公开(公告)号：US20160068926A1

公开(公告)日：2016-03-10

申请号：US14852028

申请日：2015-09-11

Applicant: Justin Langley

Inventor： Justin Langley

IPC: C22B1/08 ,  C22B59/00

CPC classification number: H01M8/0618 ,  B01D47/00 ,  B01D53/326 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C01B3/348 ,  C01B2203/02 ,  C01B2203/0233 ,  C01B2203/06 ,  C01B2203/0833 ,  C01B2203/1235 ,  C01B2203/84 ,  C10G1/002 ,  C10J3/84 ,  C10J3/86 ,  C10J2200/12 ,  C10J2300/16 ,  C10J2300/1643 ,  C10J2300/1646 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  H01M8/0675 ,  H01M8/14 ,  H01M8/188 ,  H01M8/20 ,  Y02E20/18 ,  Y02E60/324 ,  Y02W30/54

Abstract: Method of combining industrial processes having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while enabling environmentally and sustainably sound practices. Maximum chemical energy is retained throughout feedstock processing. A hybrid thermochemical cycle couples staged reforming with hydrogen production and chlorination. Hydrogen generated is used to upgrade feedstocks including bitumen, shale, coal, and biomass. Residues of upgrading are chlorinated, metals of interest are removed, and the remainder is reacted with ammonia solution and carbon dioxide to form carbonate minerals. The combination provides emissions free production of synthetic crude oil and derivatives, as well as various metals and fertilizers. Sand and carbonate minerals are potentially the only waste streams. Through this novel processing, major carbon dioxide reduction is afforded by minimizing direct oxidation. Supplemental heat to run the reactions is obtained through external means such as concentrated solar, geothermal, or nuclear.

Abstract translation: 结合具有固有碳捕获和转换功能的工业过程的方法，提供最大的灵活性，效率和经济性，同时实现环保和可持续的良好做法。 在整个原料加工过程中保留最大的化学能。 混合热化学循环将分级重整与氢气生产和氯化相结合。 产生的氢气用于升级原料，包括沥青，页岩，煤和生物质。 升级废物被氯化，去除金属，其余的与氨溶液和二氧化碳反应形成碳酸盐矿物。 该组合提供无排放的合成原油及其衍生物以及各种金属和肥料的生产。 砂和碳酸盐矿物质潜在地是唯一的废物流。 通过这种新型处理，通过最小化直接氧化来提供主要的二氧化碳还原。 通过诸如太阳能集热，地热或核的外部手段获得运行反应的补充热量。

公开(公告)号：US09786940B2

公开(公告)日：2017-10-10

申请号：US15103876

申请日：2016-01-18

Applicant: Justin Langley

Inventor： Justin Langley

IPC: C01B3/34 ,  H01M8/0612 ,  B01D47/00 ,  C01B3/00 ,  C10G1/00 ,  C10J3/84 ,  C10J3/86 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  B01D53/32 ,  C01B3/02 ,  H01M8/0662 ,  H01M8/14 ,  H01M8/18 ,  H01M8/20

CPC classification number: H01M8/0618 ,  B01D47/00 ,  B01D53/326 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C01B3/348 ,  C01B2203/02 ,  C01B2203/0233 ,  C01B2203/06 ,  C01B2203/0833 ,  C01B2203/1235 ,  C01B2203/84 ,  C10G1/002 ,  C10J3/84 ,  C10J3/86 ,  C10J2200/12 ,  C10J2300/16 ,  C10J2300/1643 ,  C10J2300/1646 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  H01M8/0675 ,  H01M8/14 ,  H01M8/188 ,  H01M8/20 ,  Y02E20/18 ,  Y02E60/324 ,  Y02W30/54

Abstract: Disclosed are systems and methods having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while simultaneously enabling environmentally and sustainably sound practices. A hybrid thermochemical cycle couples staged reforming with hydrogen production and residue chlorination. The residues of the upgrading are chlorinated, metals of interest are removed and bulk material is re-mineralized. Through the residue chlorination process, various metals including rare earths are concentrated and extracted. Energy is retained through chemical synthesis such as hydrocarbon and metal and non-metal chloride production. Produced chemicals are later exploited by redox reactions in the operation of an integrated gasification flow battery.

