Chemical Reviews, 2021, 3 (1), 83-96.
27
[28] Y. Raziani, S. Raziani, International Journal of Advanced Studies in Humanities and Social Science, 2020,9(4), 262-280.
28
[29] M. Kayhanian, M. Stenstrom, Journal of Water and Wastewater, 2021, 31, 12-26.
29
[30] M. Falinski, E. Albalghiti, A. Backhaus, J. Zimmerman, ChemSusChem, 2021, 14, 898-908.
30
[31] L. Stadler, N. Love, Environmental Science and Technology, 2019, 53, 1918-1927.
31
[32] J. Lund, Civil Engineering and Environmental Systems, 2020, 37, 183-196.
32
[33] G. Sahoo, A. Forrest, S. Schladow, J. Reuter, R. Coats, M. Dettinger, Limnology and Oceanography, 2016, 61, 496–507.
33
[34] S. Hameed, R. Riffat, B. Li, I. Naz, M. Badshah, S. Ahmed, N. Ali, Journal of Chemical Technology and Biotechnology, 2019, 94, 1816-1831.
34
[35] S. Plata, A. Childress, Desalination, 2019, 464, 51-56.
35
[36] D. Weissbrodt, M. Winkler, G. Wells, Environmental Science: Water Research and Technology, 2020, 6, 1952–1966.
36
ORIGINAL_ARTICLE
An Overview of Methane Gas Hydrate Formation
This article reviews the formation of methane gas hydrate. Gaseous hydrates are solid and crystalline grids of water molecules that are hydrogen bonded together and trap low molecular weight gas molecules in their cavities. The type of these gases depends on the gaseous composition of the environment. Methane of thermogenic and biogenic origin is the most common gas stored in gas hydrates and makes up about 99% of the gases that make up gas hydrates. Gaseous hydrates are very different from ice and, unlike ice under high pressure conditions, also form at temperatures above zero degrees Celsius. Understand the conditions under which gaseous hydrates are formed and remain stable to determine the extent. This source of energy is essential. Gaseous hydrates are very sensitive to environmental conditions and changes in pressure, temperature, water salinity, type and amount of saturated gas forming hydrate inside the pores of the sediment, cause the growth and stable conditions of gas hydrates. Gaseous hydrates are formed in systems that include water and gas, a network of water molecules (host molecules), paraffin’s such as methane, ethane, propane, isobutene, carbon dioxide, etc. (guest molecules). High pressures trap in their cavities. Gaseous hydrates are non-stoichiometric solids that are similar in appearance to ice (or snow) but completely different in structure.
https://www.jeires.com/article_129914_a54dcc79159dd70c8913f23db1ec7ff2.pdf
2021-06-01
166
177
10.22034/jeires.2021.277818.1030
hydrate
Methane
Sediment
Water
Carbon dioxide
Alireza
Bozorgian
a.bozorgian@mhriau.ac.ir
1
Department of Chemical Engineering, Mahshahr Branch, Islamic Azad University, Mahshahr, Iran
LEAD_AUTHOR
[1] R. Rahimiyan, Journal of Engineering in Industrial Research, 2021, 2, 95-112.
1
[2] A. Bozorgian, M. Ghazinezhad, Journal of Biochemical Technology, 2018, 2, 149-153.
2
[3] R. Rahimiyan, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2020, 2, 239-246.
3
[4] B. Raei, A. Bozorgian, Journal of Chemistry Letters, 2021, 1, 143-148.
4
[5] M. Amirikoshkeki, Journal of Engineering in Industrial Research. 2021, 2, 170-178.
5
[6] M. Bagheri Sadr, A. Bozorgian, Journal of Chemical Reviews, 2021, 3, 66-82.
6
[7] M. Bagherisadr, Journal of Engineering in Industrial Research. 2021, 2, 179-185.
7
[8] A. Bozorgian, Journal of Chemical Reviews, 2021, 3, 50-65.
8
[9] N. Kayedi, A. Samimi, M. Asgari Bajgirani, A. Bozorgian, South African Journal of Chemical Engineering, 2021, 35, 153-158.
