This application claims benefit of priority to Provisional Patent Application No. 61/435,302 filed on Jan. 22, 2011, the entire contents of this application being hereby incorporated by reference.
The invention relates to a high pressure fuel system, and more particularly, to a system including a high pressure fuel rail.
High pressure fuel delivery systems utilize a common rail (also known as a high pressure fuel rail, common rail, or accumulator) to accumulate and distribute fuel to fuel injectors at high-pressure while minimizing pressure fluctuations among the injectors. The high pressure fuel rail can be a single tube-like structure from which fuel is supplied to multiple injectors and functions as an accumulator to allow for precise control of high-pressure injection of fuel by an engine control unit (ECU) into the cylinders of an internal combustion engine at timing that is independent from the engine speed. Such high pressure fuel delivery systems, however, are susceptible to leakage from the high pressure fuel line or elsewhere in the delivery system. If fuel leakage occurs, the leaking fuel can spray onto high temperature surfaces of an engine and cause a fire. To safely deliver fuel in high pressure systems, modern fuel systems include measures to contain fuel leaks that may occur. For example, marine agency requirements such as the International Convention for the Safety of Life at Sea (SOLAS) treaty require double-walled fuel lines to prevent the likelihood of fire on a commercial marine vessel. These double-walled fuel lines must include a gap between the inner and outer walls to allow any fuel leaked from the inner wall to be detected by a fuel sensor while being contained by the outer wall.
The present disclosure provides an enclosure or containment assembly adapted to seal a high pressure fuel rail, and an engine system including such an enclosure or containment assembly. The assembly includes two portions that can sealingly engage to form an enclosure or compartment that contains the high pressure fuel rail. Fuel line connectors leading into the enclosure to ports of the high pressure fuel rail are in a sealing engagement with the enclosure to seal the high pressure fuel rail from the atmosphere and provide an enclosed low pressure region between the high pressure fuel rail and an inner surface of the enclosure. In this way, leaked fuel can be collected, contained and detected. The leaked fuel can be channeled to a leak detector, which can trigger an alarm with detection of a leak. The enclosure or compartment can be integrated with fuel lines and fuel line connectors that include low pressure passages for returning leaked fuel along with high pressure passages for providing fuel to an upstream location, such as a fuel injector. The low pressure region of the enclosure can link with low pressure passages of the fuel lines to complete a low pressure circuit for the collection and detection of leaking fuel.
In one aspect of the disclosure, a containment assembly for a high pressure fuel system includes a first elongated portion having a first opening and adapted to receive a high pressure fuel rail having an elongated body, an inlet port, plural outlet ports, and a connecting member extending from the elongated body. The first elongated portion includes a fastener portion configured to secure the connecting member of the high pressure fuel rail within the opening of the first elongated portion, a fuel inlet port adapted to sealingly engage a high pressure fuel line connector that connects to the inlet the high pressure fuel rail, and a leaked fuel drain port adapted connect to a low pressure fuel leakage drain line upstream of a leak detector. The containment assembly includes a second portion adapted to cover and seal the first opening to form an enclosed compartment including a low pressure region between the high pressure fuel rail and inner surfaces of the compartment. The second portion includes plural ports, each of which is adapted to sealingly engage a respective high pressure fuel line connector including a high pressure fuel line and a low pressure passage, and to align with a high pressure outlet port of the high pressure fuel rail. With the plural fuel line connectors sealingly engaged with the respective plural ports, each low pressure passage of the high pressure fuel line connectors fluidly communicates with the enclosed low pressure region.
