公开(公告)号：US20120262060A1

公开(公告)日：2012-10-18

申请号：US13501619

申请日：2010-10-08

Applicant: Martin Fransson

Inventor： Martin Fransson

IPC: H01J61/32

CPC classification number: H01J61/125 ,  H01J61/24 ,  H01J61/30 ,  H01J61/33 ,  H01J61/34 ,  H01J61/827

Abstract: The invention relates to a metal halogen lamp comprising an elongated arc tube enclosed in a transparent casing, wherein the arc tube is made up of a hollow glass body comprising two end portions and a middle portion, and electrode is arranged on the respective end portion, which electrodes, each having an electrode end, upon connection to a power source and during operation of the metal halogen lamp, generate an arc between them; and the glass body encloses halogens (h) and metal atoms (m) and has a wall thickness which is thicker on the end portions than on the middle portion. The thicker end portions each have a length (L1) of at least one-third of the total length (L) of the arc tube.

Abstract translation: 本发明涉及一种金属卤素灯，其包括封闭在透明壳体中的细长电弧管，其中所述电弧管由包括两个端部和中间部分的中空玻璃体组成，并且电极布置在相应的端部上， 每个具有电极端的电极在连接到电源并且在金属卤素灯的操作期间在它们之间产生电弧; 并且玻璃体包围卤素（h）和金属原子（m），并且具有在端部上比在中间部分更厚的壁厚。 较厚的端部各自具有电弧管的总长度（L）的至少三分之一的长度（L1）。

公开(公告)号：US07563742B2

公开(公告)日：2009-07-21

申请号：US11534595

申请日：2006-09-22

Applicant: Clementine Reyes ,  Martin Fransson ,  Horacio Treviño ,  Bing Zhou

Inventor： Clementine Reyes ,  Martin Fransson ,  Horacio Treviño ,  Bing Zhou

IPC: B01J23/40 ,  B01J23/74 ,  B01J21/18 ,  B01J21/00 ,  B01J23/00

CPC classification number: B01J23/755 ,  B01J21/04 ,  B01J23/883 ,  B01J35/0013 ,  B01J35/0053 ,  B01J35/006 ,  B01J35/0066 ,  B01J37/0203

Abstract: Supported nickel catalyst having high nickel loading and dispersion are manufactured using a dispersing agent. The dispersing agent molecules include at least one functional group that bonds with the nickel atoms and influences nanoparticle formation. The support material is loaded with at least about 5% nickel, more preferably at least about 8%, and most preferably at least about 12% by weight of the total catalyst. Catalysts manufactured using the organic dispersing agents and loaded with the foregoing amounts of nickel have metal dispersions greater than about 5% as measured by hydrogen adsorption, more preferably greater than about 10%, and most preferably greater than about 15%.

Abstract translation: 使用分散剂制造具有高镍负载和分散性的负载型镍催化剂。 分散剂分子包括至少一个与镍原子键合并影响纳米颗粒形成的官能团。 载体材料装载有总催化剂重量的至少约5％镍，更优选至少约8％，最优选至少约12％。 使用有机分散剂制造并加载上述量的镍的催化剂通过氢吸附测量的金属分散度大于约5％，更优选大于约10％，最优选大于约15％。

公开(公告)号：US20110095238A1

公开(公告)日：2011-04-28

申请号：US12985561

申请日：2011-01-06

Applicant: Bing Zhou ,  Cheng Zhang ,  Martin Fransson ,  Raymond B. Balée

Inventor： Bing Zhou ,  Cheng Zhang ,  Martin Fransson ,  Raymond B. Balée

IPC: H01B1/04 ,  C08K3/04 ,  C08K3/10 ,  C08K3/34 ,  C08K3/26 ,  C08K3/22 ,  C08K3/30 ,  C09K19/52 ,  B82Y30/00

CPC classification number: H01B1/24 ,  Y10S977/734 ,  Y10S977/735 ,  Y10S977/753 ,  Y10S977/773 ,  Y10S977/775 ,  Y10S977/778 ,  Y10S977/78 ,  Y10S977/783 ,  Y10S977/784 ,  Y10S977/788

