Page 162 - CW E-Magazine (11-3-2025)

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News from Abroad

GREEN HYDROGEN PRODUCTION
Evonik setting up new German pilot unit for making Bharat Jyoti Impex

anion exchange membranes AVAILABLE REGULARLY

 Acetophenone  Acetyl Acetone  Acrylonitrile  2-Methyl THF  Methyl Cellosolve  Methyl Cyclohexane
Evonik is building a pilot plant in the one hand, it has to allow anions to  Adipic Acid  Allyl Alcohol  Allyl Chloride  Allylamine  Methyl Iso Propyl Ketone  Methyl Propyl Ketone
Marl, Germany, for the production of pass through, but on the other hand, it  Alpha-Methyl Styrene  Amino Ethyl Ethanol Amine  Methyl Salicylate  Methyl Stearate  Methyl Stearate / Palmitate

its anion exchange membrane (AEM), has to be impermeable to the gases pro-  Amino Guanidine Bicarbonate  4 Amino Phenol  Methyl Tin Mercaptide  Methallyl Chloride  Mono Cyclohexylamine
marketed under the Duraion brand name. duced in the electrolysis, such as hydro-  Antimony Trioxide 99.8%  Barium Carbonate  Barium Nitrate 99%  Mono Ethyl Amine 70%  Mono Isopropylamine 70% / 99%
gen. It also has to be able to withstand  1,2,3 Benzotriazole 99.5%  1,2,3-Benzotriazole  1,3-Butane Diol  Monoglyme  N-Amyl Alcohol (N-Pentyl Alcohol)  N-Butyl Amine
 2 Butyne 1,4 Diol  Biphenyl  Boron Trifluoride Etherate
 N-Decanol  N-Hexyl Alcohol (99% & 98%)
A central element in AEM water high pressure and high temperatures.  Cerium Oxide  Cesium Carbonate  Cetyl Chloride  N Butyraldehyde  N Ethyl Pyrrolidone  N Vinyl Pyrrolidone
electrolysis, Duraion membranes enable  CIS-2-Butene-1,4-Diol  Crotonic Acid  Cyanuric Chloride  N,N Dimethyl Cyclohexylamine  N,N-Dicyclohexyl Carbodiimide
the cost competitive production of green “Across our many disciplines, we  Cyclohexanol  Cyclopentanone  Cyclopropylamine  N,O-Bis (Tri Methyl Silyl) Acetamide  NACOL 6 99% (N Hexanol)
hydrogen. Evonik said it is investing a were able to combine polymer design and  2,2-Dimethoxy Propane  2,4 Di Tertiary Butyl Phenol  NACOL 10-99% (N Decanol) SASOL Germany
 NACOL 8 99% (N Octanol)  Nitro Ethane  Nitro Methane
“low double-digit million euro” amount synthesis, engineering, membrane manu-  D - Tartaric Acid  D-Camphor Sulphonic Acid  Di Cyclohexylamine  N-Heptane 99%  N-Hexane 99%  N Pentane 95%  N-Pentane 99%
 Di Ethyl Ketone  Di Ethyl Malonate  Di Ethyl Sulphate
in the AEM plant, which is scheduled hydrogen production. In addition, the plant facturing as well as customer and market  Di Methyl Acetamide [Henan Junhua]  Di Methyl Malonate  N-Methyl 2 Pyrolidone  N-Methyl Piperazine  1-Octanol (C8)
to go online at the end of 2025. “This will be able to produce reinforced mem- feedback,” said Mr. Christian Däschlein,  Di Phenyl Carbonate  Di Sodium Phosphate Anhydrous  1-Octene  Ortho Chloro Benzaldehyde  Para Benzoquinone
strategic investment ties in with our branes, directly addressing growing head of the New Growth Area Hydrogen  Dibasic Ester  DIBOC (Di Tert. Butyl Dicarbonate)  Para Cresol  Para Chlorobenzaldehyde
business goals of further growing our customer interest in this new technology. Economy at Creavis, Evonik’s strategic  Dibromomethane (Methylene Di Bromide)  Para Hydroxybenzaldehyde  Perchloric Acid