9
[10] S.V. Mousavi, A. Bozorgian, N. Mokhtari, M.A. Gabris, H.R. Nodeh, Microchemical Journal, 2019, 145, 914-920.
10
[11] A. Bozorgian, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2021, 3, 54-61.
11
[12] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
12
[13] A. Bozorgian, A. Samimi, International Journal of New Chemistry, 2021, 8, 41-58.
13
[14] M. Bagheri sadr, A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 252-261.
14
[15] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial Cells, Nanomedicine, and Biotechnology., 2019, 47, 3222-3230.
15
[16] A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Nashrieh Shimi va Mohandesi Shimi Iran, 2009, 27, 59-68.
16
[17] A. Bozorgian, Journal of Engineering in Industrial Research, 2020, 1, 1-19.
17
[18] M. Torkaman, F. Zare Kazemabadi, Oriental Journal of Chemistry, 2017, 33, 197-?.
18
[19] A. Bozorgian, P. KHadiv Parsi, M.A. Mousavian, Iranian Journal of Chemical Engineering, 2009, 6, 73-86.
19
[20] A. Bozorgian, Progress in Chemical and Biochemical Research, 2020, 3, 169-179.
20
[21] R. Rahimiyan, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2020, 2, 247-253.
21
[22] K.K. Dolisgan, Y. Razisni, Journal of Critical Reviews, 2020, 7, 9899-9906.
22
[23] A. Bozorgian, Advanced Journal of Science and Engineering, 2020, 1, 34-39.
23
[24] J. Mashhadizadeh, A. Bozorgian, A. Azimi, Eurasian Chemical Communications, 2020, 2, 536-547.
24
[25] A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 205-218.
25
[26] S. Hashem, Journal of Engineering in Industrial Research, 2021, 2, 44-55.
26
[27] A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 241-251.
27
[28] A. Bozorgian, International Journal of Advanced Studies in Humanities and Social Science, 2020, 9, 229-240.
28
[29] A. Bozorgian, N.M. Nasab, H. Mirzazadeh, World Academy of Science, Engineering and Technology International Journal of Materials and Metallurgical Engineering, 2011, 5, 21-24.
29
[30] A. Bozorgian, Chemical Review and Letters, 2020, 3, 94-97.
30
[31] A. Bozorgian, Chemical Review and Letters, 2020, 3, 79-85.
31
[32] Y. Raziani, S. Raziani, Journal of Chemical Reviews, 2021, 3, 83-96.
32
[33] A. Bozorgian, S. Zarinabadi, A. Samimi, Chemical Methodologies, 2020, 4, 477-493.
33
[34]. A. Bozorgian, Z. Arab Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Progress in Chemical and Biochemical Research, 2020, 3, 31-38.
34
[35] A. Bozorgian, Journal of Engineering in Industrial Research, 2021, 2, 90-94.
35
[36] A. Bozorgian, Progress in Chemical and Biochemical Research, 2021, 4, 207-219.
36
[37] B. Raei, A. Bozorgian, Journal of Chemistry Letters, 2021, 1, 143-148.
37
[38] S. Nozariamini, R. Rahimiyan, S. Miryousefi ata, Progress in Chemical and Biochemical Research, 2020, 3, 377-389.
38
[39] A. Samimi, S. Zarinabadi, A.H. Shahbazi Kootenaei, A. Azimi, M. Mirzaei, South African Journal of Chemical Engineering, 2020, 31, 44-50.
39
[40] A. Bozorgian, Z. Arab Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Eurasian Chemical Communications, 2020, 2, 420-426.
40
[41] S.E. Mousavi, A. Bozorgian, International Journal of New Chemistry, 2020, 7, 195-219.
41
[42] A. Bozorgian, S. Zarinabadi, A. Samimi, Journal of Chemical Reviews, 2020, 2, 122-129.
42
[43] A. Samimi, S. Zarinabadi, A. Bozorgian, A. Amosoltani, Progress in Chemical and Biochemical Research, 2020, 3, 46-54.
43
[44] A. Bozorgian, Z.A. Aboosadi, A. Mohammadi, B. Honarvar, A. Azimi, Journal of Chemical and Petroleum Engineering, 2020, 54, 73-81.
