MAB 06 039中文资料

MITSUBISHI MU-2 TECHNICAL PUBLICATIONSThis document contains a list of the current Manuals, Catalogs and selected Service Information for Mitsubishi MU-2B series aircraft, including the latest applicable revisions.All MU-2 technical publications are available from Aircraft Technical Publishers (ATP) on an annual subscription basis. ATP can be reached at 2000 Sierra Point Parkway, Suite 501, Brisbane, California 94005,Tel:+1-800-227-4610or+1-415-330-9500,Email:***************,Web:.Only Airplane Flight Manuals, Pilot’s Operating Manuals and FAA Accepted Pilot Checklists are available for sale from MHIA. Airplane Flight Manuals and Pilots Operating Manuals will be delivered together as a package and never sold separately.For any questions related to MU-2 Technical Publications, please contact Mitsubishi Heavy Industries America, Inc. (MHIA):Mitsubishi Heavy Industries America, Inc.Aircraft Product Support Division17304 Preston Road, Suite 1270Dallas, Texas 75252Tel: 972-934-5480Email:********************Web: A brief summary of Publications Revision/Reissues, Service Information, and list of models is presented below.Publications Revisions and ReissuesMitsubishi MU-2B series aircraft are certified under one of two type certificates, either A10SW or A2PC. A10SW aircraft carry the letters “SA” at the end of the aircraft serial number. All aircraft manuals forA2PC aircraft carry a part number starting as YET xxxxx (example: YET 67164) where xxxxx is a specific number. All A10SW aircraft manuals carry part numbers starting as MR-xxxx (example: MR-0342).As engineering, operational or maintenance changes become necessary, revisions and/or reissues of applicable publications are prepared and issued by Mitsubishi Heavy Industries, Ltd. (MHI), Nagoya, Japan, and distributed by Mitsubishi Heavy Industries America, Inc. (MHIA) in Dallas, Texas. Revisions incorporate a number of changes and are only part of a book. A reissue reflects complex changes or a large number of changes and is a complete book. Reissues are identified by a numerical suffix after the basic part number. Example of paper publication part numbers:• MR-0342 – Basic Part Number of Parts Catalog• MR-0342 Rev 1 – First Revision to the basic Parts Catalog• MR-0342-1 – First Reissue of the basic Parts Catalog• MR-0342-1 Rev 1 – First Revision to the First Reissue to the Parts CatalogService InformationMitsubishi MU-2 Service Information consists of Service Bulletins (SB), Service Recommendations (SR), Service News (SN) and Service Letters (SL). Service information that applies to A2PC aircraft will be numbered as SB xxx or SN xxx (example: SB 035). Service information that applies to A10SW aircraft will be numbered as SB xxx/xx-xxx or SN xxx/xx-xxx (example: SB 072/24-001). Any of these documents may be amended as indicated by a revision letter and date. Some Service News and Service Letters may apply to both A2PC and A10SW aircraft and will be designated under two numbers. Periodically, MHI publishes a listing of all Service Information, applicable to either A2PC or A10SW aircraft. Each Service Information index will apply only to A2PC aircraft or A10SW aircraft. The current indices are:• A2PC aircraft: ....................................Service News 047 rev. Z, dated June 16, 2017• A10SW aircraft: .................... Service News 034/00-001 rev. S, dated June 16, 2017List of MU-2 ModelsThe table lists all MU-2B series aircraft by model number, sales designation, applicable serial numbers, and type certificate basis.T/C SalesDesignation Type CertificateModel NumberSerial Numbers ExceptionsA2PC B Model MU-2B 006-038 (004, 009, 011, 028, 031), 036D Model MU-2B-10 101-120 102, 112, 114, 115, 118DP Model MU-2B-15 114, 115, 118F Model MU-2B-20 121-233 (102), 128, (135), 147, 148, 152,153, 171, 176, 178, 181, 186,(195), 200-204, 225, 227, 230,234, 235, 236K Model MU-2B-25 239-312, 314-316 (005), 275, 278, 279, 317, 318M Model MU-2B-26 319, 320, 322-347 334-336G Model MU-2B-30 502-547 (501, 504, 505, 520, 526, 546)J Model MU-2B-35 548-651, 653 654L Model MU-2B-36 655-660, 662-696A10SW K Model MU-2B-25 313M Model MU-2B-26 349P Model MU-2B-26A 321, 348, 350-364, 366-393 359, 360, 376, 377, 378, 394N Model MU-2B-36A 661, 697-699, 701-730 715, 716, 717Solitaire MU-2B-40 365, 395-459 421, 422, 442-445, 455, 456, 457Marquise MU-2B-60 700, 731-799, 1501-1569Note: 1. Serial Numbers with ( ) indicate airplanes under JCAB TC No. 19 and 25.2. S/N 237 and 238 were not manufactured.LIST OF CURRENT MITSUBISHI PUBLICATIONSMITSUBISHI MU-2B SERIES AIRCRAFTAirplane Flight Manual (AFM)Manual TC Model Doc# Rev. Temp. Rev. Issue Date67026A - - 03/05/1987 AFM JCAB MU-2B YET13 - 11/29/200714 - 03/16/201686400 - - 03/05/1987 AFM JCAB MU-2B-10 YET12 - 08/09/200413 - 11/29/200768038A - - 03/05/1987 AFM JCAB MU-2B-15 YET12 - 08/09/200413 - 11/29/200768034A - - 03/03/1987 AFM JCAB MU-2B-20 YET13 - 11/29/200714 - 03/16/201671367A - - 03/03/1987 AFM JCAB MU-2B-25 YET13 - 11/29/200714 - 03/16/2016 AFM FAA MU-2B-25 MR-0156-1 - - 03/25/198611 - 03/10/200912 - 08/24/201674129A - - 03/03/1987 AFM JCAB MU-2B-26 YET13 - 11/29/200714 - 03/16/2016 AFM FAA MU-2B-26 MR-0160-1 - - 03/25/198611 - 03/10/200912 - 08/24/2016 AFM FAA MU-2B-26A MR-0194-1 - - 03/25/198613 - 03/10/200914 - 08/24/201669013A - - 02/19/1987 AFM JCAB MU-2B-30 YET14 - 11/29/200715 - 03/16/201670186A - - 02/19/1987 AFM JCAB MU-2B-35 YET14 - 11/29/200715 - 03/16/201674122A - - 02/19/1987 AFM JCAB MU-2B-36 YET13 - 11/29/200714 - 03/16/2016 AFM FAA MU-2B-36A MR-0196-1 - - 02/28/198615 - 03/10/200916 - 08/24/2016 AFM FAA MU-2B-40 MR-0271-1 - - 03/25/198613 - 03/10/200914 - 08/24/2016AFM FAA MU-2B-60 MR-0273-1 - - 09/24/1985 15 - 03/10/2009 16 - 08/24/2016Pilot’s Operating Manual (POM)Manual TC Model Doc# Rev. Temp. Rev. Issue DatePOM JCAB MU-2B YET 67025A - - 12/10/1987 3 - 09/10/1997 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM JCAB MU-2B-10 YET 87236 - - 11/30/1987 3 - 09/10/1997 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM JCAB MU-2B-15 YET 87237 - - 11/20/1987 3 - 09/10/1997 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM JCAB MU-2B-20 YET 68134A - - 11/10/1987 4 - 02/20/1998 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM JCAB MU-2B-25 YET 72067A - - 10/30/1987 3 - 09/10/1997 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM FAA MU-2B-25 MR-0157-1 - - 03/31/1986 4 - 07/15/2004 - TR 3-1 12/17/2012 - TR 4-1 11/13/2006 POM JCAB MU-2B-26 YET 74130A - - 09/01/1987 5 - 09/10/1997 - TR 2-1 06/16/2003 - TR 3-1 06/16/2003 - TR 3-2 12/17/2012 - TR 4-1 11/13/2006 POM FAA MU-2B-26 MR-0161-1 - - 03/31/19864 - 07/15/2004- TR 4-1 11/13/2006 POM FAAMU-2B-26A MR-0195-1 - - 03/31/19864 - 07/15/2004- TR 3-1 12/17/2012- TR 4-1 11/13/2006 POM JCABMU-2B-30 YET 69224A - - 10/01/19873 - 09/10/1997- TR 2-1 06/16/2003- TR 3-1 06/16/2003- TR 3-2 12/17/2012- TR 4-1 11/13/2006 POM JCABMU-2B-35 YET 70187A - - 07/01/19873 - 09/10/1997- TR 2-1 06/16/2003- TR 3-1 06/16/2003- TR 3-2 12/17/2012- TR 4-1 11/13/2006 POM JCABMU-2B-36 YET 74123A - - 06/01/19873 - 09/10/1997- TR 2-1 06/16/2003- TR 3-1 06/16/2003- TR 3-2 12/17/2012- TR 4-1 11/13/2006 POM FAAMU-2B-36A MR-0197-1 - - 03/12/19864 - 07/15/2004- TR 3-1 12/17/2012- TR 4-1 11/13/2006 POM FAAMU-2B-40 MR-0335-1 - - 03/26/19865 - 07/15/2004- TR 0-1 08/07/2009- TR 3-1 12/17/2012- TR 4-1A 02/06/2008 POM FAAMU-2B-60 MR-0338-1 - - 08/23/19857 - 07/15/2004- TR 2-2 08/07/2009- TR 3-1 12/17/2012 - TR 4-1 11/13/2006Maintenance Manual (MM)Manual TC Model Doc# Rev. Temp. Rev. Issue DateMM JCAB MU-2B YET 67164 ORIG - 10/01/196719 - 12/27/1999- TR 2-1 10/31/2002- TR 2-2 09/27/2004- TR 2-3 02/05/2008- TR 2-4 05/29/2015- TR 2-5 05/29/2015- TR 2-7 05/29/2015- TR 2-8 10/21/2016- TR 2-9 10/21/2016- TR 3-1 07/30/2012- TR 3-2 05/29/2015- TR 3-3 05/29/2015- TR 3-4 05/29/2015- TR 4-1 10/31/2002- TR 4-2 10/31/2002- TR 4-3 10/31/2002- TR 4-4 04/28/2009- TR 4-5 05/29/2015- TR 4-6 05/21/2012- TR 4-7 05/21/2012- TR 4-8 05/21/2012- TR 4-9 05/21/2012- TR 4-10 05/21/2012- TR 4-11 05/21/2012- TR 4-12 08/09/2016- TR 4-13 08/09/2016- TR 4-14 08/09/2016- TR 4-15 08/09/2016- TR 5-1A 10/15/2002- TR 5-2 05/15/2000- TR 5-3 10/15/2002- TR 5-4 08/09/2016- TR 5-5 08/09/2016- TR 6-1 03/10/2015- TR 6-2 07/31/2015- TR 6-3 11/19/2015- TR 9-1 09/05/2008- TR 14-1 06/16/2003 MMJCAB MU-2B-10 YET 67027 ORIG - 08/01/196722 - 12/27/1999- TR 2-1 10/31/2002- TR 2-2 09/27/2004- TR 2-3 02/05/2008- TR 3-2 07/30/2012- TR 4-1 10/31/2002- TR 4-2 10/31/2002- TR 4-3 10/31/2002- TR 4-4 04/28/2009- TR 4-6 05/21/2012- TR 4-7 05/21/2012- TR 4-8 