pioneering membranes into a true en- innovation unit and business incubator.  Dicyclopentadiene  Di-Ethyl Carbamyl Chloride  Petroleum Ethers 40-60 / 60-80 / 80-100 / 100-120 etc.
 Phenyl Ethyl Alcohol  Phenyl Ethyl Amine [ R+ ; DL ]
 Diethyl Hydroxylamine  Diethyl Oxalate  Diglyme
abler of the burgeoning green hydrogen Compared to conventional electro- In the last 12 months, Evonik has steadily  Diisobutylene  Diisopropyl Succinate  Pivaloyl Chloride  Potassium Bi Carbonate
economy,” said Mr. Goetz Baumgarten, lysis processes, AEM technology increased the production capacity of the  Diisopropylamine  Dimethyl Oxalate  Di-N-Propyl Amine  Potassium Tertiary Butoxide  Potassium Thioacetate
head of the Membranes & Fibres pro- promises lower investment costs due intermediate products used in Duraion  DL Alfa Phenyl Ethyl Amine  DMSO (Hubei Xingfa)  2-Pyrrolidone  Pyrogallol  Quinoline  Resorcinol (China)
duct line at Evonik’s High Performance to the use of less expensive materials membranes. The construction of the plant  D-Ribose  2 Ethyl Hexyl Bromide  2-Ethylhexyl Thioglycolate  Salicylic Acid Technical / Pure  Secondary Butanol (China)
Polymers business line. Once fully on- for the cells. In addition, the techno- in Marl capitalises on this higher capacity  Ethyl Benzene  Ethyl Cyclo Hexane  Ethyl Nicotinate  Sodium Diethyldithiocarbamate
 Sodium Dichloroisocyanurate (56%) Granule  Sodium Ethoxide
 Ethylene Glycol Diacetate (EGDA)  Fluorobenzene
line, the plant will be able to produce logy enables high current densities and and is the next step for the company in  Formamide  Formic Acid 99%  Fumaric Acid  Sodium Ethoxide solution in Ethanol / Methanol
enough membranes each year to pro- very good efﬁ ciency. The membrane is the planned expansion of its membrane  Furfuraldehyde  Furfuryl Alcohol  Furfurylamine  Sodium Methoxide  Sodium Sulphite (Aditya Birla -Thailand)
vide 2.5-GW of electrolysis capacity for a polymer and a high-tech product: on business.  Gamma Amino Butyric Acid (4 Amino Butyric Acid)  Sodium Sulphite 98%  Sodium Sulphite Tech 90%
 Gamma Butyrolactone  Glutaraldehyde 50%  Glycine  Sodium Tertiary Butoxide  Sorbitol Powder  Stearyl Bromide
LEARNING FROM MISTAKES  Glyoxal 40%  Glycolic Acid 70%  Glyoxylic Acid 50%  Stearyl Palmitate  Strontium Carbonate  Succinic Acid
 Guanidine HCl  Guanidine Carbonate  Guanidine Thiocyanate
 Succinic Anhydride  Sulfolane Anhydrous
US CSB releases safety video on 2020 propylene accident  Guanine  Heptane [mix]  12 Hydroxy Stearic Acid  Tert. Butyl Amine  Tertiary Amyl Alcohol
 1,6-Hexane Diol  Hippuric Acid  Imidazole  Isobutylamine
 Tertiary Butyl Acetate  Tetra Hydro Furfuryl Alcohol
The US Chemical Safety and extremely ﬂ ammable hydrocarbon gas. incident: process safety management  Isovaleraldehyde  Itaconic Acid  L + Tartaric Acid  THF (Dairen, Nan Ya)  Thioacetamide
 Lauric / Myristic / Palmitic / Oleic / DCFA / Caprylic Acid
 Thiocyanates: Ammonium / Sodium / Potassium
Hazard Investigation Board (CSB) has The CSB found that sometime over- and emergency preparedness. The video  Lactic Acid  Lanthanum Carbonate  Lithium Aluminium Hydride  Thioglycolic Acid 80%  TMOF / TEOF / TMO Acetate