In another aspect of the disclosure, an engine system includes an internal combustion engine including plural cylinders and an intake manifold, a fuel system including a high pressure fuel rail having an inlet port and plural outlet ports, plural fuel injectors, where each of the injectors is adapted to inject fuel at high pressure into one of the cylinders, a high pressure fuel inlet line fluidly connected to the inlet port of the fuel rail, and plural high pressure fuel outlet lines. Each of the high pressure fuel outlet line is fluidly connected at a first end thereof to one of the fuel injectors and fluidly connected at a second end thereof to one of the outlet ports of the fuel rail. An enclosure housing the fuel rail includes a first elongated portion having an opening is provided along a direction of a longitudinal axis of the first elongated portion, a first surface surrounding the opening, a region recessed from the first surface, a second elongated portion having a second surface that sealingly engages with the first surface to cover and seal the opening, plural ports provided through the enclosure, each of the plural ports aligned with a corresponding one of the inlet port and the plural outlet ports of the enclosed high pressure fuel rail, and a leaked fuel drain port fluidly connected to a low pressure fuel leakage drain line. A leak detector fluidly is connected to the low pressure fuel leakage drain line downstream from the enclosure housing and is adapted to detect whether fuel is present in the low pressure fuel leakage drain line. Each of the high pressure fuel outlet lines and the high pressure fuel inlet lines include a connector at one end, a high pressure fuel passage, and a corresponding low pressure leaked fuel passage, and each of the connectors is sealingly engaged with the one of the plural ports of the enclosure to form a low pressure region in the enclosure substantially surrounding the high pressure fuel rail.
Various aspects are described hereafter in connection with exemplary embodiments to facilitate an understanding of the disclosure. However, the disclosure is not limited to these embodiments. Descriptions and depictions of well-known functions and constructions may not be provided for clarity and conciseness.
Embodiments are described herein using terms such as “upper” and “lower” when describing an orientation of the embodiment depicted in the figures. However, it is to be understood that such orientation language is utilized to describe specific exemplary embodiments, and that other embodiments consistent with the present disclosure are not limited to these depicted and described orientations. Further, the terms “high pressure” and “low pressure” are used herein as relative terms with respect to one another.
The inventors realized that to control fuel leakage when it does occur, a low pressure containment system in the form of a shroud (i.e., encapsulating) assembly can be used to form a cavity or enclosure into which the high pressure fuel accumulator (fuel rail) can be provided to channel leaking fuel to a containment tank or to return the leaking fuel to the fuel tank or the fuel pump. As described later in greater detail by way of exemplary embodiments, the encapsulating assembly encloses the high pressure fuel rail and seals the fuel rail completely, and also seals high pressure line connectors fluidly connected to the fuel rail.
In operation, the engine system 1 draws fuel from a fuel tank or reservoir (not shown) through a low pressure fuel line 3a. The fuel output from the LP pump 4 can be passed through a filter (not shown) before being provided to the HP fuel pump 5. The HP pump 5 receives the fuel at low pressure and provides fuel at high pressure to the HP rail 12 via a high pressure fuel line segment 6. The HP rail 12 provides fuel at a substantially equalized high pressure to each of the high pressure fuel lines 8 that are fluidly connected to a respective fuel injector. While six high pressure lines 8, respective injectors 7, and engine cylinders are shown in the exemplary engine system 1, other applications can include more or less high pressure lines 8 and corresponding injectors 7 and engine cylinders.
The high pressure fuel lines 6 and/or 8 connected to the fuel rail 12 of the high pressure fuel rail encapsulating assembly 10 can have a double (dual) wall configuration, such as described in U.S. application Ser. No. 13/103,066, where leaked fuel from a high pressure line is contained in a low pressure passage between an outer and inner wall of the double walled fuel line structure. Fuel leaking from fuel lines (e.g., fuel leaking from joints (interfaces) and high pressure fuel line ruptures) on the injector side of the fuel rail can be directed into the low pressure region 14 of the encapsulating assembly 10 and thereafter directed to another destination, such as a detection device. In an embodiment, for example, leaked fuel can be directed from the high pressure fuel rail encapsulating assembly 10 by low pressure fuel line fluidly connected to the enclosed space of the low pressure region 14 and then directed to the fuel pump, and from the pump fed to a separate detection system or device (e.g., a leak detection tank). The detection system or device senses the leakage and activates or triggers an alarm mechanism via the controller 100, such as indication on a display, an audible alarm, ODB code, and/or another alarm indication. In an embodiment, leaked fuel from the injector side high pressure connector can be brought into the enclosure portion 11 by way of a double wall fuel line and the same fuel can be directed to the fuel pump by another double wall fuel line, and from the fuel pump it is separated from the main fuel circuit and fed to a leak detection system. The lead detection system senses the leaked fuel and triggers the alarm.