05/21/2012- TR 4-9 05/21/2012- TR 4-10 05/21/2012 - TR 4-11 05/21/2012- TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 9-1 09/05/2008 - TR14-1 06/16/2003 MM JCAB MU-2B-15 YET 68101 ORIG - 04/01/19684 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 3-2 07/30/2012 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 05/21/2012 - TR 4-11 05/21/2012 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 9-1 09/05/2008 - TR 14-1 06/16/2003 MM JCAB MU-2B-20 YET 68035 ORIG - 04/01/1968 19 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/31/2017 - TR 2-5 05/29/2015 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 10/21/2016 - TR 2-10 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012- TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 08/09/2016 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 - TR 14-1 06/16/2003 MM JCAB MU-2B-25 YET 71370 ORIG - 12/01/1971 15 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/31/2017 - TR 2-5 05/29/2015 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 10/21/2016 - TR 2-10 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 08/09/2016 - TR 4-11 08/09/2016- TR 4-13 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 - TR S1-1 06/16/2003 MM JCAB MU-2B-26 YET 74132 ORIG - 05/01/1974 14 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/31/2017 - TR 2-5 05/29/2015 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 10/21/2016 - TR 2-10 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 08/09/2016 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000- TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 MM FAA MU-2B-25/26/26A MR-0215 ORIG - 08/01/1977 12 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4B 08/31/2017 - TR 2-5 05/29/2015 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 10/21/2016 - TR 2-10 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 08/09/2016 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015- TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 MM JCAB MU-2B-30 YET 69016 ORIG - 07/01/1969 20 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/23/2013 - TR 2-5A 08/31/2017 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 05/29/2015 - TR 2-10 10/21/2016 - TR 2-11 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018MM JCAB MU-2B-35 YET 70191 ORIG - 01/01/1971 17 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/23/2013 - TR 2-5A 08/31/2017 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 05/29/2015 - TR 2-10 10/21/2016 - TR 2-11 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 - TR 11-1 06/16/2003 MM JCAB MU-2B-36 YET 74125 ORIG - 05/01/1974 14 - 12/27/1999 - TR 2-1 10/31/2002- TR 2-3 02/05/2008 - TR 2-4A 08/23/2013 - TR 2-5A 08/31/2017 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 05/29/2015 - TR 2-10 10/21/2016 - TR 2-11 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 - TR 11-1 06/16/2003 MM FAA MU-2B-35/36A MR-0218 ORIG - 12/01/1977 14 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4 07/05/2013 - TR 2-5B 08/31/2017- TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 05/29/2015 - TR 2-10 10/21/2016 - TR 2-11 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 MM FAA MU-2B-40 MR-0333 ORIG - 09/01/1978 14 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4A 08/31/2017 - TR 2-5 05/29/2015 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 10/21/2016- TR 3-1 05/29/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 4-1 10/31/2002 - TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/16/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008 - TR 9-2 04/30/2018 MM FAA MU-2B-60 MR-0336 ORIG - 09/01/1978 14 - 12/27/1999 - TR 2-1 10/31/2002 - TR 2-2 09/27/2004 - TR 2-3 02/05/2008 - TR 2-4 07/05/2013 - TR 2-5B 08/31/2017 - TR 2-6 05/29/2015 - TR 2-7 05/29/2015 - TR 2-8 05/29/2015 - TR 2-9 05/29/2015 - TR 2-10 10/21/2016 - TR 2-11 10/21/2016 - TR 3-1 03/10/2015 - TR 3-2 07/30/2012 - TR 3-3 05/29/2015 - TR 3-4 05/29/2015 - TR 3-5 05/29/2015- TR 4-2 10/31/2002 - TR 4-3 10/31/2002 - TR 4-4 04/28/2009 - TR 4-5 05/29/2015 - TR 4-6 05/21/2012 - TR 4-7 05/21/2012 - TR 4-8 05/21/2012 - TR 4-9 05/21/2012 - TR 4-10 07/05/2013 - TR 4-11 08/09/2016 - TR 4-12 08/09/2016 - TR 4-13 08/09/2016 - TR 4-14 08/09/2016 - TR 5-1A 10/15/2002 - TR 5-2 05/15/2000 - TR 5-3 10/15/2002 - TR 5-4 08/09/2016 - TR 5-5 08/09/2016 - TR 6-1 10/15/2002 - TR 6-2 03/10/2015 - TR 6-3 07/31/2015 - TR 6-4 11/19/2015 - TR 6-5 11/19/2015 - TR 8-1 06/16/2003 - TR 9-1 09/05/2008- TR 9-2 04/30/2018Wiring Diagram Manual (WDM)Manual TC Model Doc# Rev. Temp. Rev. Issue Date WDM JCAB MU-2B-20 YET 71288 ORIG - 07/01/1971 - - 07/07/1993 WDM JCAB MU-2B-25 YET 71371 ORIG - 12/01/1971 5 - 08/27/1999 WDM FAA MU-2B-25 MR-0186 ORIG - 08/16/1976 - TR28-1 07/01/2014 WDM JCAB MU-2B-26 YET 74133 ORIG - 05/01/1974 2 - 08/27/1999 WDM FAA MU-2B-26/26A MR-0216 ORIG - 04/01/1977 3 - 08/27/1999 - TR 28-1 07/01/2014 - TR 28-2 07/01/2014 WDM JCAB MU-2B-30 YET 71289 ORIG - 07/01/1971 4 - 08/27/1999 WDM JCAB MU-2B-35 YET 70206 ORIG - 04/01/1971 5 - 08/27/1999 WDM JCAB MU-2B-36 YET 74126 ORIG - 05/01/1974 2 - 08/27/1999WDM FAA MU-2B-36A MR-0219 ORIG - 02/01/1978 3 - 08/27/1999 - TR 28-1 07/01/2014 - TR 28-2 07/01/2014 WDM FAA MU-2B-40 MR-0334 ORIG - 09/01/1978 4 - 10/01/1992 - TR 28-1 07/01/2014 WDM FAA MU-2B-60 MR-0337 ORIG - 09/01/1978 - TR 28-1 07/01/2014Maintenance Requirements Manual (MRM)Manual TC Model Doc# Rev. Temp. Rev. Issue Date MRM JCAB&FAA ALL MR-0178-2 ORIG - 07/02/1976 REISSUED - 07/07/2003 1 - 07/10/2017 - TR 1 06/29/2018 MRM JCAB&FAA ALL MR-0179-2 ORIG - 07/02/1976 REISSUED - 07/07/2003 1 - 07/10/2017 - TR 1 06/29/2018Structural Repair Manual (SRM)Manual TC Model Doc# Rev. Temp. Rev. Issue Date SRM FAA&JCAB ALL YET 72035A - - 01/01/1997 2 - 01/25/2002 - TR 1-1 03/15/2002 - TR 1-2 03/15/2002 - TR 1-3 05/29/2015 - TR 1-4 05/29/2015 - TR 1-5 05/29/2015 - TR 1-6 09/30/2015 - TR 2-1 03/15/2002 - TR 2-2 09/30/2016 - TR 3-1 08/31/2017 - TR 4A-1 05/29/2015 - TR 4A-2 05/29/2015 - TR 4A-3 05/29/2015 - TR 4A-4 05/29/2015 - TR 4A-5 05/29/2015 - TR 4A-6 05/29/2015 - TR 4A-7 09/30/2015 - TR 4A-8 08/31/2017 - TR 4A-9 08/31/2017 - TR 4A-10 08/31/2017 - TR 4B-1 05/29/2015 - TR 4B-2 05/29/2015 - TR 4B-3 05/29/2015- TR 4B-5 05/29/2015 - TR 4B-6 09/30/2015 - TR 4B-7 09/30/2015 - TR 4B-8 08/31/2017 - TR 4B-9 08/31/2017 - TR 4B-10 08/31/2017 - TR 4B-11 08/31/2017 - TR 4B-12 08/31/2017 - TR 4B-13 08/31/2017 - TR 4B-14 08/31/2017 - TR 5-1 09/27/2004 - TR 5-2 09/27/2004 - TR 5-3 09/27/2004 - TR 5-4 09/27/2004 - TR 5-5 09/27/2004 - TR 5-6 09/27/2004 - TR 5-7 09/27/2004 - TR 5-8 09/27/2004 - TR 6-1 09/27/2004 - TR 6-2 05/29/2015- TR 6-3A 08/31/2017Illustrated Parts Catalog (IPC)Manual TC Model Doc# Rev. Temp. Rev. Issue Date IPC JCAB MU-2B YET 67165 ORIG - 09/01/1967 12 - 04/16/2001 - TR 2-1 02/05/2008 - TR 2-2 04/28/2009 - TR 2-3 07/30/2012 - TR 2-4 07/30/2012 - TR 2-5 07/30/2012 - TR 2-6 07/30/2012 - TR 2-7 05/21/2012 - TR 2-8 03/10/2015 - TR 2-9 03/10/2015 - TR 2-10 01/15/2016 - TR 2-11 08/09/2016 - TR 2-12 08/09/2016 - TR 2-13 08/09/2016 - TR 2-14 08/09/2016 - TR 2-15 08/09/2016 - TR 2-16 08/09/2016 - TR 2-17 08/09/2016 - TR 2-18 08/09/2016 - TR 2-19 02/07/2020 - TR 2-20 02/07/2020 - TR 2-21 02/07/2020-02/07/20202-23TRORIG - 05/01/1967 IPC JCAB MU-2B-10 YET6702813 04/16/20012-1 02/05/2008TR2-2 02/05/2008TR2-3 10/13/2009TR2-4 04/28/2009TR04/28/20092-5TR-07/30/20122-6TR-2-707/30/2012TR-2-807/30/2012TR-ORIG - 10/01/196868170IPC JCAB MU-2B-15 YET12 - 04/16/20012-1 02/05/2008TR2-2 02/05/2008TR2-3 10/13/2009TR2-4 04/28/2009TR2-5 04/28/2009TR2-6 07/30/2012TR2-7 07/30/2012TRTR2-8 07/30/201268036BORIG - 05/01/1968 IPC JCAB MU-2B-20 YET04/16/20011 -02/05/20082-1TR-02/05/20082-2-TR02/05/20082-3-TR10/13/20092-4-TR04/28/20092-5TR-2-604/28/2009TR-07/30/20122-7TR-2-807/30/2012TR-2-907/30/2012TR-2-1007/30/2012TR-07/30/20122-11-TR05/21/20122-12TR-2-1303/10/2015TR-2-1401/15/2016TR-2-1503/17/2016TR-2-1603/17/2016TR-03/17/20162-17-TR03/17/20162-18-TR06/29/20182-19A-TR06/29/20182-20ATR-2-2108/09/2016TR-08/09/20162-22TR-2-2308/09/2016TR-08/09/20162-24TR-08/09/20162-25-TR-08/09/20162-27TR08/09/20162-28-TR08/09/20162-29-TR2-3008/09/2016TR-2-3106/16/2017TR-06/16/20172-32-TR2-3307/10/2017TR-2-3408/31/2017TR-08/31/20172-35TR-2-3608/31/2017TR-2-3709/15/2017TR-04/30/20182-38-TR2-3906/29/2018TR-2-4002/07/2020TR-02/07/20202-41TR-02/07/20202-42-TR02/07/20202-43-TR02/07/20202-44TR-2-4502/07/2020TR-2-4602/07/2020TR-02/07/20202-47-TR2-4802/07/2020TR-2-4902/07/2020TR-2-5002/07/2020TR-2-5102/07/2020TR-02/07/20202-52-TR72092A ORIG - 08/01/1974IPC JCAB&FAA MU-2B-25 