3.2 The 15th Saudi-Japanese Symposium on Catalysts in Petroleum Refining & Petrochemicals
The 15th Saudi-Japanese Symposium on Catalysts in Petroleum Refining & Petrochemicals took
place on November 27-28, 2005, jointly sponsored by the Japan Petroleum Institute and King Fahd
University of Petroleum and Minerals (KFUPM) of Dhahran, Saudi Arabia.
There were seven registered participants from Japan, including the secretariat of the Japan Petroleum
Institute. In addition to these, Minoru Horike, director of JCCP’s Technical Cooperation Department,
took part. Director Horike and Group Leader Koichi Segawa of Sophia University gave opening
greetings for the Japanese contingent, and subsequently lectures were given. Last year a terrorist
incident occurred in al-Khobar, which is close by KFUPM, so only the Japan Petroleum Institute
secretariat and JCCP Riyadh Office Director Nakayama took part this year, and only four people
presented papers. As in past joint seminars, six members from the Japan contingent gave lectures this
A total of 18 technical lectures were given over the course of two days: six Japanese lectured,
along with nine Saudi Arabians and three persons from Europe or North America.
The following seven people, including the secretariat of the Japan Petroleum Institute, represented
Japan as registered participants at the joint seminar.
Professor, Department of Chemistry, Faculty of Science and Technology, Sophia University
Takashi Tatsumi Professor, Chemical Resources Laboratory, Tokyo Institute of Technology Atsushi Satsuma Professor, Department of Applied Chemistry, Graduate School of Engineering,
Professor, School of Materials Science, Japan Advanced Institute of Science and Technology
Chief Researcher, National Institute of Advanced Industrial Science and Technology
Toshiyuki Mitsui Assistant General Manager, Technology Business Department, Toyo
Chief Researcher, Japan Petroleum Institute
The six papers submitted for the proceedings by the Japan contingent, along with abstracts, are as
Strategies for the production of sulfur free fuels
Professor, Department of Chemistry, Faculty of Science and Technology, Sophia University
Strategies for the production of sulfur free fuels
The exhaust gases from motor vehicles contribute to a large extent to air pollution through their content in NOX and SOX, CO, hydrocarbons, and particulate matters (PM). In addition, sulfur in fuels is well-known poison for catalysts for clean-up exhaust gas devises. Those situations lead the governments of numerous countries to adopt new regulations which aim at a drastic reduction of sulfur content in fuels (50 ppm or less by 2005; 10 ppm or less by 2009).
Professor, Chemical Resources Laboratory, Tokyo Institute of Technology Syntheses of Petrochemicals by Using Mesoporous Silica and Functionalized Silica Catalysts
Mesoporous materials have high potentiality for various applications such as catalysis and adsorption,
because they have larger pore size and pore volume, and higher surface area than zeolites. Functional
groups attached to the mesoporous silica wall as well as silanol groups thereon act as versatile active
catalytic sites. Silanol groups on mesoporous materials can catalyze the Beckmann rearrangement,
and sulfonic acid groups can be incorporated using mercaptoalkyllsilanes followed by oxidation and
applied to various acid-catalyzed reactions. Amino groups can also be introduced, and those
introduced via an anionic surfactant templating route have proven to be highly active in base
catalyzed reactions such as Knoevenagel and aldol condensations.
Professor, Department of Applied Chemistry, Graduate School of Engineering, Nagoya University
Role of Promoters on Active Sites of Vanadyl Pyrophosphate for Selective Oxidation of Propane
The role of promoters on the modification of active sites on (VO)2P2O7 catalysts for selective
oxidation of propane was investigated. From XRD patterns, IR spectra, and Raman spectra, the
addition of promoters Sb, Ti, Zr, Hf, Cu, and Ce only slightly modified the bulk structure of
(VO)2P2O7 phase. The addition of Sb, Ti and Zr increased the selectivity to acrylic acid, while Cu, Ce
and Hf promoted catalysts showed lower selectivity than pure (VO)2P2O7. The surface V=O species,
which was measured by Nitric oxide - Ammonia Rectangular Pulse technique, was found to be the
controlling factor for the catalytic activity of propane oxidation from a proportional correlation
between the number of surface V=O species and reaction rate of propane. In the case of Sb, Ti, and Zr
promoted catalysts, the selectivity to acrylic acid significantly increased. These changes in
selectivity were well rationalized by the changes in the number and strength of Brønsted and Lewis
acid sites, which were estimated from Dimethylpyridine Temperature Programmed Desorption.
