专利汇可以提供FUEL INJECTOR HAVING AN EXTERNAL CROSS-FLOW NOZZLE FOR ENHANCED COMPRESSED NATURAL GAS JET SPRAY专利检索,专利查询,专利分析的服务。并且A compressed natural gas fuel injector including a housing, an inlet, an outlet, a seat, a closure member, and an attached nozzle. In a preferred embodiment, the inlet and outlet communicate a flow of gaseous fuel regulated by the closure member. The gaseous fuel passes through the seat, which is coupled to a rim surface of a retainer portion of the attached nozzle, and into a flow passage that further communicates the flow of gaseous fuel into one or more flow channels. The orientation of the flow channels within the attached nozzle greatly affects the discharge pattern and mixing characteristics of the gaseous fuel within an intake manifold. A method of flowing gaseous fuel through the fuel injector is also described.,下面是FUEL INJECTOR HAVING AN EXTERNAL CROSS-FLOW NOZZLE FOR ENHANCED COMPRESSED NATURAL GAS JET SPRAY专利的具体信息内容。
What is claimed is:
In the case of internal combustion engines having injection systems, fuel injectors are conventionally used to provide a precise amount of fuel needed for combustion. Compressed natural gas (hereinafter sometimes referred to as “CNG”) is a common automotive fuel for commercial fleet vehicles and residential customers. In vehicles, the CNG is delivered to the engine in precise amounts through fuel injectors, hereinafter referred to as “CNG injectors”, or simply “fuel injectors”. CNG injectors of this type are described in commonly assigned U.S. Pat. No. 5,494,224, the disclosure of which is incorporated by reference herein. Typically, the CNG injector is required to deliver the precise amount of fuel per injection pulse and maintain this accuracy over the life of the injector. In order to improve the combustion of fuel, certain strategies are required in the design of CNG injectors. These strategies are keyed to the delivery of gaseous fuel into the intake manifold of the internal combustion engine in precise amounts and flow patterns.
It is believed that some conventional CNG injector designs have failed to achieve suitable the combustion of gaseous fuel injected into the intake manifold of an internal combustion engine. Specifically, such design of CNG injectors may reduce air flow or even cause back-flow of the air-fuel mixture into the internal combustion engine's intake plenum or into other engine cylinders thereby causing engine misfire and other drivability problems.
The present invention provides improved gaseous fuel targeting and fuel distribution with an attached nozzle design for a CNG injector. Back-flow of the air-fuel mixture into the internal combustion engine's intake plenum or into other engine cylinders may be avoided by providing a discharge pattern that forms a cloud of CNG. The discharge pattern of CNG delivered to the intake manifold of the present invention is believed to improve the air-fuel mixture and drivability problems that are believed to be in the prior art.
In one aspect of the present invention, the CNG injector is provided with a housing, an inlet, an outlet, a seat, a closure member, and an attached nozzle. The inlet and outlet communicate with a flow of gaseous fuel that is regulated by the closure member disposed in at least two positions along the longitudinal axis. The seat is disposed proximate to the outlet and includes a sealing surface contiguous to a portion of the closure member in one of the two positions of the closure member and a seat orifice extending through the seat from the sealing surface along the longitudinal axis to a tapered surface that extends obliquely from the seat orifice about the longitudinal axis. Below the seat orifice, the seat is coupled to a rim surface of a retainer portion to define the beginning of a flow passage within the attached nozzle.
In a preferred aspect of the present invention, the attached nozzle includes both the retainer portion and a flow modifier portion. The retainer portion engages an outer surface of the CNG injector proximate to its outlet by employing e.g., a press-fit, snap-fit, welded, or screw-on connection. The flow modifier portion affects the flow distribution pattern of gaseous fuel through the attached nozzle. The flow modifier portion includes the flow passage and flow channel(s) of the attached nozzle. The flow channel(s) may extend along numerous axes to disperse the gaseous fuel in a particular pattern within the intake manifold.
In another aspect of the present invention, the flow channel may be disposed about an oblique axis to the longitudinal axis, and gaseous flow discharged through a singular oblique flow channel.
In yet another aspect of the present invention, a method of flowing gaseous fuel through the seat orifice, along the flow passage, and through the flow channel(s) of the attached nozzle is described. The resulting discharge pattern of the gaseous fuel improves the mixing characteristics of the gaseous fuel within the intake manifold. The method can be achieved by: flowing gaseous fuel through the seat orifice along the longitudinal axis; and dispersing the gaseous fuel into separate columns disposed either obliquely to the longitudinal axis or generally perpendicular to the longitudinal axis.
The accompanying drawings, which are incorporated herein and constitute part of this specification, illustrate presently preferred embodiments of the invention, and, together with the general description given above and the detailed description given below, serve to explain features of the invention.
