公开(公告)号：WO2016073504A1

公开(公告)日：2016-05-12

申请号：PCT/US2015/058865

申请日：2015-11-03

Applicant: DYNETICS, INC.

Inventor： MAXWELL, James, L. ,  WEBB, Nicholas ,  HOOPER, Ryan ,  ALLEN, James

IPC: B32B5/00

CPC classification number: C23C16/483 ,  C04B35/58 ,  C04B35/58007 ,  C04B35/58028 ,  C04B35/62272 ,  C04B35/62277 ,  C04B35/62286 ,  C04B2235/5296 ,  C23C16/08 ,  C23C16/20 ,  C23C16/486 ,  C23C16/50 ,  C23C16/52 ,  D01F8/18 ,  D01F9/127 ,  D04H1/4242

Abstract: The disclosed materials, methods, and apparatus, provide novel ultra-high temperature materials (UHTM) in fibrous forms/structures; such "fibrous materials" can take various forms, such as individual filaments, short-shaped fiber, tows, ropes, wools, textiles, lattices, nano/microstructures, mesostructured materials, and sponge-like materials. At least four impmiant classes of UHTM materials are disclosed in this invention: (1) carbon, doped-carbon and carbon alloy materials, (2) materials within the boron-carbon-nitride-X system, (3) materials within the silicon-carbon-nitride-X system, and (4) highly-refractory materials within the tantalum-hafniumcarbon- nitridc-X and tantalum-hafnium-carbon-boron-nitride-X system. All of these material classes offer compounds/mixtures that melt or sublime at temperatures above 1800 degrees Celsius -and in some cases are among the highest melting point materials known (exceeding 3000 degrees Celsius). In many embodiments, the synthesis/ fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical precursor mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s).

Abstract translation: 所公开的材料，方法和装置，以纤维形式/结构提供新的超高温材料（UHTM）; 这种“纤维材料”可以采取各种形式，例如单丝，短形纤维，丝束，绳索，羊毛，纺织品，格子，纳米/微结构，介观结构材料和海绵状材料。 本发明中公开了至少四种不透明的UHTM材料：（1）碳，掺杂碳和碳合金材料，（2）硼氮化物-X系统内的材料，（3）硅 - 碳氮化物-X系统和（4）钽 - 铪碳氮化物-X和钽 - 铪 - 碳 - 氮化硼-x体系中的高耐火材料。 所有这些材料类都提供在高于1800摄氏度的温度下熔化或升华的化合物/混合物，并且在某些情况下是已知的最高熔点材料（超过3000摄氏度）。 在许多实施方案中，合成/制备来自使用一种或多种低摩尔质量前体与一种或多种高摩尔质量前体（s）的气态，固体，半固体，液体，临界和超临界前体混合物 ）。

公开(公告)号：WO2016028693A1

公开(公告)日：2016-02-25

申请号：PCT/US2015/045533

申请日：2015-08-17

Applicant: DYNETICS, INC.

Inventor： MAXWELL, James, L. ,  WEBB, Nicholas ,  ALLEN, James

IPC: C23C16/48

CPC classification number: C23C16/48 ,  C23C16/01 ,  C23C16/4411 ,  C23C16/4418 ,  C23C16/45559 ,  C23C16/45576 ,  C23C16/45591 ,  C23C16/46 ,  C23C16/483 ,  C23C16/52 ,  C23C18/00 ,  D01D5/38 ,  D01F9/08 ,  D01F9/127 ,  D01F9/133 ,  G11B9/062 ,  G11B9/063

Abstract: The disclosed methods and apparatus improve the fabrication of solid fibers and microstructures. In many embodiments, the fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s). The methods and systems generally employ the thermal diffusion/Soret effect to concentrate the low molar mass precursor at a reaction zone, where the presence of the high molar mass precursor contributes to this concentration, and may also contribute to the reaction and insulate the reaction zone, thereby achieving higher fiber growth rates and/or reduced energy/heat expenditures together with reduced homogeneous nucleation. In some embodiments, the invention also relates to the permanent or semi-permanent recording and/or reading of information on or within fabricated fibers and microstructures. In some embodiments, the invention also relates to the fabrication of certain functionally-shaped fibers and microstructures. In some embodiments, the invention may also utilize laser beam profiling to enhance fiber and microstructure fabrication.

Abstract translation: 所公开的方法和装置改善了固体纤维和微结构的制造。 在许多实施方案中，制造是使用一种或多种低摩尔质量前体与一种或多种高摩尔质量前体组合的气态，固体，半固体，液体，临界和超临界混合物。 所述方法和系统通常采用热扩散/反硝化作用将低摩尔质量前体浓缩在反应区，其中高摩尔质量前体的存在有助于该浓度，并且还可以有助于反应并使反应区隔离 ，从而实现更高的纤维生长速率和/或降低的能量/热耗支，同时减少均匀成核。 在一些实施例中，本发明还涉及在制造的纤维和微结构之上或内部的信息的永久或半永久性记录和/或读取。 在一些实施例中，本发明还涉及某些功能形状的纤维和微结构的制造。 在一些实施例中，本发明还可以利用激光束轮廓来增强纤维和微结构制造。

公开(公告)号：EP3183377A1

公开(公告)日：2017-06-28

申请号：EP15834368.1

申请日：2015-08-17

Applicant: Dynetics, Inc.