公开(公告)号：US20170025695A1

公开(公告)日：2017-01-26

申请号：US15103876

申请日：2016-01-18

Applicant: Justin Langley

Inventor： Justin Langley

IPC: H01M8/0612 ,  C01B3/34 ,  C10J3/84 ,  H01M8/14 ,  H01M8/0662 ,  H01M8/20 ,  H01M8/18 ,  C01B3/02 ,  B01D53/32

CPC classification number: H01M8/0618 ,  B01D47/00 ,  B01D53/326 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C01B3/348 ,  C01B2203/02 ,  C01B2203/0233 ,  C01B2203/06 ,  C01B2203/0833 ,  C01B2203/1235 ,  C01B2203/84 ,  C10G1/002 ,  C10J3/84 ,  C10J3/86 ,  C10J2200/12 ,  C10J2300/16 ,  C10J2300/1643 ,  C10J2300/1646 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  H01M8/0675 ,  H01M8/14 ,  H01M8/188 ,  H01M8/20 ,  Y02E20/18 ,  Y02E60/324 ,  Y02W30/54

Abstract: Disclosed are systems and methods having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while simultaneously enabling environmentally and sustainably sound practices. A hybrid thermochemical cycle couples staged reforming with hydrogen production and residue chlorination. The residues of the upgrading are chlorinated, metals of interest are removed and bulk material is re-mineralized. Through the residue chlorination process, various metals including rare earths are concentrated and extracted. Energy is retained through chemical synthesis such as hydrocarbon and metal and non-metal chloride production. Produced chemicals are later exploited by redox reactions in the operation of an integrated gasification flow battery.

Abstract translation: 公开的具有固有碳捕获和转换能力的系统和方法提供最大的灵活性，效率和经济性，同时实现环境和可持续的良好做法。 混合热化学循环将分级重整与氢气产生和残留氯化相结合。 升级装置的残留物被氯化，所关注的金属被去除，散装材料被重新矿化。 通过残渣氯化处理，浓缩和提取各种金属，包括稀土。 通过化学合成如碳氢化合物和金属和非金属氯化物生产来保留能量。 生产的化学品随后在一体化气化流动电池的操作中被氧化还原反应所利用。

公开(公告)号：US10988849B2

公开(公告)日：2021-04-27

申请号：US16622129

申请日：2018-06-15

Applicant: Justin Langley

Inventor： Justin Langley

IPC: C25B15/08 ,  C25B11/036 ,  B09B3/00 ,  C01B3/34 ,  C25B1/26 ,  C25B11/02 ,  C25C3/34 ,  C25C7/00 ,  C25C7/02 ,  C25B11/043 ,  C25B11/061

Abstract: The following describes a reconfigurable set of industrial processing techniques which, when appropriately combined, enable zero-emissions reforming, utilizing a wide range of conventional and unconventional feedstocks. Hydrocarbons, harvested or refuse biomass, as well as assorted byproducts and wastes are reformed through tightly integrated processing. The system is designed to incorporate alternative energy sources such as renewables or nuclear for high-density energy utilization and storage. Central to the processing methodology is a novel molten salt electrochemical reactor designed as a modular system for high-throughput carbochlorination and resource recovery. Such a configuration drastically reduces or eliminates waste while improving efficiency and realizing vast new economic incentives.

公开(公告)号：US20150047465A1

公开(公告)日：2015-02-19

申请号：US14240569

申请日：2013-08-07

Applicant: Justin Langley

Inventor： Justin Langley

IPC: C22B1/08 ,  C10L3/08 ,  C10J3/84 ,  C10J3/86 ,  C22B59/00 ,  C10G1/00

CPC classification number: H01M8/0618 ,  B01D47/00 ,  B01D53/326 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C01B3/348 ,  C01B2203/02 ,  C01B2203/0233 ,  C01B2203/06 ,  C01B2203/0833 ,  C01B2203/1235 ,  C01B2203/84 ,  C10G1/002 ,  C10J3/84 ,  C10J3/86 ,  C10J2200/12 ,  C10J2300/16 ,  C10J2300/1643 ,  C10J2300/1646 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  H01M8/0675 ,  H01M8/14 ,  H01M8/188 ,  H01M8/20 ,  Y02E20/18 ,  Y02E60/324 ,  Y02W30/54

Abstract: Method of combining industrial processes having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while enabling environmentally and sustainably sound practices. Maximum chemical energy is retained throughout feedstock processing. A hybrid thermochemical cycle couples staged reforming with hydrogen production and chlorination. Hydrogen generated is used to upgrade feedstocks including bitumen, shale, coal, and biomass. Residues of upgrading are chlorinated, metals of interest are removed, and the remainder is reacted with ammonia solution and carbon dioxide to form carbonate minerals. The combination provides emissions free production of synthetic crude oil and derivatives, as well as various metals and fertilizers. Sand and carbonate minerals are potentially the only waste streams. Through this novel processing, major carbon dioxide reduction is afforded byminimizing direct oxidation. Supplemental heat to run the reactions is obtained through external means such as concentrated solar, geothermal, or nuclear.

