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    • 6. 发明授权
    • Combustion control via homogeneous combustion radical ignition (HCRI) or partial HCRI in cyclic IC engines
    • 通过均质燃烧自发点火(HCRI)或循环IC发动机的部分HCRI进行燃烧控制
    • US07493886B2
    • 2009-02-24
    • US11695797
    • 2007-04-03
    • David Alan Blank
    • David Alan Blank
    • F02B19/08F02B19/10F02B19/14F02B19/18F02M25/07
    • F02D19/0655F01C1/22F02B11/00F02B19/02F02B19/1095F02B19/12F02B19/165F02B19/18F02B23/06F02D19/0644F02D19/0689F02D19/0692F02D19/081F02D37/02F02D41/0027F02D41/3041F02D41/3094F02D2041/389F02M25/0228Y02T10/12Y02T10/125Y02T10/128Y02T10/17Y02T10/36
    • A process is provided for enhancing homogeneous combustion and improving ignition in rotary and reciprocating piston IC engines. Physical embodiments supporting this process have secondary chambers embedded in the cylinder periphery to initiate radical ignition (“RI”) species generation in an earlier cycle for use in the main chamber combustion of a later cycle. These communicate with the main chamber via small conduits. Coordinated with the progressions facilitated by these secondary chambers are novel control measures for regulating the quantities of RI species ultimately generated for and conveyed to the later cycle. The pre-determinable presence of RI species so supplied then alters or adds controlled variety to the dominant chain-initiation reactions of the main combustion ignition mechanism of the later cycle. This presence does so by lowering both the heat and the fuel ratios required for starting and sustaining combustion. While this presence dominates in RI mode embodiments, this presence can also assist ignition and combustion in embodiments that are instead dominated by the spark ignition (“SI”) and compression ignition (“CI”) modes. The process results in improved combustion with increased efficiencies, decreased emissions and a wider range of fuel tolerances.
    • 提供了一种用于增强旋转和往复活塞式IC发动机的均匀燃烧和改善点火的方法。 支撑该方法的物理实施例具有嵌入在圆筒周边中的次级室,以在较早循环中产生用于主室燃烧的较早循环的自由基点燃(“RI”)物质。 这些通过小导管与主室连通。 与这些次级室促进的进展协调是一种新的控制措施,用于调节最终生成并传送到后期循环的RI物质的数量。 如此提供的RI物质的预先确定的存在可以改变或添加受控的品种到后期循环的主燃烧点火机构的主要起始反应。 这种存在通过降低启动和维持燃烧所需的热量和燃料比来实现。 虽然这种存在主导于RI模式实施例,但是这种存在还可以在由火花点火(“SI”)和压缩点火(“CI”)模式主导的实施例中辅助点火和燃烧。 该过程导致燃烧效率提高,排放减少和燃料容差范围更广。
    • 7. 发明授权
    • Turbocharging and precombustion chamber spark plug internal combustion engine, ignition method and application
    • 涡轮增压和预燃室火花塞内燃机,点火方式及应用
    • US07243634B2
    • 2007-07-17
    • US10531731
    • 2003-10-17
    • Nicolas TourteauxCyril Robinet
    • Nicolas TourteauxCyril Robinet
    • F02B19/14
    • F02B17/005F02B19/12Y02T10/125
    • The invention concerns an internal combustion engine with at least one engine member, the engine member including a combustion chamber (4) of a combustible mixture with fuel components and oxidants, an ignition system of the combustible mixture by an igniter (7), sequential let-through devices for the fuel and oxidant components and for the combustion products, the engine being of the supercharging type by boost pressure of the oxidant components upstream of the engine member. According to the invention, the ignition system includes a closed head (6) (12a) substantially spherical enclosing the igniter in a precombustion chamber, the head including a set of orifices (5) intended to communicate the combustion chamber and the precombustion chamber so that combustible mixture may flow into the precombustion chamber. In a variation of the invention, at least one of the let-through devices is a direct injector in the combustion chamber for, in all or in part, the fuel components and/or fuels. A method and an application are also described.
    • 本发明涉及具有至少一个发动机构件的内燃机,所述发动机构件包括具有燃料成分和氧化剂的可燃混合物的燃烧室(4),通过点火器(7)的可燃混合物的点火系统,顺序让 通过用于燃料和氧化剂组分以及燃烧产物的装置,通过发动机构件上游的氧化剂组分的增压压力,发动机是增压型。 根据本发明,点火系统包括封闭的头部(6)(12a),其基本上是球形的,将点火器包围在预燃室中,该头部包括一组旨在使燃烧室和预燃室连通的孔口(5), 该可燃混合物可能流入预燃室。 在本发明的变型中,至少一个通过装置是燃烧室中的直​​接喷射器,用于全部或部分燃料部件和/或燃料。 还描述了一种方法和应用。
    • 10. 发明授权
    • Combustion chamber structure of a gas engine
    • 燃气发动机的燃烧室结构
    • US6073604A
    • 2000-06-13
    • US135801
    • 1998-08-18
    • Kenro Nakashima
    • Kenro Nakashima
    • F02B19/02F02B19/14F02B19/16F02B19/18F02B43/00F02D19/02F02D41/38F02M21/02
    • F02B19/165F02B19/02F02B19/18Y02T10/125
    • In the combustion chamber structure of the gas engine the combustion chamber members are formed with the sub-communication holes allowing communication between the main combustion chambers and the pre-combustion chambers and also with throat holes in which throat hole valves are installed. This structure avoids excessively high compressed air pressure in the main combustion chambers during the compression stroke and reduces the compression work to improve performance. The sub-communication holes open at the wall surfaces situated in the main combustion chambers and also at the upper wall surfaces of the pre-combustion chambers. The axes of the ports of the sub-communication holes opening to the main combustion chambers extend toward the center axes of the throat holes. The axes of the ports of the sub-communication holes opening to the pre-combustion chambers extend offset from the center axes of the pre-combustion chambers. Hence, this gas engine can reduce the compression work, lower the maximum pressure of the compressed air at the end of the compression stroke, prevent the gas fuel from remaining in the pre-combustion chambers, and enhance the air utilization factor, improving thermal coefficient.
    • 在燃气发动机的燃烧室结构中,燃烧室部件形成有允许主燃烧室和预燃烧室之间连通的副连通孔,并且还具有安装有喉孔阀的喉孔。 这种结构避免了在压缩冲程期间主燃烧室中的过高的压缩空气压力,并且减小了压缩工作以提高性能。 子连通孔在位于主燃烧室中的壁表面以及在预燃烧室的上壁表面处打开。 通向主燃烧室的副连通孔的端口的轴线朝向喉孔的中心轴线延伸。 通向预燃室的子连通孔的端口的轴线偏离预燃烧室的中心轴线。 因此,该气体发动机可以减小压缩作用,降低压缩冲程结束时的压缩空气的最大压力,防止气体燃料残留在预燃烧室中,提高空气利用系数,提高热系数 。