YET04/16/20011 -02/05/20082-1-TR02/05/20082-2TR-10/13/20092-3-TR2-404/28/2009TR-2-504/28/2009TR-07/30/20122-6TR-07/30/20122-7-TR07/30/20122-8-TR2-907/30/2012TR-2-1007/01/2014TR-2-1107/01/2014TR-07/01/20142-12-TR2-1307/01/2014TR-2-1405/21/2012TR-2-1503/10/2015TR-11/30/20152-16-TR11/30/20152-17-TR2-1801/15/2016TR-2-19A06/29/2018TR-06/29/20182-20A-TR-08/09/20162-22TR08/09/20162-23-TR08/09/20162-24-TR2-2508/09/2016TR-2-2608/09/2016TR-08/09/20162-27-TR2-2808/09/2016TR-2-2906/16/2017TR-06/16/20172-30TR-08/31/20172-31-TR08/31/20172-32-TR2-3308/31/2017TR-2-3409/15/2017TR-2-3504/30/2018TR-02/07/20202-36-TR2-3702/07/2020TR-2-3802/07/2020TR-2-3902/07/2020TR-02/07/20202-40-TR02/07/20202-41-TR2-4202/07/2020TR-2-4302/07/2020TR-02/07/20202-44-TR74134A ORIG - 08/01/1974IPC JCAB&FAA MU-2B-26/26A YET04/16/20011 -2-102/05/2008TR-2-202/05/2008TR-02/05/20082-3TR-10/13/20092-4-TR07/30/20122-5-TR07/30/20122-6TR-2-707/30/2012TR-2-807/30/2012TR-07/30/20122-9-TR2-1007/01/2014TR-2-1107/01/2014TR-07/01/20142-12-TR2-1307/01/2014TR-2-1403/10/2015TR-05/22/20162-15-TR2-1601/15/2016TR-2-17A06/29/2018TR-2-18A06/29/2018TR-08/09/20162-19-TR08/09/20162-20-TR2-2108/09/2016TR-2-2208/09/2016TR-08/09/20162-23-TR-08/09/20162-25TR08/09/20162-26-TR06/16/20172-27-TR2-2806/16/2017TR-2-2907/10/2017TR-08/31/20172-30-TR2-3108/31/2017TR-2-3208/31/2017TR-09/15/20172-33TR-2-3409/15/2017TR-2-3504/30/2018TR-02/07/20202-36-TR2-3702/07/2020TR-2-3802/07/2020TR-02/07/20202-39TR-02/07/20202-40-TR02/07/20202-41-TR02/07/20202-42TR-2-4302/07/2020TR-2-4402/07/2020TR-02/07/20202-45-TR2-4602/07/2020TR-ORIG - 10/01/196969019IPC JCAB MU-2B-30 YET14 - 04/16/20012-102/05/2008TR-02/05/20082-2-TR02/05/20082-3-TR10/13/20092-4TR-2-504/28/2009TR-2-604/28/2009TR-07/30/20122-7-TR2-807/30/2012TR-2-907/30/2012TR-07/30/20122-10TR-03/10/20152-11-TR03/10/20152-12-TR2-1307/02/2015TR-2-1401/15/2016TR-2-15A06/29/2018TR-06/29/20182-16A-TR2-1708/09/2016TR-2-1808/09/2016TR-2-1908/09/2016TR-08/09/20162-20-TR08/09/20162-21-TR2-2208/09/2016TR-2-2308/09/2016TR-08/09/20162-24-TR。

42-------------------------------------ÅCorresponding author e-mail: gsgokavi@ †Present address: Solid State and Catalysis Laboratory, Department of Chemistry, Indian Institute of Technology-Bombay, Powai, Mumabi 400 076. ‡On lien from Department of Chemistry, Indian Institute of Technology-Bombay, Powai, Mumabi 400 076. E-mail: selvam@iitb.ac.in; selvam@iitm.ac.inPoly(Vinyl Alcohol) Supported 12-Tungstocobaltate (II) as a NovelHeterogeneous Catalyst for Oxidation of Benzyl AlcoholsSanjeev P. Maradur † and Gavisiddappa S. Gokavi Å Kinetics and Catalysis Laboratory, Department of Chemistry,Shivaji University, Kolhapur 416 004 Parasuraman Selvam ‡National Centre for Catalysis Research, Department of Chemistry,Indian Institute of Technology −Madras, Chennai 400 076[Received 14th January 2007]Abstract : In this paper, selective oxidation of alcohols to the corresponding carbonyl products using Oxone ® has been investigated on poly(vinyl alcohol) supported 12-tungstocobaltate (II), a heterogeneous catalyst. Variety of activated and non-activated alcohols has been effectively oxidized under relatively mild reaction conditions.R 1R 2CH 2OHR 1R 2CHO1. INTRODUCTIONOrganic-inorganic hybrid materials havemany distinct advantages over the conventional materials. Development of heterogeneous catalysts for the fine chemicalssynthesis has recently become a major area ofresearch in view of the advantages likesimplified recovery and reusability of thesematerials over the homogeneous systems [1,2].Majority of catalysts are based on silica, sinceits (chemical and thermal) stability, high surface area, good accessibility and organic groups can be robustly anchored to the surfaceto provide catalytic centers. However, it has limited stability in aqueous media since itcannot easily form membranes. Variety ofpolystyrene-based resins has been used as solidphase catalyst supports for organic synthesis, absorption and separation of chemicals [3,4].Polystyrene resins are rather hydrophobic andhence, their applications in aqueous media arelimited, whereas hydrophilic polymers possessbetter swell ability in water. Poly (vinyl alcohol) (PVA), a hydrophilic and a low cost polymer, would be a good choice in making such solid supports.Oxidation of alcohols to aldehydes and ketones has several industrial applications as well as in organic synthesis due to wide ranging utility of these products. Traditional alcohol oxidations use toxic, corrosive and expensive oxidants such as chromium (VI) and manganese complexes under stringent conditions such as high pressure or temperatures or use of strong mineral acids [5-8]. Other methods use molecular oxygen in the presence of stoichiometric amount of a reactive aldehyde, producing peracid as the actual oxidizing agent [9].However, due to increasing environmental concerns, oxidations use environmentally benign oxidants such as molecular oxygen or hydrogen peroxide. Oxidation with hydrogen peroxide is relatively less economical due to its cost and comparatively poor efficiency [10]. Oxone®, used in the present study, is convenient because it is readily available and has been used for various transformations in organic synthesis [11-16]. Recently, we have studied the homogeneous 12-tungstocobaltate (II) as a highly effective catalyst for the oxidation of aliphatic and benzylic alcohols [17].An interesting modification of the above described catalytic system would be the heterogenizationof the 12-tungstocobaltate (II) onto a polymer such as poly (vinyl alcohol) (PVA). In the present paper, we report the results on catalytic activity of PVA supported polyoxometalate (POM), 12-tungstocobaltate (II) as an active heterogenized and recyclable catalyst for the oxidation of benzylic alcohols with Oxone®. The POM, 12-tungstocobaltate (II) was selected due to its stability towards oxidative and hydrolytic decompositions.2. EXPERIMENTALThe catalyst 12-tungstocobaltate (II) was prepared as reported before [18] and was standardized spectrophotometrically. FTIR was recorded as KBr pellet on IR Spectrum GX series 49387. TGA-DTA was recorded on SDT-2960, TA Instruments, USA at the heating rate of 10o C/min under nitrogen atmosphere. SEM of the film was recorded ona LEO 143OVP instrument. Polyvinyl alcohol (Mol Wt. 1,25,000) was purchased from s.d. fine chemicals, Mumbai, India. The alcohols were of commercial grade samples, purchased from Lancaster, Mumbai. Potassium peroxomonosulfate was purchased from Across Chemicals. Acetonitrile and dichloromethane were purchased from s.d. fine chemicals (Mumbai) and were used without purification. Comparing their physical and spectral property data identified all raw materials used. Melting points were determined in open capillaries and are uncorrected.2.1.Preparation of polyvinyl alcohol supported12-tungstocobaltate (II)About 1 g of PVA was dissolved in 25 mL distilled water. To this viscous solution, about6 mL of glutaraldehyde was added as a crosslinking agent, and the mixture was stirred vigorously. To this, a solution of 12-tungstocobaltate (II) (0.5 g taken in 15 mL distilled water) was added with continuous stirring. Stirring was stopped after pre-crosslinking; then after adding 250 mL paraffin oil, the viscous mixture was stirred at a high speed for about 5 min followed by the additionof 2 mL Tween 80 surfactant. PVA supported POM beads were formed during the reverse suspension. At the end of the reaction, beads were washed with a mixture of toluene and petroleum ether (1:1, 3x200 mL) and then by methanol (100 mL) to extract the oil from the beads. The beads were subsequently washed with deionized water (500 mL), filtered and dried. Beads having the mesh size of 300 were used for catalytic runs.432.2. General procedureAlcohol (2.2 mmol) and Oxone® (1 mmol) were taken in 50:50 % aqueous acetonitrile mixture in a round-bottom flask followed by adding PVA-POM catalyst (0.10 g). The reaction mixture was stirred at room temperature and TLC monitored the progress of reaction. After completion of the reaction, supported catalyst was filtered and the resulting filtrate was extracted with dichloromethane (40 mL). The combined organic layer was washed with a solution of NaHCO3 and dried over MgSO4. The solution was then concentrated to obtain the crude carbonyl compound, which was purified by crystallization or distillation.3. RESULTS AND DISCUSSIONFTIR spectra of pure 12-tungstocobaltate (II), PVA and the supported 12-tungstocobaltate onto PVA are shown in Fig. 1(A-C). Spectrum of the catalyst (Fig. 1A) shows