Inventor： MAXWELL, James, L. ,  WEBB, Nicholas ,  ALLEN, James

IPC: C23C16/48

CPC classification number: C23C16/48 ,  C23C16/01 ,  C23C16/4411 ,  C23C16/4418 ,  C23C16/45559 ,  C23C16/45576 ,  C23C16/45591 ,  C23C16/46 ,  C23C16/483 ,  C23C16/52 ,  C23C18/00 ,  D01D5/38 ,  D01F9/08 ,  D01F9/127 ,  D01F9/133 ,  G11B9/062 ,  G11B9/063

Abstract: The disclosed methods and apparatus improve the fabrication of solid fibers and microstructures. In many embodiments, the fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s). The methods and systems generally employ the thermal diffusion/Soret effect to concentrate the low molar mass precursor at a reaction zone, where the presence of the high molar mass precursor contributes to this concentration, and may also contribute to the reaction and insulate the reaction zone, thereby achieving higher fiber growth rates and/or reduced energy/heat expenditures together with reduced homogeneous nucleation. In some embodiments, the invention also relates to the permanent or semi-permanent recording and/or reading of information on or within fabricated fibers and microstructures. In some embodiments, the invention also relates to the fabrication of certain functionally-shaped fibers and microstructures. In some embodiments, the invention may also utilize laser beam profiling to enhance fiber and microstructure fabrication.

Abstract translation: 所公开的方法和设备改进了固体纤维和微结构的制造。 在许多实施方案中，使用一种或多种低摩尔质量前体与一种或多种高摩尔质量前体相组合来制造气体，固体，半固体，液体，关键和超临界混合物。 该方法和系统通常采用热扩散/索雷特效应将低摩尔质量前体浓缩在反应区，其中高摩尔质量前体的存在有助于该浓度，并且还可以促成反应并隔绝反应区 由此实现更高的纤维生长速率和/或降低的能量/热量消耗以及均匀成核减少。 在一些实施例中，本发明还涉及在制造的纤维和微结构上或内部的信息的永久或半永久记录和/或读取。 在一些实施例中，本发明还涉及制造某些功能形状的纤维和微结构。 在一些实施例中，本发明还可以利用激光束轮廓来增强纤维和微结构制造。

公开(公告)号：EP3215361A1

公开(公告)日：2017-09-13

申请号：EP15857529.0

申请日：2015-11-03

Applicant: Dynetics, Inc.

Inventor： MAXWELL, James, L. ,  WEBB, Nicholas ,  HOOPER, Ryan ,  ALLEN, James

IPC: B32B5/00

CPC classification number: C23C16/483 ,  C04B35/58 ,  C04B35/58007 ,  C04B35/58028 ,  C04B35/62272 ,  C04B35/62277 ,  C04B35/62286 ,  C04B2235/5296 ,  C23C16/08 ,  C23C16/20 ,  C23C16/486 ,  C23C16/50 ,  C23C16/52 ,  D01F8/18 ,  D01F9/127 ,  D04H1/4242

Abstract: The disclosed materials, methods, and apparatus, provide novel ultra-high temperature materials (UHTM) in fibrous forms/structures; such "fibrous materials" can take various forms, such as individual filaments, short-shaped fiber, tows, ropes, wools, textiles, lattices, nano/microstructures, mesostructured materials, and sponge-like materials. At least four impmiant classes of UHTM materials are disclosed in this invention: (1) carbon, doped-carbon and carbon alloy materials, (2) materials within the boron-carbon-nitride-X system, (3) materials within the silicon-carbon-nitride-X system, and (4) highly-refractory materials within the tantalum-hafniumcarbon- nitridc-X and tantalum-hafnium-carbon-boron-nitride-X system. All of these material classes offer compounds/mixtures that melt or sublime at temperatures above 1800 degrees Celsius -and in some cases are among the highest melting point materials known (exceeding 3000 degrees Celsius). In many embodiments, the synthesis/ fabrication is from gaseous, solid, semi-solid, liquid, critical, and supercritical precursor mixtures using one or more low molar mass precursor(s), in combination with one or more high molar mass precursor(s).

Abstract translation: 所公开的方法和设备改进了固体纤维和微结构的制造。 在许多实施方案中，使用一种或多种低摩尔质量前体与一种或多种高摩尔质量前体相组合来制造气体，固体，半固体，液体，关键和超临界混合物。 该方法和系统通常采用热扩散/索雷特效应将低摩尔质量前体浓缩在反应区，其中高摩尔质量前体的存在有助于该浓度，并且还可以促成反应并隔绝反应区 由此实现更高的纤维生长速率和/或降低的能量/热量消耗以及均匀成核减少。 在一些实施例中，本发明还涉及在制造的纤维和微结构上或内部的信息的永久或半永久记录和/或读取。 在一些实施例中，本发明还涉及制造某些功能形状的纤维和微结构。 在一些实施例中，本发明还可以利用激光束轮廓来增强纤维和微结构制造。