A fuel filter 24 with an inlet passage 26 is disposed within the overmolded plastic member 20. The inlet passage 26 serves as part of the fuel passageway 16 of the CNG injector 10. A fuel filter retainer member 28 and an adjustable tube 30 is provided in the inlet passage 26. The preload adjustment tube 30 is positionable along the longitudinal axis 18 before being secured in place, thereby varying the length of an armature bias spring 32. In combination with other factors, the length of the spring 32, and hence the bias force against the armature, control the quantity of gaseous fuel flow through the CNG injector 10. The overmolded plastic member 20 also supports an electrical connector 20a that receives a plug (not shown) to operatively connect the CNG injector 10 to an external source of electrical potential, such as an electronic control unit ECU (not shown). An elastomeric O-ring 34 is provided in a groove on an exterior extension of the filter 24 or outlet 14. The O-ring 34 sealingly secures the filter 24 to a gaseous fuel supply member (not shown), such as a fuel rail and the outlet 14 to an intake manifold.
The coil housing 22 encloses a coil assembly 40 as shown in
The body shell 50 engages the body 52. An armature guide eyelet 56 is located on an inlet portion 60 of the body 52. An axially extending body passage 58 connects the inlet portion 60 of the body 52 with an outlet portion 62 of the body 52. The armature passage 54 of the armature 46 is in fluid communication with the body passage 58 of the body 52. A seat 64, which is preferably a metallic material, is mounted at the outlet portion 62 of the body 52.
As shown in
Operative performance of the CNG injector 10 is achieved by magnetically coupling the armature 46 to the end of the filter 26 that is closest to the inlet portion 60 of the body 52. Thus, the lower portion of the filter 26 that is proximate to the armature 46 serves as part of the magnetic circuit formed with the armature 46 and coil assembly 40. The armature 46 is guided by the armature guide eyelet 56 and is responsive to an electromagnetic force generated by the coil assembly 40 for axially reciprocating the armature 46 along the longitudinal axis 18 of the CNG injector 10. The electromagnetic force is generated by current flow from the ECU (not shown) through the coil assembly 40. Movement of the armature 46 also moves the operatively attached closure member 68. The closure member 68 opens and closes the seat orifice 76 of the seat 64 to permit or inhibit, respectively, gaseous fuel from exiting the outlet of the CNG injector 10. In order to open the seat orifice 76, the seal between the tip of closure member 68 and the seat 64 is broken by upward movement of the closure member 68. The closure member 68 moves upwards when the magnetic force is substantially higher than necessary to lift the armature closure member assembly against the force of spring 32. In order to close the seat orifice 76 of the seat 64, the magnetic coil assembly 40 is de-energized. This allows the tip of closure member 68 to re-engage surface 80 of seat 64 and close passage 76. During operation, gaseous fuel flows in fluid communication from the fuel inlet source (not shown) through the fuel inlet passage 26 of the filter 24, the armature passage 54 of the armature 46, the body passage 58 of the body 52, and the seat orifice 76 of the seat 64 and is injected from the CNG injector 10.
As shown in
The retainer portion 110 of the attached nozzle engages an outer surface 67 of the outlet 14 (shown in
A second retainer surface 113 and a third retainer surface 114 of the retainer portion 110 connect the first retainer surface 112 to the flow modifier portion 120 of the nozzle 100 as shown in
The flow modifier portion 120 affects the flow distribution pattern of gaseous fuel through the attached nozzle 100, as shown in
The first flow channel 124 is encompassed by a second modifier surface 125 and extends along a first axis 126a that is generally orthogonal to the longitudinal axis 18. The first flow channel 124 directs gaseous fuel to a first discharge outlet 127 of the attached nozzle 100 as shown in
In one preferred embodiment, a second flow channel (130 in
Gaseous fuel flows through the seat orifice 76, along the flow passage 121, and may be dispersed through one, two, three, four, or other multiple flow channel configurations of the attached nozzle 100. Thus, the resulting multiple columns of gaseous fuel are dispersed generally perpendicular to the longitudinal axis 18 of the CNG injector 10 to improve the mixing characteristics within the intake manifold (not shown). The above-mentioned singular oblique flow channel 141 delivers a single column of gaseous fuel to the intake manifold at the first angle θ with respect to the longitudinal axis 18 to that in conjunction with an intake manifold geometry, the fuel injector is able to improve its mixing characteristics with air flow in the manifold. The preferred pressure at which the CNG injector 10 operates is approximately 200 pounds per square inch gauge pressure and a pressure drop of no more than 5 pounds per square inch gauge is expected across the nozzle.
As shown in
In yet another preferred embodiment of a nozzle as shown here in
While the present invention has been disclosed with reference to certain preferred embodiments, numerous modifications, alterations, and changes to the described embodiments are possible without departing from the sphere and scope of the present invention, as defined in the appended claims. Accordingly, it is intended that the present invention not be limited to the described embodiments, but that it have the full scope defined by the language of the following claims, and equivalents thereof.
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