fundamental bands at 933, 862 and 756 cm-1 corresponding to W-O d, W-O b-W and W-O c-W stretching modes of the Keggin structure. A broad peak at 3392 cm-1and a sharp peak at 1619 cm-1 indicate the water associated with Keggin structure of the catalyst as either in the lattice or in the coordinated form. The spectrum of pure PVA (Fig. 1B) shows characteristic OH and CH2 stretching frequencies at 3458 and 2923 cm-1 along with smaller peaks at lower frequencies. The characteristic bands of the Keggin unit between 900 to 700 cm-1 were retained in the FTIR spectra of the supported catalyst (Fig. 1C), indicating no change in the nature of the catalyst after supporting it onto polymer network.19,20 This retainment of basic structureof the catalyst helped to use it as an efficient heterogeneous catalyst in the present study. The peaks due to water associated with the pure catalyst were also retained in the supported catalyst as evidenced by the broad peak at 3397 cm-1 and a sharp peak at 1657 cm-1 (Fig. 1C). Therefore, it becomes difficultto conclude quantitatively about the number of water molecules associated with 12-tungstocobaltate of the supported catalyst as compared to pure catalyst.Spectroscopic examination of the supported catalyst indicated that Keggin structure of the pure catalyst is retained. Note that catalyst was not released even after swelling the supported catalyst in water for 3-4 days since there was no significant weight loss. There was no leaching of the catalyst, which rules out the adsorption onto polymeric network. Therefore, binding of the catalyst to the polymer network might be by replacing of one or more of the coordinated water molecules of the catalyst by the -OH group of PVA. In order to know the coordinated water molecules in pure and supported catalyst, TGA and DTA analyses were performed (see Fig. 2). The TGA of pure PVA (Fig. 2A) shows an endothermic weight loss due to decomposition between 250º to 400o C. On the other hand, pure catalyst looses its coordinated water molecules (Fig. 2B) between 50º to and 180o C. From the % weight loss data, number of water molecules was calculated to be eight. The TGAof the supported catalyst (Fig. 2C) also shows weight loss between 50º and 180o C; here, number of water molecules lost accounts for five. While calculating the number of water molecules from the supported catalyst, contribution from pure PVA was subtracted. Therefore, the assumption that supported catalyst is bound to the polymer matrix through the replacement of some of the coordinated water molecules by the -OH groupof PVA is justifiedThe surface electron microscopic analysisof the films (see Fig. 3) of PVA-supported catalyst prepared by solution casting method revealed that catalyst is dispersed onto the polymer matrix.The present study addresses a method for efficient oxidation of alcohols by Oxone® in the presence of PVA supported of 12-tungstocobaltate (II). The uncatalyzed44Fig. 1. FT-IR spectra of (A) 12-tungstocobaltate (II), (B) poly(vinyl alcohol) and (C).45Fig. 2. TGA of (A) PVA, (B) 12-Tungstocobaltate (II) and (C) PVA-supported 12-tungstocobaltate.4647Fig. 3. SEM of PVA-supported 12-tungstocobaltate.Table 1: Oxidation of Alcohols to Carbonyl Compounds Catalyzed by PVASupported [Co II (W 12O 40]6-/Oxone®.Reactant Product Time (h) Yield (%)M.P/B.P of carbonyl compound (°C) M.P of 2,4-DNP derivative (°C)Benzyl alcohol Benzaldehyde 45 58 179 235 2-Nitrobenzyl alcohol 2-Nitrobenzaldehyde 40 65 43-45 264 4-Nitrobenzyl alcohol4-Nitrobenzaldehyde 40 67 104 >300 4-Methoxybenzyl alcohol4-Methoxy benzaldehyde43 63 248 254 4-Chlorobenzyl alcohol4-Chlorobenzaldehyde 40 69 47 263 4-Methylbenzyl alcohol4-Methylbenzaldehyde 48 48201-204231oxidation of alcohols occurred at a negligible rate under the experimental conditions. Results of this study (see Table 1) for various alcohols indicated that aldehyde is the only product obtained in comparatively high yields without further conversion to carboxylic acid. Thus, the reaction is initiated by oxidation of 12-tungstocobaltate (II) by Oxone® and converting it to 12-tungstocobaltate (III), an outer- sphere oxidant [17]. This oxidant generated in situ will react with alcohol in a rate-determining step,which involves the creation of negative charge. Such a transition state is more stabilized by electron-withdrawing substrate and makes the reaction to occur faster. In the present study, 4-nitro and 4-chlorobenzyl alcohols react at a faster rate than benzyl alcohol. After the first run, catalyst was filtered and added to a second run. In this case, conversion was 63 %. However, for the isolation of catalyst after this run, and recycling in the subsequent runs, the conversion was low. Hence, the catalyst is easy to prepare and can be readily separated from the reaction mixture by filtration. Also, the catalyst reuse is possible without any significant loss of activity and selectivity up to three cycles.4. CONCLUSIONSKeggin-type polyoxometalate12-tungstocobaltate (II) [{Co II(W12O40)6-}] catalyst supported on PVA is efficient for heterogeneous liquid phase peroxomonosulfate (Oxone®) oxidation of benzyl alcohols to the corresponding carbonyl compounds. The reduced reactivity in the heterogeneous vs. homogeneous is probably related to the more limited interaction of the catalyst-substrate upon heterogenization which limits contact and /or diffusion of the reacting species. The low cost, ease of handling and environmental concern makes this method useful for industrial applications. The catalyst reported here is important with the potential for commercial exploitation in organic oxidation reactions.Acknowledgements: G.S.G and S.M. thank the University Grants Commission (UGC) (F.12-29/2003[SR]) New Delhi for financial support.REFERENCES[1]J. H Clark, D.J. Macqarrie, Hand Book ofGreen Chemistry and Technology Ed.,Blackwell: Oxford, 2002.[2]P. T. Anastas, M. M. Kirchoff, T. C.Williamson., Appl. Catal. A: Gen,221(2001) 3.[3]R. B. Merrifield., J. Am. Chem. Soc. 85(1963) 2149.[4]K. Takigawa, Y. Inaki, R. M. Ottenbrite.,Functional Monomers and Polymers,Marcel Dekkar: New York, 1987.[5]R. A. Sheldon, and J. K. Kochi, MetalCatalyzed Oxidation of Organic Compounds, Academic Press: New York,1981.[6]M. Hudlicky, Oxidations in OrganicChemistry, American Chemical Society:Washington DC, 1990.[7]R. A. Sheldon, I. W. C. E. Arends, A.Dijksman., Catal. Today 57 (2000) 157. [8]W. P. Griffith, J. M. Joliffe., DioxygenActivation and Homogeneous CatalyticOxidation, Ed., Simandi, I. I. Elsevier:Amsterdam, 1991.[9]S. J. Murahashi, T. Naota, J. J. Hirai.,Org. Chem. 58 (1993) 7318; T. Inokuchii,K. Nakagawa, S. Torii, Tetrahedron. Lett.36 (1995) 3223; T. Iwaharna, S.Sakaguchi, Y. Nishiyama, Y. Ishii,Tetrahedron. Lett. 36 (1995) 6923.[10]U. R. Pillai, E. Shale-Denessie., Appl.Catal. A: Gen. 245 (2002) 103.[11]L. A. Wozniak, W. J. Stec, Tetrahedron.Lett. 40 (1999) 2637.48[12]L. A. Wozniak, M. Koziolkiewicz, A.Kobylanska, W. J. Stec., Bio. Org. Med.Chem. Lett. 8 (1998) 2641.[13]K. S. Webb, D. Levy., Tetrahedron. Lett.36 (1995) 5117.[14]K. S. Webb, S. J. Ruszkay., Tetrahedron.54 (1998) 401.[15]B. M. Trost, D. P. Curran, Tetrahedron.Lett. 22 (1981) 1287.[16]L. Baumstark, M. Beeson, P. C.Vasquez, Tetrahedron. Lett. 30 (1989)5567.[17]S. P. Maradur, S. B. Halligudi, G. S.Gokavi., Catal. Lett. 96 (2004) 165.[18]S. E. Denmark, D. C. Forbes, D. S. Hays,J.-S. Depue, R. G. Wilde., J. Org. Chem.60 (1995) 1391.[19]C. Edwards, C. Y. Thiel, B. Benac, J.Kniffton., Catal. 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专利名称：绣花数据存储设备
专利类型：发明专利
发明人：水野雅裕,二村正生,武藤幸好申请号：CN95105265.9
申请日：19950519
公开号：CN1121544A
公开日：
19960501
专利内容由知识产权出版社提供
摘要：把闪速存储器卡中的所有绣花数据拷贝到RAM中，在LCD上显示拷贝到RAM中的绣花数据的文件号。

当用户选择将要删除的绣花数据时，该数据从RAM和LCD中删除。

当选完将要删除的数据并按下结束键时，对闪速存储器卡初始化，然后留在RAM中的剩余绣花数据被拷贝到闪速存储器卡。

因此，一次完成在闪速存储器卡中的写数据操作，结果可以大大缩短删除许多绣花数据所需的重写时间。

申请人：兄弟工业株式会社
地址：日本名古屋市
国籍：JP
代理机构：中国专利代理(香港)有限公司