44
[45] A. Bozorgian, Journal of Engineering in Industrial Research, 2020, 1, 99-110.
45
[46] A. Surendar, A. Bozorgian, A. Maseleno, L.K. Ilyashenko, M. Najafi, Inorganic Chemistry Communications, 2018, 96, 206-210.
46
[47] A. Bozorgian, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2020, 2, 91-101.
47
[48] A. Bozorgian, Polymer. 2012, 2, 12923-12929.
48
[49] A. Pourabadeh, B. Nasrollahzadeh, R. Razavi, A. Bozorgian, M. Najafi, Journal of Structural Chemistry, 2018, 59, 1484-1491.
49
[50] M.E. Bidhendi, Z. Asadi, A. Bozorgian, A. Shahhoseini, M.A. Gabris, Environmental Progress & Sustainable Energy., 2020, 39, 13306.
50
[51] Y. Raziani, S. Raziani, International Journal of Advanced Studies in Humanities and Social Science, 2020,9, 262-280.
51
[52] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial Cells, Nanomedicine, and Biotechnology, 2019, 47, 3222-3230.
52
[53] R. Rahimiyan, Progress in Chemical and Biochemical Research, 2020, 3, 329-339.
53
[54] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
54
[55] R. Rahimiyan, S. Zarinabadi, Progress in Chemical and Biochemical Research, 2020, 3, 251-268.
55
[56] S. M. S. Mirnezami, F. Zare Kazemabadi, A. Heydarinasab, Progress in Chemical and Biochemical Research, 2021, 4, 191-206.
56
[57] M. Torkaman, F. Z. Kazemabadi, Oriental Journal of Chemistry, 2017, 33, 1976-1984.
57
ORIGINAL_ARTICLE
Evaluation of V2G System in Electric Vehicle and DC Charging System
With an increasing number of electricity companies’ subscribers, the necessity of restructuring these systems is an important issue that cannot be overlooked. In this regard, a solution that has become interesting subject for network designers is the evolution of the traditional power grids into intelligent power grids. One of the influential elements in these networks is electric vehicles, which are considered by both researchers and consumers. They are Eco-friendly and provide the needed comfort. Given the fact that the presence of these vehicles is growing in the networks, an important challenge which is posed is their exploitation as an actor in the secondary services market of the power networks. So that it is possible to achieve peak shaving in the power system by optimally scheduling the charging and discharging time of these vehicles. In this paper, PSO and ACO algorithms were used as optimizing tools for charging and discharging time of the vehicles and then the DVR was applied as the stabilizer of the network asymmetry.
https://www.jeires.com/article_130068_cb4336b2907888fbe149ca7e1244014c.pdf
2021-06-01
178
193
10.22034/jeires.2021.278468.1034
V2G system
Electric Vehicle
Intelligent power grid
particle swarm optimization algorithm (PSO)
Economic Dispatch
Ebadollah
Amouzad Mahdiraji
ebad.amouzad@gmail.com
1
Department of Engineering, Sari Branch, Islamic Azad University, Sari, Iran
LEAD_AUTHOR
[1] E. Amouzad Mahdiraji, S. Shariatmadar, International Journal of Smart Electrical Engineering, 2019, 8, 99-104.
1
[2] E. Amouzad Mahdiraji, S. Shariatmadar, International Journal of Smart Electrical Engineering, 2019, 8, 51-58.
2
[3] P.J. Bree, A. Veltman, V.D. Bosch, Vehicular technology, 2009, 2, 58, 588-595.
3
[4] E. Amouzad Mahdiraji, A. Yousefi Talouki, Journal of Chemical Reviews, 2020, 2, 284-291.
4
[5] E. Amouzad Mahdiraji, S. Shariatmadar, International Journal of Smart Electrical Engineering, 2019, 8, 143-148.
5
[6] E. Amouzad Mahdiraji, S.M. Shariatmadar, Advanced Journal of Science and Engineering. 2020, 1, 27-31.
6
[7] W. Li, John Wiley & Sons, 2005, 1, 108-164.