released a new safety video on its inves- night prior to the incident, a hose dis- also highlights a safety recommenda-  Lithium Amide  Lithium Carbonate [Equivalent to I.P.]  Tolyl Triazole  Tolyltriazole Granular
tigation into the January 24, 2020, fatal connected from its ﬁ tting inside a booth tion made by the CSB to the Compressed  Lithium Carbonate  Lithium Hydroxide Anhydrous  1,2,4-Triazole & its Sodium Salt  2,2,2 Tri Fluoro Ethanol
propylene release and explosion at the used for the coating process, releasing Gas Association. In the video CSB Chair-  Lithium Hydroxide  Lithium Hydroxide Monohydrate LIOH : 57.7% Min  2,2,2-Tri Fluoro Ethylene  Tri Ethyl Citrate
Watson Grinding and Manufacturing ﬂ ammable propylene that accumulated person Steve Owens states, “This deadly  Lithium Metal 99% / 99.9%  L-Proline  M. P. Diol  Tri Fluoro Acetic Acid  Tri Fluoro Acetic Anhydride
 Malonic Acid  Malononitrile  Maltol  Meta Cresol 99.5%
 Tri Isodecyl Stearate  Triacetin (Glycerine Triacetate)
Company facility in Houston, Texas. inside the coating building. By the time incident could have been prevented if  Meta Hydroxy Benzoic Acid  Meta Para Cresol [Meta 60%]  Trichloroisocyanuric Acid 5-8 Mesh,100-120 Mesh
The massive explosion resulted in the employees arrived at the facility early Watson Grinding had implemented a  1 Methoxy Propanol  1-Methoxy Propyl Acetate  Triethyl Ortho Acetate  Triethylsilane  Triisobutyl Phosphate
death of two workers and a nearby resi- on the morning of January 24, an ex- process safety management system to  1-Methyl Imidazole  2-Methyl Imidazole  Triss Buffer  Tri-N-Butyl Phosphate  Triphosgene  2,6-Xylidine
dent and damaged hundreds of neigh- plosive concentration of propylene had address the hazards of its coating ope- AVAILABLE REGULARLY AT A SPECIAL RATE
bouring homes. formed inside the building. When one ration. And even if a leak still had taken • Azelaic Acid • Caproic Acid • Methyl Iso Butyl Carbinol [MIBC]
of the employees entered the building place, an emergency response plan could • Methyl Glycol • Phosphorous Pentoxide • Di Iso Butyl Ketone [DIBK]
Watson Grinding specialised in and turned on the lights, the ﬂ ammable have prevented the tragic loss of life that • Pelargonic Acid • Potassium Ter Sulphate
machining and grinding services as well vapor ignited, triggering the explosion. occurred. We urge companies to develop Bharat Jyoti Impex
as applying high-performance coatings – and implement effective process safety “Jasu”, Ground Floor, 30, Dadabhai Road, (Near CNM School), Vile Parle (West), Mumbai 400 056.
particularly High Velocity Oxygen As in the CSB’s ﬁ nal report on the management systems and emergency res- Phone: +91 91528 33394 & +91 91524 33394  Whats App:. +91 99300 51288
Fuel, or HVOF, coating. The process of incident, the safety video covers the two ponse plans so that something like this Email: info@bharatjyotiimpex.com  Website: www.bharatjyotiimpex.com
HVOF coating involved propylene – an key safety issues that contributed to the never happens again.” More than 2000 CheMiCals in sMall PaCking

162 Chemical Weekly March 11, 2025

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