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•Rugged, reliable tube-to-tubesheet weld head with 200 amp torch•Welds projected, flush or recessed tubes with filler wire, or flush joints fusion-only •Unlimited torch rotation•Multiple-pass welds without stopping •Self-supporting on tubesheet•Welds in any position, including overhead •Air-operated “fixtures”speed up production•Compatible with Arc Machines’Model 215, 227 or 415 power suppliesMODEL 6TUBE-TO-TUBESHEET WELD HEADMKT 6 WH / MAY, 2000 / EHEADQUARTERS • Arc Machines, Inc. • 10500 Orbital Way, Pacoima, CA 91331 U.S.A. • Tel: 1-818-896-9556 • Fax: 1-818-890-3724EUROPEAN OFFICE • Arc Machines, Inc. • Chemin du Lavasson 2, CH-1196 Gland, Switzerland • Tel: +41 / 22 / 995.00.51 • Fax: +41 / 22 / 995.00.59GERMAN OFFICE • Arc Machines GmbH • Markelsbach 2 • D-53804 Much, Germany • Tel: 02245 / 91680 • Fax: 02245 / 916868UK OFFICE • Arc Machines UK Limited • Unit 4, Raynesway Park Drive, Derby, UK, DE21 7BH • Tel: 01332 / 574000 • Fax: 01332 / 757757AMI is an ISO 9001 Certified CompanyThe Arc Machines’Model 6 is a rugged, field-proven weld head for high-production welding of tube-to-tubesheet using the GTAW process.The Model 6 has exceptionally fast mount and dismount times for ease of operation and productivity.The torch is positioned on the tube to be welded by a pneumatically operated locating fixture.With the touch of a button, the locating fixture precisely locates itself over the tube to be welded.The “C”and “D”torches (for fillet welds) are spring-loaded torches with a chill follower.The chill follower is located on the inside of the tube to be welded and contacts the tube wall exactly opposite the electrode, thus minimizing the possibility of burn-through on thin-wall tubes.The mechanics of the spring-loaded torch allows it to perfectly track the shape of the tube regardless of minor ovality.The Arc Machines Model 6 Offers:•Servo-controlled AVC, rotation and synchronized wire feed•Servo-controlled AVC•Water-cooled torches•Assortment of torches for recessed, projected or flush tubes•Adjustable torch tilt•Automatically sets distance between electrode andtubesheet before arc initiation•Non-linear vertical tungsten travel prevents tube-end burn-off•Pulsed-current welding and synchronized pulsed-wire feed•Compatible with Arc Machines’Model 215, 227,or 415 power suppliesThe Model 6 can be equipped with several torches:•“C”T orch - for fillet welding of projected tubes•“D”T orch - for fillet welding of projected tubes withminiumum spacing between tubes•“E”T orch - for welding flush or recessed tubes•Gas chamber for welding titanium availableTechnical DataProcess:GTAW (TIG)Weld Current:200 ADC (maximum) Arc Voltage Control:AutomaticRotation Speed:0.1 to 10.0 RPMWire Feed Speed: 5 to 100 IPM(13 to 254 cm/min.) Torches - “C”, “D”,Water-cooled, 200 ADC and “E”:100% duty cycleT ungsten Size:1/16" or 3/32"(1,6 or 2,4 mm Ø)Wire Manipulator(Manual Adj.):Vertical, Horizontal and Angular Filler Wire:0.030" recommended(0,8mm Ø)Wire Spool: 2 lb., 4" standard spool(1 kg, 100mm)Weight:16 lbs.(7,3 kg) less cables Outline Drawing No.:40060014, 40060015,40060016, 40060110,40060113, 40060109 Applicable Specification:Spec.No.:6"C" TorchPhoto Courtesy of Verolme Machinefabriek ljsselmonde b.v.Specifications subject to change without notice.One Year Limited Warranty Made in the U.S.A.。

专利名称：PURGE STOCKER AND PURGING METHOD 发明人：ONISHI Shinji,MURATA Masanao,YAMAJI Takashi申请号：EP15810199.8申请日：20150421公开号：EP3157047A4公开日：20180307专利内容由知识产权出版社提供摘要：To provide a purge stocker and a purging method allowing a simple configuration of the device while reducing the consumption of the purge gas. A purge stocker 1 includes a first supply unit 20 including N first purge apparatuses 21 each having a first supply unit 22 configured to support a storage container F, a first supply pipe 23 configured to supply the purge gas into the storage container F supported by the first supporting unit 22, and a first flow rate adjusting unit 24 configured to adjust the flow rate of the purge gas in the first supply pipe 23; and a second supply unit 30 including M second purge apparatuses 31 each having a second supporting unit 32 configured to support the storage container F and a second supply pipe 34 configured to supply the purge gas into the storage container F supported by the second supporting unit 32. When a certain number of second supporting units 32 are provided with storage containers F, the second supply unit 30 supplies the storage containers F with the purge gas through the respective second supply pipes 34.申请人：Murata Machinery, Ltd.地址：3 Minami Ochiai-cho Kisshoin Minami-ku Kyoto-shi, Kyoto 601-8326 JP国籍：JP代理机构：Weickmann & Weickmann PartmbB 更多信息请下载全文后查看。

专利名称：INFORMATION PROCESSING UNIT, SYSTEM AND METHOD, AND PROCESSOR发明人：KANEKO, Motoi申请号：JP2006309263申请日：20060508公开号：WO06/123547P1公开日：20061123专利内容由知识产权出版社提供摘要：Information processing efficiency of a multiplexer system is improved. An information processing unit (1000) is provided with a main processor (200) for generally controlling the entire unit; a graphic processor (100) for performing image processing operation; and a main memory (50). The information processing unit (1000) is also provided with a DMA controller (28) for controlling transmission of m pieces of data at the same time (m is an integer satisfying m>1); a main memory (50) wherein the data for specific process is developed at first; and a group of buffers (12) composed of n buffers (n is an integer satisfying n>m) for storing data when data is transmitted from the main memory (50). When a plurality of data transmissions are performed at the same time, the first buffer among the group of buffers (12) is set for one transfer destination of the data and the second buffer is set for the other transfer destination of the data.申请人：KANEKO, Motoi地址：2-6-21, Minami-Aoyama, Minato-ku Tokyo 1070062 JP,c/o SONY COMPUTER ENTERTAINMENT INC., 2-6-21, Minami-Aoyama, Minato-ku Tokyo 1070062 JP 国籍：JP,JP代理机构：MORISHITA, Sakaki 更多信息请下载全文后查看。

• reacts with additives• forms oil/water emulsions• causes significant deterioration in the performance of the oil.• eliminates or reduces corrosion by removing any waterpresent in the oilStandard equipmentThe separator is working either with two or three phases and could easaly be changed between the two diffrent versions clarifier and purifier.MAB 206 complete with motorFeatures and benifitsCompact and robust design with the following benefits:• Simple installation, operation and maintenance• Internal paring disc for discharge of clean oil• Large sludge space• Sludge basket for easy removal of sludge• Flexibility: the bowl may be used either as purifier or clarifier• Extremely reliable, ensuring long service life eliminates or reduces corrosion by removing anywaterpresent in the oilPCHS00112EN 1309How to contact Alfa Laval Up-to-date Alfa Laval contact details for all countries arealways available on our website at .Alfa Laval reserves the right to change specifications without prior notification.Technical specificationsMax. throughput capacity 10.6 m 3/h 1)Sludge and water space 3.4 l Feed temperature range 0 - 100 °C Installed motor power 5.5 / 12 kW 2)Sound pressure 75 dB(A)3)1 ) Actual capacity depends on composition of feed and separation demands.2 )Without built-on pump 5.5 kW With built-on pump 12 kW 3 )According to ISO 3744 or 3746Shipping data (approximate)Net weight 420 kg (926 lbs)Gross weight 525 kg (1 157 lbs)Volume 2.1 m 3Dimensions1055 mm (3 ft 5 17/32 inch)Fig 3 MAB bowl arranged as a purifier for separating oils containing sludge and an appreciable quantity of water.Fig 2 MAB bowl arranged as a clarifier for separating oils containing sludge and a very small quantity of water.Clarifier 1. Oil inlet2. Clean oil outlet3. SludgePurifier 1. Oil inlet2. Clean oil outlet3. Sludge4. Oil/water interface5. Water outlet1810 mm (5 ft 11 17/64 inch)1430 m m (4 f t 8 19/64 i n c h )Utilities consumptionElectric power 3.3 – 8 kW 4)4 )Actual consumption depends on throughput capacity, feed characteristics.。