From a good correlation between the selectivity to acrylic acid and the surface concentration of
Lewis acid sites, it was experimentally demonstrated that Lewis acid site is the key factor for
Professor, School of Materials Science, Japan Advanced Institute of Science and Technology
Constituent Analysis of DAO Before and After Hydrocracking over Zeolite Catalyst by Ultra-high
Resolution Fourier Transform Ion Cyclotron Resonance Mass Spectrometry
Ultra-high resolution FT-ICR MS is expected to provide molecular formula information about
constituents of DAO by precise mass values of peaks in measured spectra. We have estimated
molecular structure of nitrogen-containing and hydrocarbon constituents by ESI and EI, respectively,
before and after hydrocracking of DAO over zeolite catalyst. It is elucidated that specific
nitrogen-compounds tend to remain after hydrocracking under serious reaction conditions.
Chief Researcher, National Institute of Advanced Industrial Science and Technology
Novel HDS Catalysts for Sulfur-Free Fuel Production
Performances of HDS catalysts are crucial to the sustainable production of sulfur-free (S<10 wtppm)
fuel in the existing units with minimal process modifications.
We have introduced a new concept to increase the crystallinity of MoS2 in addition to increasing the
dispersion of MoS2 crystallites as well as the utilization of Co (and Ni). Increased crystallinity of
dispersed MoS2 with minimal stacking caused the amounts of CUS sites to decrease as expected,
however, increased basic properties of CUS sites might contribute to the deeper HDS with minimal
hydrogenation of the aromatic compounds. According to the newly introduced concepts, we have
finally commercialized a novel HDS catalyst of LX-NC1 for sulfur-free diesel fuel production in the
existing units operating with almost the same conditions as in the production of <50 wtppm sulfur
We have further applied the same concept to prepare a new hydrodesulfurization (HDS) catalyst that
is selective in HDS of fluid catalytic cracked (FCC) gasoline. The developed catalysts showed higher
HDS activities and more depressed olefin hydrogenation performances than the commercially
Assistant General Manager, Technology Business Department, Toyo Engineering Corporation
DME (Di-Methyl Ether) is a non-toxic chemical currently used in aerosol propellants, etc., as a substitute for chlorofluorocarbons. However, the future DME market would be fuel considering its attractive properties as a substitute for LPG and diesel oil, etc., as a clean fuel without SOx and soot. LPG existing infrastructures such as tanks and tankers could be used with minor modifications. The total investment cost of a DME plant would be smaller compared with LNG and GTL (FT Synthesis). In China, DME plants for fuel use have already started commercial operations. In East Asia, many studies of DME applications have been made and are ongoing. For the Japanese market there are several large-scale DME projects undergoing detailed feasibility studies for introduction around 2008. In China, there are many small- and middle-scale projects planned for local fuel use. Lutianhua Group Inc. constructed a 10,000 t/y (30 t/d) commercial DME plant for fuel use under license by TOYO, and started production in August 2003, becoming the first commercial plant in the world for energy usage. After achieving the excellent DME plant performance of 110,000 t/y (340 t/d), the DME project started in December 2003 under license by TOYO. The plant was the world’s largest commercial DME plant and will begin in 4Q 2005. A Jumbo DME Plant based on the methanol dehydration process is a combination of a methanol plant and a DME synthesis plant consisting of a single-train concept, and both plants have been commercially proven in the world. The DME synthesis plant is very similar to methanol synthesis, but simpler considering the lower reaction heat and lower synthesis pressure. Therefore, scaled-up technology of a methanol plant could be easily applied to a Jumbo DME Plant. Oxygen consumption is a very important factor for selection of DME process scheme. Oxygen is not required for a Jumbo DME Plant of 3,500 t/d. An economic study shows DME production costs from a Jumbo DME Plant could be economically feasible compared with LPG and LNG.
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Consists of 6 nozzle and receiver sets that are color coded for quick identification of mating parts. Each color nozzle and receiver will only couple with their matching color component. This providescomplete protection against cross contamination. • Maximum flow rate of 45 gpm at 70 PSI • Working pressure rating: 200 PSI Fittings ENBL Nozzle with Plug Part # No