Abstract: The present invention relates to novel composites that incorporate carbon nanospheres into a polymeric material. The polymeric material can be any polymer or polymerizable material compatible with graphitic materials. The carbon nanospheres are hollow, graphitic nanoparticles. The carbon nanospheres can be manufactured from a carbon precursor using templating catalytic nanoparticles. The unique size, shape, and electrical properties of the carbon nanospheres impart beneficial properties to the composites incorporating these nanomaterials.

Abstract translation: 本发明涉及将碳纳米球结合到聚合材料中的新型复合材料。 聚合物材料可以是与石墨材料相容的任何聚合物或可聚合材料。 碳纳米球是中空的石墨纳米颗粒。 碳纳米球可以使用模板催化纳米颗粒由碳前体制造。 碳纳米球的独特尺寸，形状和电学特性为纳入这些纳米材料的复合材料赋予了有利的特性。

公开(公告)号：US07758660B2

公开(公告)日：2010-07-20

申请号：US11351661

申请日：2006-02-09

Applicant: Bing Zhou ,  Zhihua Wu ,  Martin Fransson

Inventor： Bing Zhou ,  Zhihua Wu ,  Martin Fransson

IPC: B01D9/00

CPC classification number: C10L10/02 ,  B01J23/745 ,  B01J35/0013 ,  B01J35/006 ,  B01J37/08 ,  C10L1/10 ,  C10L1/1208 ,  C10L1/1233 ,  C10L1/125 ,  C10L1/1824 ,  C10L1/1826 ,  C10L1/1855 ,  C10L1/1857 ,  C10L1/1881 ,  C10L1/1883 ,  C10L1/1985 ,  C10L1/2222 ,  C10L1/2225 ,  C10L1/2406 ,  C10L1/2418 ,  C10L1/2437 ,  C10L5/361 ,  C10L9/10 ,  C10L10/04

Abstract: Organically complexed nanocatalyst compositions are applied to or mixed with a carbon-containing fuel (e.g., tobacco, coal, briquetted charcoal, biomass, or a liquid hydrocarbon like fuel oils or gasoline) in order to enhance combustion properties of the fuel. Nanocatalyst compositions can be applied to or mixed with a solid fuel substrate in order to reduce the amount of CO, hydrocarbons, and soot produced by the fuel during combustion. In addition, coal can be treated with inventive nanocatalyst compositions to reduce the amount of NOx produced during combustion (e.g., by removing coal nitrogen in a low oxygen pre-combustion zone of a low NOx burner). The nanocatalyst compositions include nanocatalyst particles made using a dispersing agent. At least a portion of the nanoparticles is crystalline with a spacing between crystal planes greater than about 0.28 nm. The nanocatalyst particles can be activated by heating to a temperature greater than about 75° C., more preferably greater than about 150° C. and most preferably greater than about 250° C.

Abstract translation: 将有机络合的纳米催化剂组合物施用于含碳燃料（例如烟草，煤，压块炭，生物质或液体烃如燃料油或汽油）或与其混合，以增强燃料的燃烧性能。 纳米催化剂组合物可以施加到固体燃料基质上或与固体燃料基质混合，以便减少在燃烧过程中由燃料产生的CO，烃和烟炱的量。 此外，煤可以用本发明的纳米催化剂组合物处理以减少在燃烧期间产生的NOx的量（例如，通过去除低NOx燃烧器的低氧预燃烧区中的煤氮）。 纳米催化剂组合物包括使用分散剂制备的纳米催化剂颗粒。 纳米颗粒的至少一部分是结晶的，晶面之间的间隔大于约0.28nm。 纳米催化剂颗粒可以通过加热至大于约75℃，更优选大于约150℃，最优选大于约250℃的温度来活化。