7
[8] E. Amouzad Mahdiraji, M. Sedghi Amiri. International Journal of Smart Electrical Engineering, 2020, 9, 01, 13-21.
8
[9] E. Amouzad Mahdiraji, Journal of Scientific Perspectives, 2020, 4, 245-254.
9
[10] E. Amouzad Mahdiraji, M. Amiri, Journal of Engineering Technology and Applied Sciences, 2020, 5, 133-147.
10
[11] J. Lei, J. Xie, D. Gan, Automation of power system, 2009, 4, 23, 33-35.
11
[12] E. Amouzad Mahdiraji, Gazi Mühendislik Bilimleri Dergisi (GMBD), 2020, 6, 138-144.
12
[13] E. Sortomme, M.A. El-Sharkawi, IEEE Trans. Smart Grid, 2011, 2, 131–138.
13
[14] E. Amouzad Mahdiraji, Transactions of Electrical, Electronic and Computer Engineering 2020, 6, 238–244.
14
[15] E. Amouzad Mahdiraji, A. Yousefi Talouki, Journal of Chemical Reviews, 2021, 3, 40-49.
15
[16] K. Clement-Nyns, E. Haesen, J. Driesen, IEEE Trans. Power Syst., 2010, 25, 371–380.
16
[17] Y. Raziani, S. Raziani, International Journal of Advanced Studies in Humanities and Social Science, 2020,9(4), 262-280.
17
[18] E. Amouzad Mahdiraji, N. Ramezani, International Journal of Science and Engineering Investigations (IJSEI), 2020, 9, 35-42.
18
[19] E. Amouzad Mahdiraji, N. Ramezani, Signal Processing and Renewable Energy, 2020, 4, 37-50.
19
[20] A.G. Boulanger, A. Chu, S. Maxx, D. Waltz, Proc. I EEE, 2011. 99, 1116–1138.
20
[21] E. Amouzad Mahdiraji, N. Ramezani, International Journal of Science and Engineering Investigations (IJSEI), 2020, 9, 24-28.
21
[22] O. Sundstrom, C. Binding, IEEE Trans. Smart Grid, 2012, 3, 26–37.
22
[23] E. Amouzad Mahdiraji, Signal Processing and Renewable Energy, 2020, 4, 67-80.
23
[24] E. Amouzad Mahdiraji, M. Sedghi Amiri, Journal of Engineering in Industrial Research, 2020, 1, 111-122.
24
[25] N. Kayedi, A. Samimi, M. Asgari Bajgirani, A. Bozorgian, South African Journal of Chemical Engineering, 2021, 35, 153-158.
25
[26] A. Bozorgian, A. Samimi, International Journal of New Chemistry, 2021, 8, 41-58.
26
[27] A. Bozorgian, S. Zarinabadi, A. Samimi, Chemical Methodologies, 2020, 4, 477-493.
27
[28] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadeh, M. Ardjmand, Artificial Cells, Nanomedicine, and Biotechnology, 2019, 47, 3222-3230.
28
[29] A. Samimi, Journal of Engineering in Industrial Research, 2021, 2, 71-76.
29
[30] F. Zare Kazemabadi, A. Heydarinasab, A. Akbarzadehkhiyavi, M. Ardjmand, Chemical Methodologies, 2021, 5, 135-152.
30
[31] S. M. S. Mirnezami, F. Zare Kazemabadi, A. Heydarinasab, Progress in Chemical and Biochemical Research, 2021, 4, 191-206.
31
[32] M. Torkaman, F. Zare Kazemabadi, Oriental Journal of Chemistry, 2017, 33, 1976-1984.
32
[33] R. Rahimiyan, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2020, 2, 247-253.
33
[34] R. Rahimiyan, Advanced Journal of Chemistry, Section B: Natural Products and Medical Chemistry, 2020, 2, 239-246.
34
[35] R. Rahimiyan, Journal of Engineering in Industrial Research, 2021, 2, 95-112.
35
[36] Y. Raziani, S. Raziani, Journal of Chemical Reviews, 2021, 3, 83-96.
36
[37] E. Amouzad Mahdiraji, M. Sedghi Amiri, Journal of Engineering in Industrial Research, 2021, 2, 7-16.
37