Patents by Inventor Ryan J. Eismin
Ryan J. Eismin has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20260118567Abstract: A biaxially stretched reflective polarizer includes a plurality of biaxially stretched polymeric layers numbering at least 10 in total where each of the polymeric layers has an average thickness of less than about 500 nm. The reflective polarizer is stretched along orthogonal first and second directions by respective S1 and S2 percentages where S2?2% and S2/S1?10, such that for at least one location on the reflective polarizer, a substantially normally incident light at the at least one location, and for a visible wavelength range extending from about 420 nm to about 680 nm, the plurality of polymeric layers has: an average reflectance of greater than about 60% when the incident light is polarized along the first direction; and an average transmittance of greater than about 60% and an average reflectance of less than about 1% when the incident light is polarized along the second direction.Type: ApplicationFiled: February 19, 2024Publication date: April 30, 2026Inventors: Yifan Xu, Adam D. Haag, Lin Zhao, Robert D. Taylor, David J.W. Aastuen, Ryan J. Eismin, Justin M. Foley, Mark B. O'Neill, Matthew C. Dachel, Jacob W. Jaeschke, Kayla A. McGrath, Susan L. Kent
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Publication number: 20260055304Abstract: Self-priming adhesive articles include a release liner with a release surface, an adhesion promotion layer on the release surface, and an optically clear adhesive layer in contact with the adhesion promotion layer. The adhesion between the adhesive layer and the adhesion promotion layer is higher than that of the adhesion between the adhesion promotion layer and the release liner, such that the adhesion promotion layer remains adhered to the surface of the adhesive layer upon removal from the release liner. The adhesive articles can be prepared by applying the adhesion promotion layer to the release liner and applying the adhesive layer to the adhesion promotion layer, or by applying to the adhesion promotion layer to the surface of the adhesive layer and then contacting the adhesion promotion layer-coated adhesive layer to the release liner.Type: ApplicationFiled: September 20, 2023Publication date: February 26, 2026Inventors: Ryan J. Eismin, David T. Amos
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Patent number: 12496765Abstract: A system for laminating an adhesive to a component includes a liner including a first major surface facing the component and a second major surface opposite to the first major surface. An adhesive is disposed on the first major surface. The adhesive is configured to be laminated to the component. A support pad engages the second major surface of the liner for laminating the adhesive to the component. Each of the support pad and the liner undergoes deformation upon engagement of the support pad with the liner. The support pad includes a body made of an elastic pad material and includes an upper surface facing the component, a lower surface opposite to the upper surface, and a lateral surface disposed between the upper surface and the lower surface. The liner includes a conformable liner material having a liner elastic modulus from about 5 megapascals (MPa) to about 650 MPa.Type: GrantFiled: February 4, 2022Date of Patent: December 16, 2025Assignee: 3M INNOVATIVE PROPERTIES COMPANYInventors: Ryan J. Eismin, David J. McDaniel, Encai Hao
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Publication number: 20250199224Abstract: An optical film includes a plurality of alternating first and second polymeric layers, such that the first polymeric layers have a smaller average in-plane index of refraction than the second polymeric layers and the first polymeric layers have a glass transition temperature of at least 107 deg. C. The optical film may be a reflective polarizer. An optical stack includes a linear absorbing polarizer and the reflective polarizer disposed on, and bonded to, the absorbing polarizer. The reflective polarizer may have an optical reflectance of at least 60% for a first polarization state and an optical transmittance of at least 60% for an orthogonal second polarization state. When heated at 105 deg. C. for 15 minutes, a difference in shrinkage of the reflective polarizer and the absorbing polarizer along the first and second polarization states may be greater than about zero and 0.2%, respectively.Type: ApplicationFiled: March 6, 2025Publication date: June 19, 2025Inventors: Adam D. Haag, Yi-Chen Chen, Tze Yuan Wang, Hiroki Matsuda, Michelle L. Toy, Ryan J. Eismin, John F. VanDerlofske, III, David J. McDaniel, Matthew B. Johnson
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Patent number: 12271015Abstract: An optical film includes a plurality of alternating first and second polymeric layers, such that the first polymeric layers have a smaller average in-plane index of refraction than the second polymeric layers and the first polymeric layers have a glass transition temperature of at least 107 deg. C. The optical film may be a reflective polarizer. An optical stack includes a linear absorbing polarizer and the reflective polarizer disposed on, and bonded to, the absorbing polarizer. The reflective polarizer has an optical reflectance of at least 60% for a first polarization state and an optical transmittance of at least 60% for an orthogonal second polarization state. When heated at 105 deg. C. for 15 minutes, a difference in shrinkage of the reflective polarizer and the absorbing polarizer along the first and second polarization states is greater than about zero and 0.2%, respectively.Type: GrantFiled: May 20, 2020Date of Patent: April 8, 2025Assignee: 3M INNOVATIVE PROPERTIES COMPANYInventors: Adam D. Haag, Yi-Chen Chen, Tze Yuan Wang, Hiroki Matsuda, Michelle L. Toy, Ryan J. Eismin, John F. VanDerlofske, III, David J. McDaniel, Matthew B. Johnson
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Publication number: 20240109242Abstract: A system for laminating an adhesive to a component includes a liner including a first major surface facing the component and a second major surface opposite to the first major surface. An adhesive is disposed on the first major surface. The adhesive is configured to be laminated to the component. A support pad engages the second major surface of the liner for laminating the adhesive to the component. Each of the support pad and the liner undergoes deformation upon engagement of the support pad with the liner. The support pad includes a body made of an elastic pad material and includes an upper surface facing the component, a lower surface opposite to the upper surface, and a lateral surface disposed between the upper surface and the lower surface. The liner includes a conformable liner material having a liner elastic modulus from about 5 megapascals (MPa) to about 650 MPa.Type: ApplicationFiled: February 4, 2022Publication date: April 4, 2024Inventors: Ryan J. Eismin, David J. McDaniel, Encai Hao
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Publication number: 20240059937Abstract: The present invention is an adhesive delivery system including a conformable film having top and bottom faces, an adhesive releasably coated on at least a portion of the top face of the conformable film, and a light release liner adhered to the adhesive side opposite the conformable film.Type: ApplicationFiled: October 9, 2020Publication date: February 22, 2024Inventors: Andrew J. Stockholm, Ryan J. Eismin, Encai Hao, David J. McDaniel, Yongshang Lu, Karen J. Calverley
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Publication number: 20220236466Abstract: An optical film includes a plurality of alternating first and second polymeric layers, such that the first polymeric layers have a smaller average in-plane index of refraction than the second polymeric layers and the first polymeric layers have a glass transition temperature of at least 107 deg. C. The optical film may be a reflective polarizer. An optical stack includes a linear absorbing polarizer and the reflective polarizer disposed on, and bonded to, the absorbing polarizer. The reflective polarizer has an optical reflectance of at least 60% for a first polarization state and an optical transmittance of at least 60% for an orthogonal second polarization state. When heated at 105 deg. C. for 15 minutes, a difference in shrinkage of the reflective polarizer and the absorbing polarizer along the first and second polarization states is greater than about zero and 0.2%, respectively.Type: ApplicationFiled: May 20, 2020Publication date: July 28, 2022Inventors: Adam D. Haag, Yi-Chen Chen, Tze Yuan Wang, Hiroki Matsuda, Michelle L. Toy, Ryan J. Eismin, John F. VanDerlofske, III, David J. McDaniel, Matthew B. Johnson