公开(公告)号：US20100125035A1

公开(公告)日：2010-05-20

申请号：US12693915

申请日：2010-01-26

Applicant: Cheng Zhang ,  Martin Fransson ,  Changkun Liu ,  Bing Zhou

Inventor： Cheng Zhang ,  Martin Fransson ,  Changkun Liu ,  Bing Zhou

IPC: C01B31/04 ,  B01J21/18

CPC classification number: H01M4/96 ,  B01J21/18 ,  B01J21/185 ,  B01J23/40 ,  B01J23/74 ,  B01J37/084 ,  B82Y30/00 ,  C01B32/05 ,  H01M4/9083

Abstract: Methods for manufacturing carbon nanostructures include: 1) forming a plurality of catalytic templating particles using a plurality of dispersing agent molecules; 2) forming an intermediate carbon nanostructure by polymerizing a carbon precursor in the presence of the plurality of templating nanoparticles; 3) carbonizing the intermediate carbon nanostructure to form a composite nanostructure; and 4) removing the templating nanoparticles from the composite nanostructure to yield the carbon nanostructures. The carbon nanostructures are well-suited for use as a catalyst support. The carbon nanostructures exhibit high surface area, high porosity, and high graphitization. Carbon nanostructures according to the invention can be used as a substitute for more expensive and likely more fragile carbon nanotubes.

Abstract translation: 制造碳纳米结构的方法包括：1）使用多个分散剂分子形成多个催化模板颗粒; 2）通过在多个模板纳米颗粒的存在下聚合碳前体形成中间碳纳米结构; 3）碳化中间碳纳米结构以形成复合纳米结构; 和4）从复合纳米结构中去除模板纳米颗粒以产生碳纳米结构。 碳纳米结构非常适合用作催化剂载体。 碳纳米结构表现出高的表面积，高孔隙率和高石墨化。 根据本发明的碳纳米结构可用作更昂贵且可能更脆弱的碳纳米管的替代物。

公开(公告)号：US08912720B2

公开(公告)日：2014-12-16

申请号：US13505960

申请日：2010-09-23

Applicant: Martin Fransson ,  Mikael Severinsson

Inventor： Martin Fransson ,  Mikael Severinsson

IPC: H01J17/16 ,  H01J61/30 ,  H01J61/82 ,  H01J61/34 ,  H01J61/92

CPC classification number: H01J61/92 ,  H01J61/34 ,  H01J61/827

Abstract: The present invention relates to a metal halogen lamp comprising, inside an outer casing (7), first (3) and second (5) arc tube members, which are electrically parallel-connected and are connected via conductive members (9) to a base part (11), each arc tube member having a first end (15), facing toward the top part (17) of the outer casing (7) opposite the base part (11), and a second end (19), facing toward the base part (11). The first arc tube member (3) is arranged closer to the top part (17) than the second arc tube member (5), and the second end (19) of the first arc tube member (3) and the first end (15) of the second arc tube member (5) adjoin an imaginary plane (P) defined substantially transversely to the center line (CL) of the outer casing (7), which center line extends from the top part (17) to the base part (11).

Abstract translation: 金属卤素灯技术领域本发明涉及一种金属卤素灯，其包括在外壳（7），第一（3）和第二（5）电弧管构件的内部，其电并联连接并且经由导电构件（9）连接到基座 部分（11），每个电弧管部件具有第一端部（15），该第一端部面向与所述基部部分（11）相对的所述外部壳体（7）的顶部部分（17）;以及第二端部（19） 基部（11）。 第一电弧管构件（3）布置成比第二电弧管构件（5）更靠近顶部（17），并且第一电弧管构件（3）的第二端（19）和第一端部 所述第二电弧管构件（5）的所述第二弧形管构件（5）邻接于基本上横向于所述外壳（7）的中心线（CL）限定的虚拟平面（P），所述中心线从所述顶部部分（17）延伸到所述基部 （11）。