DescriptionThe ICX039DNB is an interline CCD solid-state image sensor suitable for PAL color video cameras with a diagonal 8mm (Type 1/2) system. Smear,sensitivity, D-range, S/N and other characteristics have been greatly improved compared with the ICX039BNB. High sensitivity and low dark current are achieved through the adoption of Ye, Cy, Mg and G complementary color mosaic filters and HAD (Hole-Accumulation Diode) sensors.This chip features a field period readout system and an electronic shutter with variable charge-storage time. Also, this outline is miniaturized by using original package.This chip is compatible with and can replace the ICX039BNB.Features •Low smear (–20dB compared with the ICX039BNB)••High D range (+2.5dB compared with the ICX039BNB)•High S/N•High resolution and low dark current •Excellent antiblooming characteristics•Ye, Cy, Mg, and G complementary color mosaic filters on chip •Continuous variable-speed shutter •Substrate bias:Adjustment free (external adjustment also possible with 6 to 14V)•Reset gate pulse:5Vp-p adjustment free (drive also possible with 0 to 9V)•Horizontal register:5V drive •Maximum package dimensions:φ13.2mmDevice Structure•Interline CCD image sensor •Image size:Diagonal 8mm (Type 1/2)•Number of effective pixels:752 (H) x 582 (V) approx. 440K pixels •Total number of pixels:795 (H) x 596 (V) approx. 470K pixels •Chip size:7.95mm (H) x 6.45mm (V)•Unit cell size:8.6µm (H) x 8.3µm (V)•Optical black:Horizontal (H) direction: Front 3 pixels, rear 40 pixelsVertical (V) direction : Front 12 pixels, rear 2 pixels•Number of dummy bits:Horizontal 22Vertical 1 (even fields only)•Substrate material:SiliconICX039DNBDiagonal 8mm (T ype 1/2) CCD Image Sensor for P AL Color Video CamerasSony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits.16 pin DIP (Ceramic)Optical black position (Top View)Pin No.Symbol Description Pin No.Symbol Description1 2 3 4 5 6 7 8Vφ4Vφ3Vφ2φSUBVφ1V LV DDV OUTVertical register transfer clockVertical register transfer clockVertical register transfer clockSubstrate clockVertical register transfer clockProtective transistor biasOutput circuit supply voltageSignal output910111213141516V GGV SSGNDRDφRGV DSUBHφ1Hφ2Output circuit gate biasOutput circuit sourceGNDReset drain biasReset gate clockSubstrate bias circuit supply voltageHorizontal register transfer clockHorizontal register transfer clockNote) : Photo sensorVLVφ1φSUBVφ2Vφ3Vφ4VDDVOUTVGGVDSUBVSSGNDRDφRGHφ1Hφ2Block Diagram and Pin Configuration (Top View)Pin DescriptionItem–0.3 to +50–0.3 to +18–55 to +10–15 to +20to +10to +15to +17–17 to +17–10 to +15–55 to +10–65 to +0.3–0.3 to +30–30 to +80–10 to +60V V V V V V V V V V V V °C °C∗1Ratings Unit RemarksAbsolute Maximum Ratings∗1 +27V (Max.) when clock width < 10µs, clock duty factor < 0.1%.Substrate clock φSUB – GND V DD , V RD , V DSUB , V OUT , V SS – GND Supply voltageV DD , V RD , V DSUB , V OUT , V SS – φSUB V φ1, V φ2, V φ3, V φ4– GND Clock input voltageV φ1, V φ2, V φ3, V φ4– φSUBVoltage difference between vertical clock input pins Voltage difference between horizontal clock input pins H φ1, H φ2– V φ4φRG , V GG – GND φRG , V GG – φSUB V L – φSUBPins other than GND and φSUB – V L Storage temperature Operating temperatureItemV DD V RD V GG V SS V L V DSUB V SUB ∆V SUB14.5514.551.756.0–315.015.02.0∗3∗415.4515.452.2514.0+3V V VV %V RD = V DD ∗5∗5Symbol Min.Typ.Max.Unit RemarksBias Conditions 2 [when used in substrate bias external adjustment mode]Output circuit supply voltage Reset drain voltage Output circuit gate voltage Output circuit source Protective transistor biasSubstrate bias circuit supply voltage Substrate voltage adjustment range Substrate voltage adjustment precision∗3V L setting is the V VL voltage of the vertical transfer clock waveform, or the same supply voltage as the V Lpower supply for the V driver should be used. (When CXD1267AN is used.)∗4Connect to GND or leave open.∗5The setting value of the substrate voltage (V SUB ) is indicated on the back of the image sensor by a specialcode. When adjusting the substrate voltage externally, adjust the substrate voltage to the indicated voltage. The adjustment precision is ±3%. However, this setting value has not significance when used in substrate bias internal generation mode.V SUB code — one character indicationCode and optimal setting correspond to each other as follows.DC CharacteristicsItemOutput circuit supply currentI DD5.010.0mASymbol Min.Typ.Max.Unit RemarksV SUB codeOptimal setting 6.0 6.57.07.58.08.59.09.510.010.511.011.512.012.513.013.514.0EfGhJKLmNPQRSTUVW<Example> "L" →V SUB = 9.0VItemV DD V RD V GG V SS V L V DSUB φSUB14.5514.551.7514.5515.015.02.0∗115.0∗215.4515.452.2515.45V V VVV RD = V DD Symbol Min.Typ.Max.Unit RemarksBias Conditions 1 [when used in substrate bias internal generation mode]Output circuit supply voltage Reset drain voltage Output circuit gate voltage Output circuit source Protective transistor biasSubstrate bias circuit supply voltage Substrate clockGrounded with 390Ωresistor∗1V L setting is the V VL voltage of the vertical transfer clock waveform, or the same supply voltage as the V Lpower supply for the V driver should be used. (When CXD1267AN is used.)∗2Do not apply a DC bias to the substrate clock pin, because a DC bias is generated within the CCD.Grounded with 390ΩresistorItemReadout clock voltageV VTV VH1, V VH2V VH3, V VH4V VL1, V VL2, V VL3, V VL4V φVI V VH1– V VH2I V VH3– V VH V VH4– V VH V VHH V VHL V VLH V VLLV φH V HL V RGL V φRGV RGLH – V RGLL V φSUB14.55–0.05–0.2–9.68.3–0.25–0.254.75–0.054.523.015.000–9.09.05.00∗15.024.015.450.050.05–8.59.650.10.10.10.50.50.50.55.250.055.50.825.0V V V VVp-p V V V V V V VVp-p V VVp-p VVp-p122222222222334445V VH = (V VH1+ V VH2)/2V VL = (V VL3+ V VL4)/2V φV = V VH n – V VL n (n = 1 to 4)High-level coupling High-level coupling Low-level coupling Low-level coupling Low-level coupling Horizontal transfer clock voltage Reset gate clock voltage ∗1Substrate clock voltageVertical transfer clock voltageSymbolMin.Typ.Max.Unit Waveform diagramRemarksItemSymbol Min.Typ.Max.Unit Waveform diagramRemarks∗1Input the reset gate clock without applying a DC bias. In addition, the reset gate clock can also be drivenwith the following specifications.Reset gate clock voltageV RGL V φRG–0.28.509.00.29.5V Vp-p44Clock Voltage ConditionsClock Equivalent Circuit ConstantItemCapacitance between vertical transfer clock and GNDC φV1, C φV3C φV2, C φV4C φV12, C φV34C φV23, C φV41C φH1C φH2C φHH C φRG C φSUBR 1, R 2, R 3, R 4R GND1800220045027064624784006815pF pF pF pF pF pF pF pF pF ΩΩCapacitance between vertical transfer clocksCapacitance between horizontal transfer clock and GND Capacitance between horizontal transfer clocks Capacitance between reset gate clock and GND Capacitance between substrate clock and GND Vertical transfer clock series resistor Vertical transfer clock ground resistorSymbol Min.Typ.Max.UnitRemarks H φ2H φ1V 12V φ4V φ3Vertical transfer clock equivalent circuit Horizontal transfer clock equivalent circuitDrive Clock Waveform Conditions (1) Readout clock waveform(2) Vertical transfer clock waveform100%90%10%0%V VT0VV VH = (V VH1+ V VH2)/2V VL = (V VL3+ V VL4)/2V φV = V VH n – V VL n (n = 1 to 4)(3) Horizontal transfer clock waveformV HL(4) Reset gate clock waveformV RGHV RGL + 0.5VV RGLV RGLHRG waveformV RGLLH φ1V RGLH is the maximum value and V RGLL is the minimum value of the coupling waveform during the period from Point A in the above diagram until the rising edge of RG. In addition, V RGL is the average value of V RGLH and V RGLL .V RGL = (V RGLH + V RGLL )/2Assuming V RGH is the minimum value during the period twh, then:V φRG = V RGH – V RGL(5) Substrate clock waveformV SUBClock Switching CharacteristicsItem Readout clock Vertical transfer clockDuring imagingDuring parallel-serialconversionReset gate clock Substrate clockV TV φ1, V φ2, V φ3, V φ4H φH φ1H φ2φRG φSUB2.3111.52.5205.38131.8205.38510.5150.010.013190.50.515150.010.013250190.5µsns ns µs ns µsDuring readout∗1∗2During drainchargeSymbol twh Min.Typ.Max.Min.Typ.Max.Min.Typ.Max.Min.Typ.Max.twl tr tfUnit Remarks ∗1 When vertical transfer clock driver CXD1267AN is used.∗2 tf ≥tr – 2ns.ItemHorizontal transfer clockH φ1, H φ21620ns∗3Symbol twoMin.Typ.Max.Unit Remarks ∗3 The overlap period for twh and twl of horizontal transfer clocks H φ1and H φ2is two.H o r i z o n t a l t r a n s f e r c l o c kImage Sensor Characteristics(Ta = 25°C) ItemSensitivitySaturation signalSmearVideo signal shading Uniformity between video signal channelsDark signalDark signal shading Flicker YFlicker R-YFlicker B-YLine crawl RLine crawl GLine crawl BLine crawl WLag SYsatSmSHy∆Sr∆SbYdt∆YdtFyFcrFcbLcrLcgLcbLcwLag5507206600.000320.00056202510102125533330.5mVmV%%%%%mVmV%%%%%%%%123445567888999910Ta = 60°CZone 0 and IZone 0 to II'Ta = 60°CTa = 60°C Symbol Min.Typ.Max.Unit Measurement method RemarksZone Definition of Video Signal ShadingMeasurement SystemChroma signal outputNote) Adjust the amplifier gain so that the gain between [∗A] and [∗Y], and between [∗A] and [∗C] equals 1.Image Sensor Characteristics Measurement MethodMeasurement conditions1)In the following measurements, the device drive conditions are at the typical values of the bias and clockvoltage conditions. (when used with substrate bias external adjustment, set the substrate voltage to the value indicated on the device.)2)In the following measurements, spot blemishes are excluded and, unless otherwise specified, the opticalblack level (OB) is used as the reference for the signal output, which is taken as the value of Y signal output or chroma signal output of the measurement system.Color coding of this image sensor & Composition of luminance (Y) and