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특허 상세정보

Light-weight structural panel

국가/구분 United States(US) Patent 등록
국제특허분류(IPC7판) E04C-002/26    B32B-003/10    B32B-015/08   
미국특허분류(USC) 052/791.1; 052/796.1; 428/138; 428/458; 428/464
출원번호 US-0841339 (2001-04-24)
발명자 / 주소
출원인 / 주소
대리인 / 주소
    Nassif, Omar A.
인용정보 피인용 횟수 : 19  인용 특허 : 9
초록

A structural panel comprises a metal and fibrous composite in which the metal outer skins have a minimum thickness of 0.005 in. exceeding foils and a maximum thickness of 0.012 in. while the fibrous core ranges between 0.01 in. and 0.05 in. The panel is a stiff, lightweight substitute for thicker metals and may replace light metal sheets such as aluminum with a composite in which the metal skins comprise sheets from heavier metals such as steel. The fibrous core is a web which is adhesively bonded to the metal skins and which has a plurality of weight-re...

대표
청구항

A structural panel comprises a metal and fibrous composite in which the metal outer skins have a minimum thickness of 0.005 in. exceeding foils and a maximum thickness of 0.012 in. while the fibrous core ranges between 0.01 in. and 0.05 in. The panel is a stiff, lightweight substitute for thicker metals and may replace light metal sheets such as aluminum with a composite in which the metal skins comprise sheets from heavier metals such as steel. The fibrous core is a web which is adhesively bonded to the metal skins and which has a plurality of weight-re...

이 특허를 인용한 특허 피인용횟수: 19

  1. Preisler, Darius J.; Heikkila, Christopher A.. Assembly including a compression-molded, composite panel having a cellulose-based core and a hinged mounting flange. USP2017019539958.
  2. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system for a vehicle and including a pair of opposing cargo trim panels, each of which is made by a composite, compression molding process and has a wood grain finish. USP2016059346375.
  3. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system including a vehicle load floor having a cellulose-based core and made by a composite, compression molding process and having a wood grain finish. USP2016129511690.
  4. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system including a vehicle load floor having a cellulose-based core with a cellular structure and made by a composite, compression molding process and having a wood grain finish. USP2017109776536.
  5. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system including a vehicle load floor made by a composite, compression molding process and having a wood grain finish. USP2016049308945.
  6. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system including an automotive vehicle seat having a cargo trim panel made by a composite, compression molding process and having a wood grain finish. USP2015099126537.
  7. Preisler, Darius J.; Heikkila, Christopher A.; Mitchell, Steven A.; Schmelzer, Jeffrey P.. Cargo management system including an automotive vehicle seat having a cargo trim panel made by a composite, compression molding process and having a wood grain finish. USP2016079399435.
  8. Speer, Dwaine D.. Composite panel having perforated foam core and method of making the same. USP2018039908315.
  9. Preisler, Darius J.; Heikkila, Christopher A.. Deep-drawn marine hull having a sandwich structure and watercraft utilizing same. USP2018019873488.
  10. Preisler, Darius J.; Heikkila, Christopher A.. Deep-drawn marine hull having a sandwich structure with a cellulose-based core and watercraft utilizing same. USP2017029567037.
  11. Peterson, John; Lambert, James. Flooring for vehicle decks and manufactured housing. USP2018069988097.
  12. Peterson, John; Lambert, James. Flooring for vehicle decks and manufacturing housing. USP20180910077079.
  13. Renck, Lawrence E.; Demare, Stéphane. Laminated structures constructed from adhesively joined sheet material layers. USP2004116815022.
  14. Preisler, Darius J; Heikkila, Christopher A.; Mitchell, Steven A.. Method of making a laminated trim component at a pair of spaced first and second molding stations. USP20190110166704.
  15. Preisler, Darius J.; Heikkila, Christopher A.. Method of making a sandwich-type composite panel having a cellulose-based core and a living hinge and panel obtained by performing the method. USP2016129527268.
  16. Preisler, Darius J.; Heikkila, Christopher A.. Method of making a sandwich-type composite panel having a cellulose-based core and a living hinge and panel obtained by performing the method. USP2018019878526.
  17. Preisler, Darius J.; Heikkila, Christopher A.. Method of making a sandwich-type composite panel having a living hinge and panel obtained by performing the method. USP2016089427942.
  18. Preisler, Darius J.; Heikkila, Christopher A.. Method of making a sandwich-type, compression-molded, composite component having a cellulose-based core and improved surface appearance. USP2017079707725.
  19. Preisler, Darius J.; Heikkila, Christopher A.. Method of making a sandwich-type, compression-molded, composite component having improved surface appearance. USP2017099770849.