公开(公告)号：US20150321408A1

公开(公告)日：2015-11-12

申请号：US14700284

申请日：2015-04-30

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Jianjian Wang ,  Jonathan Kien-Kwok Tong ,  Hadi Ghasemi ,  Xiaopeng Huang ,  James Loomis ,  Yanfei Xu

IPC: B29C47/00 ,  B29C71/02 ,  H01B1/24 ,  C09K5/14 ,  C08J5/18 ,  C08K3/04

CPC classification number: B29C48/0018 ,  B29C48/022 ,  B29C48/08 ,  B29C48/9135 ,  B29C48/914 ,  B29C55/005 ,  B29C55/06 ,  B29C55/18 ,  B29K2023/0683 ,  B29K2995/0005 ,  B29K2995/005 ,  B29K2995/0077 ,  B29L2007/008 ,  C08J5/18 ,  C08J2323/06 ,  C08K3/04 ,  C08K3/042 ,  C09K5/14 ,  D01F6/04 ,  D01F6/06 ,  D07B2205/201 ,  D07B2205/2014 ,  H01B1/24 ,  C08L23/06

Abstract: Process for continuous fabrication of highly aligned polymer films. A polymer-solvent solution is subjected to a high shear, high temperature, Couette flow to extrude a thin film having polymer chain disentanglement. The extruded thin film is frozen and the solvent is allowed to evaporate to form a dried film. The dried film is mechanically drawn using a constant force, adaptive-thickness drawing system to align polymer molecular chains through plastic deformation. A suitable polymer is ultra-high molecular weight polyethylene.

Abstract translation: 用于连续制造高度排列的聚合物膜的方法。 将聚合物 - 溶剂溶液经受高剪切，高温的Couette流，以挤出具有聚合物链解缠的薄膜。 将挤出的薄膜冷冻并使溶剂蒸发以形成干燥的膜。 使用恒定力自适应厚度拉伸系统机械拉伸干燥的膜，以通过塑性变形来调整聚合物分子链。 合适的聚合物是超高分子量聚乙烯。

公开(公告)号：US20240150183A1

公开(公告)日：2024-05-09

申请号：US18508634

申请日：2023-11-14

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Evelyn N. Wang ,  Svetlana Boriskina ,  Lee A. Weinstein ,  Sungwoo Yang ,  Bikramjit S. Bhatia ,  Lin Zhao ,  Elise M. Strobach ,  Thomas A. Cooper ,  David M. Bierman ,  Xiaopeng Huang ,  James Loomis

IPC: C01B33/158 ,  B01J13/00 ,  C01B33/14 ,  C04B14/06 ,  F24S10/95 ,  F24S20/20 ,  F24S23/70 ,  F24S70/20 ,  F24S80/56 ,  F24S80/65

CPC classification number: C01B33/1585 ,  B01J13/0091 ,  C01B33/14 ,  C04B14/064 ,  F24S10/95 ,  F24S20/20 ,  F24S23/70 ,  F24S70/20 ,  F24S80/56 ,  F24S80/65 ,  C01P2004/64 ,  C01P2006/16 ,  C01P2006/32 ,  F24S2023/872 ,  Y02E10/40

Abstract: A silica aerogel having a mean pore size less than 5 nm with a standard deviation of 3 nm. The silica aerogel may have greater than 95% solar-weighted transmittance at a thickness of 8 mm for wavelengths in the range of 250 nm to 2500 nm, and a 400° C. black-body weighted specific extinction coefficient of greater than 8 m2/kg for wavelengths of 1.5 μm to 15 μm. Silica aerogel synthesis methods are described. A solar thermal aerogel receiver (STAR) may include an opaque frame defining an opening, an aerogel layer disposed in the opaque frame, with at least a portion of the aerogel layer being proximate the opening, and a heat transfer fluid pipe in thermal contact with and proximate the aerogel layer. A concentrating solar energy system may include a STAR and at least one reflector to direct sunlight to an opening in the STAR.

公开(公告)号：US11851334B2

公开(公告)日：2023-12-26

申请号：US17091141

申请日：2020-11-06

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Evelyn N. Wang ,  Svetlana Boriskina ,  Lee A. Weinstein ,  Sungwoo Yang ,  Bikramjit S. Bhatia ,  Lin Zhao ,  Elise M. Strobach ,  Thomas A. Cooper ,  David M. Bierman ,  Xiaopeng Huang ,  James Loomis

IPC: F24S20/20 ,  C01B33/158 ,  B01J13/00 ,  F24S80/65 ,  F24S80/56 ,  C04B14/06 ,  C01B33/14 ,  F24S70/20 ,  F24S10/95 ,  F24S23/70

CPC classification number: C01B33/1585 ,  B01J13/0091 ,  C01B33/14 ,  C04B14/064 ,  F24S10/95 ,  F24S20/20 ,  F24S23/70 ,  F24S70/20 ,  F24S80/56 ,  F24S80/65 ,  C01P2004/64 ,  C01P2006/16 ,  C01P2006/32 ,  F24S2023/872 ,  Y02E10/40

Abstract: A silica aerogel having a mean pore size less than 5 nm with a standard deviation of 3 nm. The silica aerogel may have greater than 95% solar-weighted transmittance at a thickness of 8 mm for wavelengths in the range of 250 nm to 2500 nm, and a 400° C. black-body weighted specific extinction coefficient of greater than 8 m2/kg for wavelengths of 1.5 μm to 15 μm. Silica aerogel synthesis methods are described. A solar thermal aerogel receiver (STAR) may include an opaque frame defining an opening, an aerogel layer disposed in the opaque frame, with at least a portion of the aerogel layer being proximate the opening, and a heat transfer fluid pipe in thermal contact with and proximate the aerogel layer. A concentrating solar energy system may include a STAR and at least one reflector to direct sunlight to an opening in the STAR.