chroma (color difference) signalsmixed by pairs such as A1 and A2 in the A field. (pairs suchas B in the B field)As a result, the sequence of charges output as signals fromthe horizontal shift register (Hreg) is, for line A1, (G + Cy),(Mg + Ye), (G + Cy), and (Mg + Ye).These signals are processed to form the Y signal and chroma (color difference) signal. The Y signal is formed by adding adjacent signals, and the chroma signal is formed by subtracting adjacent signals. In other words, the approximation:Y= {(G + Cy) + (Mg + Ye)} ×1/2= 1/2 {2B + 3G + 2R}is used for the Y signal, and the approximation:R – Y= {(Mg + Ye) – (G + Cy)}= {2R – G}is used for the chroma (color difference) signal. For line A2, the signals output from Hreg in sequence are (Mg + Cy), (G + Ye), (Mg + Cy), (G + Ye).The Y signal is formed from these signals as follows:Y= {(G + Ye) + (Mg + Cy)} ×1/2= 1/2 {2B + 3G + 2R}This is balanced since it is formed in the same way as for line A1.In a like manner, the chroma (color difference) signal is approximated as follows:– (B – Y)= {(G + Ye) – (Mg + Cy)}= – {2B – G}In other words, the chroma signal can be retrieved according to the sequence of lines from R – Y and – (B – Y)in alternation. This is also true for the B field.Definition of standard imaging conditions1)Standard imaging condition I :Use a pattern box (luminance 706cd/m 2, color temperature of 3200K halogen source) as a subject. (Pattern for evaluation is not applicable.) Use a testing standard lens with CM500S (t = 1.0mm)as an IR cut filter and image at F5.6. The luminous intensity to the sensor receiving surface at this point is defined as the standard sensitivity testing luminous intensity.2)Standard imaging condition II :Image a light source (color temperature of 3200K) with a uniformity of brightness within 2% at all e a testing standard lens with CM500S (t = 1.0mm) as an IR cut filter. The luminous intensity is adjusted to the value indicated in each testing item by the lens diaphragm.1.SensitivitySet to standard imaging condition I . After selecting the electronic shutter mode with a shutter speed of 1/250s, measure the Y signal (Ys) at the center of the screen and substitute the value into the following formula.S = Ys ×[mV]2.Saturation signalSet to standard imaging condition II . After adjusting the luminous intensity to 10 times the intensity with average value of the Y signal output, 200mV, measure the minimum value of the Y signal.3.SmearSet to standard imaging condition II . With the lens diaphragm at F5.6 to F8, adjust the luminous intensity to 500 times the intensity with average value of the Y signal output, 200mV. When the readout clock is stopped and the charge drain is executed by the electronic shutter at the respective H blankings, measure the maximum value YSm [mV] of the Y signal output and substitute the value into the following formula.4.Video signal shadingSet to standard imaging condition II . With the lens diaphragm at F5.6 to F8, adjust the luminous intensity so that the average value of the Y signal output is 200mV. Then measure the maximum (Ymax [mV]) and minimum (Ymin [mV]) values of the Y signal and substitute the values into the following formula.SHy = (Ymax – Ymin)/200 ×100 [%]5.Uniformity between video signal channelsSet to standard imaging condition II . Adjust the luminous intensity so that the average value of the Y signal output is 200mV, and then measure the maximum (Crmax, Cbmax [mV]) and minimum (Crmin, Cbmin [mV]) values of the R – Y and B – Y channels of the chroma signal and substitute the values into the following formula.∆Sr = | (Crmax – Crmin)/200 | ×100 [%]∆Sb = | (Cbmax – Cbmin)/200 | ×100 [%]6.Dark signalSm =×100 [%] (1/10V method conversion value)××200YSm 5001101502507.Dark signal shadingAfter measuring 6, measure the maximum (Ydmax [mV]) and minimum (Ydmin [mV]) values of the dark signal output and substitute the values into the following formula.∆Ydt = Ydmax – Ydmin [mV]8.Flicker 1) FySet to standard imaging condition II . Adjust the luminous intensity so that the average value of the Y signal output is 200mV, and then measure the difference in the signal level between fields (∆Yf [mV]). Then substitute the value into the following formula.Fy = (∆Yf/200) ×100 [%]2) Fcr, FcbSet to standard imaging condition II . Adjust the luminous intensity so that the average value of the Y signal output is 200mV, insert an R or B filter, and then measure both the difference in the signal level between fields of the chroma signal (∆Cr, ∆Cb) as well as the average value of the chroma signal output (CAr, CAb).Substitute the values into the following formula.Fci = (∆Ci/CAi) ×100 [%] (i = r, b)9.Line crawlsSet to standard imaging condition II . Adjust the luminous intensity so that the average value of the Y signal output is 200mV, and then insert a white subject and R, G, and B filters and measure the difference between Y signal lines for the same field (∆Ylw, ∆Ylr, ∆Ylg, ∆Ylb [mV]). Substitute the values into the following formula.Lci = (∆Yli/200) ×100 [%] (i = w, r, g, b)10. LagAdjust the Y signal output value generated by strobe light to 200mV. After setting the strobe light so that it strobes with the following timing, measure the residual signal (Ylag). Substitute the value into the following g = (Ylag/200) ×100 [%]Ylag (lag)Y signal output 200mVLightFLDV1Strobe lighttimingOutput15VX S U BX V 2X V 1X S G 1X V 3X S G 2X V 4H φ2H φ1R G–9V C i r c u i t 1 (s u b s t r a t e b i a s i n t e r n a l g e n e r a t i o n m o d e )15VX S U BX V 2X V 1X S G 1X V 3X S G 2X V 4H φ2H φ1R G–9V C i r c u i t 2 (s u b s t r a t e b i a s e x t e r n a l a d j u s t m e n t m o d e )Spectral Sensitivity Characteristics(Excludes lens characteristics and light source characteristics)700650600550500450400Wave Length [nm]R e l a t i v e R e s p o n s e1.00.80.60.40.20.0Sensor Readout Clock Timing Chartunit : µsOdd FieldEven FieldV1V2V3V4V1V2V3V4T i m i n g C h a r t (V e r t i c a l S y n c )F L DV DB L KH DV 1V 2V 3V 4C CD O U TT i m i n g C h a r t (H o r i z o n t a l S y n c)745750135102034012351020221231231020752Notes on Handling1)Static charge preventionCCD image sensors are easily damaged by static discharge. Before handling be sure to take the following protective measures.a)Either handle bare handed or use non-chargeable gloves, clothes or material. Also use conductiveshoes.b)When handling directly use an earth band.c)Install a conductive mat on the floor or working table to prevent the generation of static electricity.d)Ionized air is recommended for discharge when handling CCD image sensors.e)For the shipment of mounted substrates, use boxes treated for the prevention of static charges.2)Solderinga)Make sure the package temperature does not exceed 80°C.b)Solder dipping in a mounting furnace causes damage to the glass and other defects. Use a grounded30W soldering iron and solder each pin in less than 2 seconds. For repairs and remount, cool sufficiently.c)To dismount an image sensor, do not use solder suction equipment. When using an electric desolderingtool, use a thermal controller of the zero cross On/Off type and connect it to ground.3)Dust and dirt protectionImage sensors are packed and delivered by taking care of protecting its glass plates from harmful dust and dirt. Clean glass plates with the following operation as required, and use them.a)Operate in clean environments (around class 1000 is appropriate).b)Do not either touch glass plates by hand or have any object come in contact with glass surfaces. Shoulddirt stick to a glass surface, blow it off with an air blower. (For dirt stuck through static electricity ionized air is recommended.)c)Clean with a cotton bud and ethyl alcohol if grease stained. Be careful not to scratch the glass.d)Keep in a case to protect from dust and dirt. To prevent dew condensation, preheat or precool whenmoving to a room with great temperature differences.e)When protective tape is applied before shipping, just before use remove the tape applied forelectrostatic protection. Do not reuse the tape.4)Do not expose to strong light (sun rays) for long periods; color filters will be discolored. When highluminance objects are imaged with the exposure level control by electronic-iris, the luminance of the image-plane may become excessive and discolor of the color filter will possibly be accelerated. In such a case, it is advisable that taking-lens with the automatic-iris and closing of the shutter during the power-off mode should be properly arranged. For continuous using under cruel condition exceeding the normal using condition, consult our company.5)Exposure to high temperature or high humidity will affect the characteristics. Accordingly avoid storage orusage in such conditions.6)CCD image sensors are precise optical equipment that should not be subject to too much mechanicalshocks.ICX039DNBa g e O u t l i n e U n i t : m m16p i n D I P (300m i l )r o f t h e e f f e c t i v e i m a g e a r e a .t h e p a c k a g e i s t h e h o r i z o n t a l r e f e r e n c e .f t h e p a c k a g e i s t h e v e r t i c a l r e f e r e n c e .o f t h e p a c k a g e i s t h e h e i g h t r e f e r e n c e .e f f e c t i v e i m a g e a r e a r e l a t i v e t o t h e c e n t e r o f t h e p a c k a g e (∗) ± 0.15m m .l e o f t h e e f f e c t i v e i m a g e a r e a r e l a t i v e t o H a n d V i s ± 1°.t h e b o t t o m “C ” t o t h e e f f e c t i v e i m a g e a r e a i s 1.41 ± 0.15m m .f e c t i v e i m ag e a r e a r e l a t i v e t o th e b o t t o m “C ”i s l e s s t h a n 60µm .t h e c o v e r g l a s s i s 0.75m m , a n d t h e r e f r a c t i v e i n d e x i s 1.5.a g e : T h e c e n t e r i s h a l f w a yb e t w e e n t w o p a i r s o f o p p o s i t e s i d e s , “B ”, “B '”.。