The fuel rail 12 can be essentially of known design having an elongated tubular shaped body and include a high pressure inlet port 16 configured to attach a high pressure supply line 6 from a high pressure pump 5 (see
With reference to
Each high pressure fuel line connector 34 can form a seal with the upper portion 13a of the encapsulation assembly 10 by inserting the fuel line connector 34 through a respective cylindrical opening, or port 35 provided in the upper portion 13a and screwing a threaded inner surface 36 of the fuel line connector 34 to a threaded surface of the high pressure fuel rail outlet port 18. As the high pressure fuel line connector 34 is screwed onto the high pressure fuel rail outlet port 18, a collar 42 that supports the high pressure inner tube 37 is urged downward direction in the figure such that a mating surface of the high pressure fuel rail outlet port 18 is pressed into sealing engagement with a surface of the inner high pressure fuel line 37 of the fuel line 8, which is shown in the exemplary embodiment as having a conical cross section. An O-ring 38 forms a seal between the cylindrical opening 35 and the fuel line connector 34 for sealing of the low pressure region 14 including the annular gap and one or more low pressure passage in each fuel line 8.
As shown in
Referring now to
Returning to
To allow for efficient spatial packing on an engine, some embodiments can integrate the high pressure fuel rail encapsulation assembly 10 with other engine system components, such as an intake manifold, although such integration of the upper portion 13a and lower portion 13b of the encapsulation assembly 10 is not necessary. For instance,
The connector 52 of the high pressure supply line 6 can include an O-ring sealing assembly similar to the fuel line connector 34 to provide seal from the atmosphere along the sidewalls the opening 53 in the lower portion 13b. Any other high pressure fuel line including high pressure fuel passage surrounded by a low pressure region can connect to a port on the fuel rail 12 utilizing a similar configuration such that a network of low pressure regions including the low pressure region 14 are fluidly connected and include essentially the entire high pressure fuel system.
Thus, a fuel leak that may develop in the high pressure fuel line would be contained in the passage of the low pressure region 40 and in the low pressure region 14 to provide a fluid path that is sealed from the atmosphere such that leaked fuel can be collected in an enclosure provided by the high pressure fuel rail encapsulation assembly 10. Collected leaked fuel is thereafter directed to the low pressure leak drain line 3c, which fluidly connects at one end thereof to the encapsulating assembly 10 utilizing a banjo style connector 60 (see
The attaching members 22 of the high pressure fuel rail 12 are secured to threaded holes in lands 123 provided in the lower portion 113b. The lands 123 are recessed from an upper surface 125 of the lower portion 113b to at least an extent necessary for the fuel rail 12 not to interfere with the upper portion 113a. The O-ring of each of the high pressure fuel line connectors 34 seals against a respective sleeve element 135. Each sleeve element 135 is inserted into a respective opening 136 provided in the upper portion 113a with a gasket 137 therebetween to form a port above a respective high pressure outlet port 18. Similarly, sleeve elements 153 and 154 are provided in openings in a side surface of the lower portion 113b to form ports that are respectively aligned with the high pressure inlet port 16 and the rail drain outlet port 20 of the fuel rail 12, and receive the respective high pressure drain line 21 and high pressure fuel line 6.
As described above, the embodiment shown in
Embodiments consistent with the disclosure provide a low pressure enclosure that encloses the high pressure fuel rail entirely, and can serve as a reservoir for collecting fuel leaking from the high pressure fuel lines and fuel line connector interfaces (e.g., leakages at the joints or as a result of line ruptures) and comply with current and future governmental marine agency mandates related to fuel containment.
Although a limited number of embodiments is described herein, one of ordinary skill in the art will readily recognize that there could be variations to any of these embodiments and those variations would be within the scope of the disclosure.
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Number | Date | Country | |
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Number | Date | Country | |
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61435302 | Jan 2011 | US |