公开(公告)号：US20210094834A1

公开(公告)日：2021-04-01

申请号：US17091141

申请日：2020-11-06

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Evelyn N. Wang ,  Svetlana Boriskina ,  Lee A. Weinstein ,  Sungwoo Yang ,  Bikramjit S. Bhatia ,  Lin Zhao ,  Elise M. Strobach ,  Thomas A. Cooper ,  David M. Bierman ,  Xiaopeng Huang ,  James Loomis

IPC: C01B33/158 ,  B01J13/00 ,  F24S80/65 ,  F24S80/56 ,  F24S20/20 ,  C04B14/06 ,  C01B33/14 ,  F24S70/20 ,  F24S10/95 ,  F24S23/70

Abstract: A silica aerogel having a mean pore size less than 5 nm with a standard deviation of 3 nm. The silica aerogel may have greater than 95% solar-weighted transmittance at a thickness of 8 mm for wavelengths in the range of 250 nm to 2500 nm, and a 400° C. black-body weighted specific extinction coefficient of greater than 8 m2/kg for wavelengths of 1.5 μm to 15 μm. Silica aerogel synthesis methods are described. A solar thermal aerogel receiver (STAR) may include an opaque frame defining an opening, an aerogel layer disposed in the opaque frame, with at least a portion of the aerogel layer being proximate the opening, and a heat transfer fluid pipe in thermal contact with and proximate the aerogel layer. A concentrating solar energy system may include a STAR and at least one reflector to direct sunlight to an opening in the STAR.

公开(公告)号：US10427345B2

公开(公告)日：2019-10-01

申请号：US14700284

申请日：2015-04-30

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Jianjian Wang ,  Jonathan Kien-Kwok Tong ,  Hadi Ghasemi ,  Xiaopeng Huang ,  James Loomis ,  Yanfei Xu

IPC: B29C47/00 ,  C08J5/18 ,  B29C48/00 ,  C08K3/04 ,  H01B1/24 ,  C09K5/14 ,  B29C55/06 ,  B29C55/18 ,  B29C48/08 ,  B29C48/88 ,  B29L7/00 ,  D01F6/04 ,  D01F6/06 ,  B29K23/00 ,  B29C55/00

Abstract: Process for continuous fabrication of highly aligned polymer films. A polymer-solvent solution is subjected to a high shear, high temperature, Couette flow to extrude a thin film having polymer chain disentanglement. The extruded thin film is frozen and the solvent is allowed to evaporate to form a dried film. The dried film is mechanically drawn using a constant force, adaptive-thickness drawing system to align polymer molecular chains through plastic deformation. A suitable polymer is ultra-high molecular weight polyethylene.

公开(公告)号：US20190100439A1

公开(公告)日：2019-04-04

申请号：US16079172

申请日：2017-02-24

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Evelyn N. Wang ,  Svetlana Boriskina ,  Lee A. Weinstein ,  Sungwoo Yang ,  Bikramjit S. Bhatia ,  Lin Zhao ,  Elise M. Strobach ,  Thomas A. Cooper ,  David M. Bierman ,  Xiaopeng Huang ,  James Loomis

IPC: C01B33/158 ,  B01J13/00 ,  F24S80/65 ,  F24S80/56 ,  F24S23/70 ,  F24S20/20 ,  F24S10/95 ,  F24S70/20

Abstract: A silica aerogel having a mean pore size less than 5 nm with a standard deviation of 3 nm. The silica aerogel may have greater than 95% solar-weighted transmittance at a thickness of 8 mm for wavelengths in the range of 250 nm to 2500 nm, and a 400° C. black-body weighted specific extinction coefficient of greater than 8 m2/kg for wavelengths of 1.5 μm to 15 μm. Silica aerogel synthesis methods are described. A solar thermal aerogel receiver (STAR) may include an opaque frame defining an opening, an aerogel layer disposed in the opaque frame, with at least a portion of the aerogel layer being proximate the opening, and a heat transfer fluid pipe in thermal contact with and proximate the aerogel layer. A concentrating solar energy system may include a STAR and at least one reflector to direct sunlight to an opening in the STAR.

公开(公告)号：US10889501B2

公开(公告)日：2021-01-12

申请号：US16079172

申请日：2017-02-24

Applicant: Massachusetts Institute of Technology

Inventor： Gang Chen ,  Evelyn N. Wang ,  Svetlana Boriskina ,  Lee A. Weinstein ,  Sungwoo Yang ,  Bikramjit S. Bhatia ,  Lin Zhao ,  Elise M. Strobach ,  Thomas A. Cooper ,  David M. Bierman ,  Xiaopeng Huang ,  James Loomis

IPC: C01B33/158 ,  B01J13/00 ,  F24S80/65 ,  F24S80/56 ,  F24S20/20 ,  C04B14/06 ,  C01B33/14 ,  F24S70/20 ,  F24S10/95 ,  F24S23/70

Abstract: A silica aerogel having a mean pore size less than 5 nm with a standard deviation of 3 nm. The silica aerogel may have greater than 95% solar-weighted transmittance at a thickness of 8 mm for wavelengths in the range of 250 nm to 2500 nm, and a 400° C. black-body weighted specific extinction coefficient of greater than 8 m2/kg for wavelengths of 1.5 μm to 15 μm. Silica aerogel synthesis methods are described. A solar thermal aerogel receiver (STAR) may include an opaque frame defining an opening, an aerogel layer disposed in the opaque frame, with at least a portion of the aerogel layer being proximate the opening, and a heat transfer fluid pipe in thermal contact with and proximate the aerogel layer. A concentrating solar energy system may include a STAR and at least one reflector to direct sunlight to an opening in the STAR.