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Access price assessments depicting Propylene prices in United States, Europe, China, United States, China, United States, Europe, China and Southeast Asia. Intratec Primary Commodity Prices provides historical prices and forecasts of as many as 225 commodities, across several locations worldwide.
This report examines the costs related to Polymer Grade (PG) Propylene production from refinery grade (RG) propylene, via a typical purification process. Propane stream is generated as by-product. The economic analysis performed assumes a plant located in the United States.
This report analyses the economics of Polymer Grade (PG) Propylene production from raffinate-1 in the United States, using two typical integrated processes: isomerization and metathesis. In these processes, 1-butene present in raffinate-1 is isomerized into 2-butenes. The 2-butenes are submitted with ethylene to a metathesis reaction, producing propylene. A C5s stream is generated as by-product.
This study presents the economics of Polymer Grade (PG) Propylene production from ethylene in the United States similar to the one proposed by Lummus Technology. First, ethylene is dimerized into 2-butenes, which are then reacted with ethylene via a metathesis reaction, yielding propylene.
This report presents the economics of Polymer Grade (PG) Propylene production from ethylene and raffinate-2. The process under analysis consists in a metathesis process similar to Lummus Technology's Olefins Conversion Technology (OCT). The economic analysis performed assumes a plant located in the United States.
This report analyses the economics of Polymer Grade (PG) Propylene production from methanol in the United States. The process examined in this report is similar to UOP/Norsk Hydro (now Ineos) methanol-to-olefins (MTO) process. Polymer grade ethylene is also generated as co-product in the process.
This report presents the economics of Polymer Grade (PG) Propylene production from methanol in the United States, using a methanol-to-propylene (MTP) process similar to Lurgi MTP. Initially, methanol is converted do dimethyl ether (DME), which is then converted to Propylene. Gasoline is generated as by-product.
This report presents the economics of Polymer Grade (PG) Propylene production from light naphtha feedstock in Germany. The process examined in this report uses a catalytic cracking process similar to KBR SUPERFLEX. Polymer grade ethylene and gasoline are generated as by-products.
This report approaches the economics of producing Polymer Grade (PG) Propylene from light naphtha in Germany, using a typical low-severity steam cracking process (maximizing propylene to ethylene ratio). In addition to Propylene and ethylene, the process generates electricity, crude C4, pyrolysis gas and fuel oil.
This report examines the costs related to Polymer Grade (PG) Propylene production from propane in the United States. The process examined in this report is based on the dehydrogenation of propane carried out in fixed-bed reactors, similar to Lummus CATOFIN.
This study presents the economics of Polymer Grade (PG) Propylene production from propane. The process consists in the dehydrogenation of propane, carried out in a moving-bed reactor, similar to UOP Oleflex. The economic analysis performed assumes a plant located in the United States.
The report under analysis presents the economics of Polymer Grade (PG) Propylene production from propane in the United States. The process examined in this report uses a two-step dehydrogenation process (steam reforming/oxyreaction), similar to Uhde STAR.
It presents the economics of Polymer Grade (PG) Propylene production from soybean oil in the United States, via a typical fluid catalytic process (FCC). In this process, soybean oil is cracked into olefin-rich light gases, including propylene. In order to yield greater amounts of propylene, the light gases are fed to a secondary FCC reactor.
This report presents the economics of Polymer Grade (PG) Propylene production from vacuum gas oil (VGO) in China. The portrayed process is similar to Sinopec Deep Catalytic Cracking (DCC) technology, in which VGO is converted to Propylene, generating propane, C4 fraction, C5+ naphtha and fuel oil as by-products.
This report presents the economics of Polymer Grade (PG) Propylene production process from vacuum gas oil (VGO) in China. The process examined in this report is similar to Sinopec Catalytic Pyrolysis Process (CPP) technology, in which VGO is converted to Propylene and ethylene, generating also propane, C4 fraction, C5+ naphtha and fuel oil as by-products.
Access prices and costs of key industrial utilities used in Propylene Production. Subscribers to Intratec Industry Economics Worldwide can monitor key manufacturing costs and indexes in strategic countries.
Have unbiased multipliers for instantaneously adjusting construction costs of Propylene plants over time. Subscribers to Intratec Industry Economics Worldwide can monitor key manufacturing costs and indexes in strategic countries.
Get Propylene plant capex in a country of interest based on capex in other countries. Subscribers to Intratec Industry Economics Worldwide can monitor key manufacturing costs and indexes in strategic countries