公开(公告)号：US07718156B2

公开(公告)日：2010-05-18

申请号：US11614011

申请日：2006-12-20

Applicant: Cheng Zhang ,  Martin Fransson ,  Bing Zhou

Inventor： Cheng Zhang ,  Martin Fransson ,  Bing Zhou

IPC: C01B31/00 ,  C01B31/04 ,  C09C1/44 ,  C09C1/46 ,  B01J21/18

CPC classification number: B82Y30/00 ,  B82Y40/00 ,  C01B32/18 ,  C01B32/20 ,  C01P2002/72 ,  C01P2002/82 ,  C01P2004/03 ,  C01P2004/04 ,  C01P2004/32 ,  C01P2004/62 ,  C01P2004/64 ,  C01P2006/12 ,  C09C1/44

Abstract: Carbon nanostructures are formed from a carbon precursor and catalytic templating nanoparticles. Methods for manufacturing carbon nanostructures generally include (1) forming a precursor mixture that includes a carbon precursor and a plurality of catalytic templating particles, (2) carbonizing the precursor mixture to form an intermediate carbon material including carbon nanostructures, amorphous carbon, and catalytic metal, (3) purifying the intermediate carbon material by removing at least a portion of the amorphous carbon and optionally at least a portion of the catalytic metal, and (4) heat treating the purified intermediate carbon material and/or treating the purified intermediate carbon material with a base to remove functional groups on the surface thereof. The removal of functional groups increases the graphitic content of the carbon nanomaterial and decreases its hydrophilicity.

Abstract translation: 碳纳米结构由碳前体和催化模板纳米颗粒形成。 制造碳纳米结构的方法通常包括（1）形成包含碳前体和多个催化模板颗粒的前体混合物，（2）将前体混合物碳化以形成包括碳纳米结构，无定形碳和催化金属的中间碳材料 （3）通过除去至少一部分无定形碳和任选的至少一部分催化金属来纯化中间碳材料，和（4）对纯化的中间碳材料进行热处理和/或处理纯化的中间碳材料 具有用于除去其表面上的官能团的碱。 官能团的去除增加了碳纳米材料的石墨含量，降低了其亲水性。

公开(公告)号：US20080152576A1

公开(公告)日：2008-06-26

申请号：US11614011

申请日：2006-12-20

Applicant: Cheng Zhang ,  Martin Fransson ,  Bing Zhou

Inventor： Cheng Zhang ,  Martin Fransson ,  Bing Zhou

IPC: C09C1/44 ,  C01B31/04

CPC classification number: B82Y30/00 ,  B82Y40/00 ,  C01B32/18 ,  C01B32/20 ,  C01P2002/72 ,  C01P2002/82 ,  C01P2004/03 ,  C01P2004/04 ,  C01P2004/32 ,  C01P2004/62 ,  C01P2004/64 ,  C01P2006/12 ,  C09C1/44

Abstract: Carbon nanostructures are formed from a carbon precursor and catalytic templating nanoparticles. Methods for manufacturing carbon nanostructures generally include (1) forming a precursor mixture that includes a carbon precursor and a plurality of catalytic templating particles, (2) carbonizing the precursor mixture to form an intermediate carbon material including carbon nanostructures, amorphous carbon, and catalytic metal, (3) purifying the intermediate carbon material by removing at least a portion of the amorphous carbon and optionally at least a portion of the catalytic metal, and (4) heat treating the purified intermediate carbon material and/or treating the purified intermediate carbon material with a base to remove functional groups on the surface thereof. The removal of functional groups increases the graphitic content of the carbon nanomaterial and decreases its; hydrophilicity.