WARNING! This product is not fireproof. The fabric will burn if it comes into contact with an open flame or fuel source. Keep product away from direct flame. Failure to follow this warning may result in serious injury or death!WARNING! This product is for hunting purposes only! It is not to be used as a camping tent or for any other function. Failure to follow this warning may result in serious injury or death! WARNING! Do not use devices that produce fumes inside of blind. Vapors and fumes could result in carbon monoxide poisoning, serious injury, or death!WARNING! Do not allow children or adults to use lighted candles, matches, or other sources of fire near this product. Failure to follow this warning may result in serious injury or death! WARNING! Do not allow the material to cover your face. This may result in serious injury, suffocation, or death!WARNING! Do not allow children to use this product without direct adult supervision. Failure to follow this warning may result in serious injury or death!WARNING!Read all instructions and safety warnings and follow them thoroughly. Failure to follow these instructions mayresult in serious injury or death!TIPS FOR INCREASING PRODUCT LONGEVITYAlways store your blind in a cool dry place and make sure that your blind is completely dry and clean before storing in carrying bag. Never leave your blind outside for any longer than needed. This material may fade after long periods of time in direct sunlight.HARDWARE LISTPart #Description Qty UP77-0156[A] 5mm X 1'' Hex Bolt75UP77-0173[B] 5mm x 1 1/4'' Hex Bolt 12UP77-0157[C] 5mm x 1 1/2'' Hex Bolt 2UP77-00975mm Nylock Nut 89UP77-0002Nylon Washer 1Part #DescriptionQty UP15-0096End Frame Base - Male Piece 2UP15-0097End Frame Base - Female Piece 2UP15-0098End Frame Hoop 8UP15-0099Side Support8UP15-0100End Support - Male Piece 4UP15-0101End Support - Female Piece 4UP15-0102Waterfowl Door1UP15-0103Waterfowl Door Extension 1UP15-0104Waterfowl Door Latch 1UP15-0105Cross Support 4UP15-0372Lower Cross Support 8UP15-0106Anchor Stakes 4UP15-0107Blind Cover 1UP15-0108Window Cover 6UP15-0109Peek Window Cover 3UP15-0110Side Window Bungee - 48''4UP15-0111End Window Bungee - 30''2UP15-0112End Window Bungee - 60''2PARTS LISTNote: Hardware is not listed for pre-assembled Waterfowl Door Hinges.Bale BlindModel MGB6000January 2018. Published by Premier Outdoor Equipment, LLC., Windom, Minnesota © 2018 Premier Outdoor Equipment, LLC. All rights reserved.PO Box 454 • Windom, MN 56101 • (844) 745-7723 • Check to make sure you have all the required parts and hardware. If you find damaged or missing parts in a newly purchased product, please return this product to the retailer for replacement.Please read and follow all instructions and warnings. Failure to follow these instructions may result in serious injury or death!2WARNING! DO NOT over tighten the hardware. Over tightening can lead to structural damage and may negatively affect the performance of your blind. Failure to follow these instructions may result in serious injury or death!NOTE: All Steps require that you temporarily finger tighten all nuts and bolts until instructed to tighten. This will ensure proper alignment during assembly.Most parts of this model are manufactured to be universal in use, so there may be some parts containing holes that will not be used for assembly. To minimize confusion in the assembly process, please read these instructions in entirety before beginning.STEP 1. Attach the (2) end frame base male pieces to the (2) end frame base female pieces using (2) 5mm x 1’’ hex bolts [A] and (2) 5mm nylock nuts. Note: Only one shown here.READ THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.End Frame Male PieceEnd Frame Female PieceAEnd Frame HoopEnd Frame HoopEnd Frame HoopEnd Frame HoopEnd Frame BaseSTEP 2. Complete each end frame by connecting (4) end frame hoops to each assembled end frame base. Note: Only one shown here.3READ THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.STEP 3. Using (16) 5mm x 1’’ hex bolts [A] and (16) 5mm nylock nuts, attach (4) side supports to the outside of the assembled end frames in the illustrated locations. NOTE: For proper assembly the assembled end frames MUST mirror each other.End FrameEnd FrameSide SupportSide SupportSide SupportSide SupportAA AA AA AA AA A AAA AA4READ THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.STEP 4. Next, attach the (4) remaining side supports to the outside of the assembled end frames in the illustrated locations using (16) 5mm x 1’’ hex bolts [A] and (16) 5mm nylock nuts to secure.End FrameEnd FrameSide SupportSide SupportSide SupportSide SupportA AA AAAAA A AA AA AAA5AA End FrameEnd FrameWaterfowl DoorAACWaterfowl Door ExtensionWaterfowl DoorCREAD THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.STEP 5. Connect the waterfowl door extension to the pre-assembled waterfowl door using (2) 5mm x 1 1/2’’ hex bolts [C] and (2) 5mm nylock nuts.STEP 6. Using (4) 5mm x 1’’ hex bolts [A] and (4) 5mm nylock nuts, attach the assembledwaterfowl door to the outside of the assembled end frames in the illustrated locations.6AASide SupportsAA AAAA AAA ACross SupportsREAD THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.AEnd FrameBBBAAB BBEnd FrameEnd Support Male PieceEnd Support Male PiecesEnd Support Male PieceEnd Support Female PieceEnd Support Female PieceEnd SupportFemale PiecesBBASTEP 7. Attach the (4) end support male pieces to the (4) end support female pieces using (4) 5mm x 1’’ hex bolts [A] and (4) 5mm nylock nuts.STEP 8. Next, secure the assembled end supports to the illustrated locations on the end frames using (8) 5mm x 1 1/4’’ hex bolts [B] and (8) 5mm nylock nuts.STEP 9. Using (12) 5mm x 1’’ hex bolts [A] and (12) 5mm nylock nuts, attach the cross supports to the outer holes on the top three side supports .7Cross Support Assembly HolesBBBBAAAAAAAAAAAAAAAA AAAALower Cross SupportsLower Cross SupportsSide SupportsWaterfowl DoorGroundBBAAASide SupportWaterfowl Door LatchREAD THIS MANUAL IN ITS ENTIRETY PRIOR TO USING THIS PRODUCT.STEP 12. Using (1) 5mm x 1’’ hex bolt [A], (1) nylon washer and (1) 5mm nylock nut attach the waterfowl door latch to the center hole on the side support above the waterfowl door.STEP 10. Attach (4) lower cross supports to the remaining cross support assembly holes using (4) 5mm x 1 1/4’’ hex bolts [B] and (4) 5mm nylock nuts to secure. Then, finish connecting these (4) lower cross supports to the side supports using (8) 5mm x 1’’ hex bolts [A] and (8) 5mm nylock nuts.STEP 11. Secure the reaming the lower cross supports to the outer holes on the three side supports below the waterfowl door using (12) 5mm x 1’’ hex bolts [A] and (12) 5mm nylock nuts.STEP 13. SECURELY TIGHTEN ALL NUTS AND BOLTS AT THIS TIME.STEP 14. Ensuring the zippered corners are open, carefully pull the fabric cover over the assembled frame noting the waterfowl door opening is on the same side as the waterfowl door. Align and secure the fabric cover on the assembled frame using inner ties and zippered corners.Anchoring the bale blind: (4) anchor stakes are included to secure your bale blind to theground. The (4) anchor stakes are to be placed in the corners of the interior of the blind as illustrated.AnchorSTEP 15. Secure the pre-assembled windows between the fabric cover and the assembled frame using bungee hooks.。