Abstract translation: 结合具有固有碳捕获和转换功能的工业过程的方法，提供最大的灵活性，效率和经济性，同时实现环保和可持续的良好做法。 在整个原料加工过程中保留最大的化学能。 混合热化学循环将分级重整与氢气生产和氯化相结合。 产生的氢气用于升级原料，包括沥青，页岩，煤和生物质。 升级废物被氯化，去除金属，其余的与氨溶液和二氧化碳反应形成碳酸盐矿物。 该组合提供无排放的合成原油及其衍生物以及各种金属和肥料的生产。 砂和碳酸盐矿物质潜在地是唯一的废物流。 通过这种新型处理，通过最小化直接氧化来提供主要的二氧化碳还原。 通过诸如太阳能集热，地热或核的外部手段获得运行反应的补充热量。

公开(公告)号：US10326155B2

公开(公告)日：2019-06-18

申请号：US14852028

申请日：2015-09-11

Applicant: Justin Langley

Inventor： Justin Langley

IPC: H01M8/0612 ,  C22B1/08 ,  B01D53/32 ,  C22B59/00 ,  H01M8/0662 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C10G1/00 ,  C10J3/84 ,  C10J3/86 ,  C10L3/08 ,  H01M8/14 ,  H01M8/18 ,  H01M8/20 ,  B01D47/00

Abstract: Method of combining industrial processes having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while enabling environmentally and sustainably sound practices. Maximum chemical energy is retained throughout feedstock processing. A hybrid thermochemical cycle couples staged reforming with hydrogen production and chlorination. Hydrogen generated is used to upgrade feedstocks including bitumen, shale, coal, and biomass. Residues of upgrading are chlorinated, metals of interest are removed, and the remainder is reacted with ammonia solution and carbon dioxide to form carbonate minerals. The combination provides emissions free production of synthetic crude oil and derivatives, as well as various metals and fertilizers. Sand and carbonate minerals are potentially the only waste streams. Through this novel processing, major carbon dioxide reduction is afforded by minimizing direct oxidation. Supplemental heat to run the reactions is obtained through external means such as concentrated solar, geothermal, or nuclear.

公开(公告)号：US09163297B2

公开(公告)日：2015-10-20

申请号：US14240569

申请日：2013-08-07

Applicant: Justin Langley

Inventor： Justin Langley

IPC: C22B1/08 ,  C22B59/00 ,  B01D47/00 ,  C10G1/00 ,  C10J3/84 ,  C10L3/08 ,  C01B3/00 ,  C10J3/86

CPC classification number: H01M8/0618 ,  B01D47/00 ,  B01D53/326 ,  C01B3/00 ,  C01B3/02 ,  C01B3/34 ,  C01B3/348 ,  C01B2203/02 ,  C01B2203/0233 ,  C01B2203/06 ,  C01B2203/0833 ,  C01B2203/1235 ,  C01B2203/84 ,  C10G1/002 ,  C10J3/84 ,  C10J3/86 ,  C10J2200/12 ,  C10J2300/16 ,  C10J2300/1643 ,  C10J2300/1646 ,  C10L3/08 ,  C22B1/08 ,  C22B59/00 ,  H01M8/0675 ,  H01M8/14 ,  H01M8/188 ,  H01M8/20 ,  Y02E20/18 ,  Y02E60/324 ,  Y02W30/54

Abstract: Method of combining industrial processes having inherent carbon capture and conversion capabilities offering maximum flexibility, efficiency, and economics while enabling environmentally and sustainably sound practices. Maximum chemical energy is retained throughout feedstock processing. A hybrid thermochemical cycle couples staged reforming with hydrogen production and chlorination. Hydrogen generated is used to upgrade feedstocks including bitumen, shale, coal, and biomass. Residues of upgrading are chlorinated, metals of interest are removed, and the remainder is reacted with ammonia solution and carbon dioxide to form carbonate minerals. The combination provides emissions free production of synthetic crude oil and derivatives, as well as various metals and fertilizers. Sand and carbonate minerals are potentially the only waste streams. Through this novel processing, major carbon dioxide reduction is afforded byminimizing direct oxidation. Supplemental heat to run the reactions is obtained through external means such as concentrated solar, geothermal, or nuclear.

Abstract translation: 结合具有固有碳捕获和转换功能的工业过程的方法，提供最大的灵活性，效率和经济性，同时实现环保和可持续的良好做法。 在整个原料加工过程中保留最大的化学能。 混合热化学循环将分级重整与氢气生产和氯化相结合。 产生的氢气用于升级原料，包括沥青，页岩，煤和生物质。 升级废物被氯化，去除金属，其余的与氨溶液和二氧化碳反应形成碳酸盐矿物。 该组合提供无排放的合成原油及其衍生物以及各种金属和肥料的生产。 砂和碳酸盐矿物质潜在地是唯一的废物流。 通过这种新型处理，通过最小化直接氧化来提供主要的二氧化碳还原。 通过诸如太阳能集热，地热或核的外部手段获得运行反应的补充热量。