Abstract translation: 碳纳米结构由碳前体和催化模板纳米颗粒形成。 制造碳纳米结构的方法通常包括（1）形成包含碳前体和多个催化模板颗粒的前体混合物，（2）将前体混合物碳化以形成包括碳纳米结构，无定形碳和催化金属的中间碳材料 （3）通过除去至少一部分无定形碳和任选的至少一部分催化金属来纯化中间碳材料，和（4）对纯化的中间碳材料进行热处理和/或处理纯化的中间碳材料 具有用于除去其表面上的官能团的碱。 官能团的去除增加了碳纳米材料的石墨含量，降低了其碳纳米材料的石墨含量。 亲水性。

公开(公告)号：US20120280615A1

公开(公告)日：2012-11-08

申请号：US13505960

申请日：2010-09-23

Applicant: Martin Fransson ,  Mikael Severinsson

Inventor： Martin Fransson ,  Mikael Severinsson

IPC: H01J61/06

CPC classification number: H01J61/92 ,  H01J61/34 ,  H01J61/827

Abstract: The present invention relates to a metal halogen lamp comprising, inside an outer casing (7), first (3) and second (5) arc tube members, which are electrically parallel-connected and are connected via conductive members (9) to a base part (11), each arc tube member having a first end (15), facing toward the top part (17) of the outer casing (7) opposite the base part (11), and a second end (19), facing toward the base part (11). The first arc tube member (3) is arranged closer to the top part (17) than the second arc tube member (5), and the second end (19) of the first arc tube member (3) and the first end (15) of the second arc tube member (5) adjoin an imaginary plane (P) defined substantially transversely to the center line (CL) of the outer casing (7), which center line extends from the top part (17) to the base part (11).

Abstract translation: 金属卤素灯技术领域本发明涉及一种金属卤素灯，其包括在外壳（7），第一（3）和第二（5）电弧管构件的内部，其电并联连接并且经由导电构件（9）连接到基座 部分（11），每个电弧管部件具有第一端部（15），该第一端部面向与所述基部部分（11）相对的所述外部壳体（7）的顶部部分（17）;以及第二端部（19） 基部（11）。 第一电弧管构件（3）布置成比第二电弧管构件（5）更靠近顶部（17），并且第一电弧管构件（3）的第二端（19）和第一端部 所述第二电弧管构件（5）的所述第二弧形管构件（5）邻接于基本上横向于所述外壳（7）的中心线（CL）限定的虚拟平面（P），所述中心线从所述顶部部分（17）延伸到所述基部 （11）。

公开(公告)号：US07935276B2

公开(公告)日：2011-05-03

申请号：US11614006

申请日：2006-12-20

Applicant: Bing Zhou ,  Cheng Zhang ,  Martin Fransson ,  Raymond B. Balée

Inventor： Bing Zhou ,  Cheng Zhang ,  Martin Fransson ,  Raymond B. Balée

IPC: H01B1/06

CPC classification number: H01B1/24 ,  Y10S977/734 ,  Y10S977/735 ,  Y10S977/753 ,  Y10S977/773 ,  Y10S977/775 ,  Y10S977/778 ,  Y10S977/78 ,  Y10S977/783 ,  Y10S977/784 ,  Y10S977/788

Abstract: The present invention relates to novel composites that incorporate carbon nanospheres into a polymeric material. The polymeric material can be any polymer or polymerizable material compatible with graphitic materials. The carbon nanospheres are hollow, graphitic nanoparticles. The carbon nanospheres can be manufactured from a carbon precursor using templating catalytic nanoparticles. The unique size, shape, and electrical properties of the carbon nanospheres impart beneficial properties to the composites incorporating these nanomaterials.

Abstract translation: 本发明涉及将碳纳米球结合到聚合材料中的新型复合材料。 聚合物材料可以是与石墨材料相容的任何聚合物或可聚合材料。 碳纳米球是中空的石墨纳米颗粒。 碳纳米球可以使用模板催化纳米颗粒由碳前体制造。 碳纳米球的独特尺寸，形状和电学特性为纳入这些纳米材料的复合材料赋予了有利的特性。