The present disclosure relates generally to a fuel pump assembly.
Vehicles typically include a fuel system with a fuel tank, a fuel pump that pumps fuel from the tank to a vehicle engine to support operation of the engine, and sometimes other components, such as a fuel level sensor, fuel pressure regulator, fuel injectors, fuel filter and the like. In some vehicles, the fuel pump is mounted within the vehicle fuel tank as part of a module or assembly that may include other components of the fuel system, such as the fuel level sensor and one or more fuel filters. Some modules have been mounted in the fuel tank by a mounting flange received in an opening of a fuel tank and secured to and suspended from a top wall of the fuel tank. Often, the fuel tanks are disposed in relatively small and oddly shaped areas which can lead to a wide range of shapes and sizes of fuel tanks. Some fuel tanks may have a limited depth or other constructions that make it difficult to insert a module that includes full size accessories or components into the fuel tank. Further, there is a need for improved routing of fuel within a fuel pump assembly and in and out of a fuel tank, with easy to assemble and a reduced number of components.
In at least some implementations, a fuel pump assembly includes a mounting flange, support, carrier, reservoir and fuel pump. The mounting flange has a first surface with a sealing area, a second surface opposite to the first surface, and a fluid passage extending through the mounting flange. The support is coupled to the mounting flange, and the carrier is coupled to the support with the weight of the carrier providing a compression force on the support. The reservoir is carried by at least one of the carrier and the mounting flange with the weight of the reservoir acting on the carrier and/or the mounting flange, and the reservoir defining an interior. And the fuel pump is carried by at least one of the carrier and the reservoir. The fuel pump has an inlet received within the reservoir interior and an outlet from which pressurized fuel is discharged from the fuel pump when the fuel pump is operating, wherein the support defines at least part of a passage that is communicated with a fluid source.
In at least some implementations, the reservoir is supported at least partially by the carrier and is suspended above the mounting flange.
In at least some implementations, the passage defined by the support is communicated with the fuel pump and wherein, when the fuel pump discharges pressurized fuel, at least some of the pressurized fuel flows through the support. In at least some implementations, the passage defined by the support is communicated with an outlet of a vent valve.
In at least some implementations, the support is a first support and the fluid passage is a first fluid passage, and the assembly includes a second support that is coupled to the mounting flange and to the carrier, and the mounting flange includes a second fluid passage separate from the first fluid passage, and the second support defines a passage that is communicated with the second fluid passage.
In at least some implementations, the carrier includes a passage communicated with the fuel pump and with a secondary fuel pump to provide fuel from the fuel pump to the secondary fuel pump. The secondary fuel pump may include a nozzle, a venturi and an inlet and fuel flow through the nozzle and venturi draws fuel through the inlet of the secondary fuel pump. The inlet of the secondary fuel pump may be communicated with a fuel passage having an end spaced from the inlet of the secondary fuel pump so that fuel remote from the secondary fuel pump inlet may be drawn into the secondary fuel pump inlet.
In at least some implementations, the carrier includes a passage communicated with the fuel pump and with a pressure regulator to provide fuel from the fuel pump to the pressure regulator.
In at least some implementations, the mounting flange includes a first coupling feature to which the support is coupled, and the carrier includes a second coupling feature to which the support is coupled, and wherein the first coupling feature and second coupling feature both include openings communicated with the passage defined by the support.
In at least some implementations, a fuel control valve is carried by the carrier and a secondary fuel pump carried by the carrier.
In at least some implementations, the reservoir has a lower wall and a sidewall extending vertically from the lower wall to retain fuel in the reservoir, and the carrier is coupled to or arranged adjacent to an upper end of the sidewall. The lower wall of the reservoir may be supported on the mounting flange. The lower wall of the reservoir may be spaced from the mounting flange. The lower wall may be defined by the mounting flange.
In at least some implementations, an assembly for a fuel system, includes a fuel tank, a mounting flange, a support, a carrier, a reservoir and a fuel pump. The fuel tank has a lower wall that defines part of an interior in which fuel is received, and fuel is received on the lower wall under the force of gravity. The mounting flange is secured to the lower wall, and has a first surface with a sealing area and a fluid passage extending through the mounting flange. The support is coupled to the mounting flange. The carrier is coupled to the support and suspended above the flange at least in part by the support. The reservoir is carried by at least one of the carrier and the mounting flange, and the reservoir defining an interior. And the fuel pump is carried by at least one of the carrier and the reservoir, has an inlet received within the reservoir interior and an outlet from which pressurized fuel is discharged from the fuel pump when the fuel pump is operating. The support defines a passage that is communicated with a fluid source and permitting fluid flow through the support.
In at least some implementations, the carrier includes a carrier passage communicating with a component including the fuel pump, a secondary fuel pump or a vent valve, and in operation of the assembly fluid flows through the carrier passage to an inlet of the component or fluid flows through the carrier passage from an outlet of the component.
In at least some implementations, the carrier passage is communicated with the passage defined by the support. The fluid passage in the mounting flange, the carrier passage and the passage defined by the support may all define part of the same fluid flow path.
In at least some implementations, the mounting flange and/or carrier may be used with different size reservoirs. Other components, like one or more of a filter, pressure regulator, fuel pump, secondary pump, vent and the like may be the same as well, to enable efficient provision of a range of fuel pump assemblies having different reservoir capacities or other characteristics. The assembly may be mounted to a bottom or lower wall of a fuel tank and extend upwardly into an interior of the fuel tank. The mounting flange, supports and carrier may have openings or passages therethrough for fluid flow into and out of the fuel tank, and between and among the various components of the fuel pump assembly. Of course, other arrangements and assemblies will be known from the teachings and disclosure provided herein, with respect to various disclosed implementations which include and are representative of various innovations.
The following detailed description of certain embodiments and best mode will be set forth with reference to the accompanying drawings, in which:
Referring in more detail to the drawings,
The fuel pump assembly 10 includes a body assembly 16 that may have a mounting flange 18, a carrier 20 and a reservoir 22. The mounting flange 18 is arranged to be fixed and sealed to a wall 24 of the fuel tank, which may be a lower or bottom wall on which fuel is received under the force of gravity (that is, the lower or bottom wall is relative to the direction of gravity). The wall 24 may be continuous with the lower or bottom defined by a part of the wall 24 that is lowest relative to gravity in the installed position of the tank 12. The wall 24 may define at least part of the interior 11 in which fuel is maintained. The tank wall 24 may include an opening 25 through which part of the fuel pump assembly 10 is inserted with, in at least some implementations, at least part of the flange 18 outboard of the tank interior 11 and overlying part of the tank wall 24. The mounting flange 18 may be molded of a polymeric material suitable for use with a polymeric fuel tank 12, and to be sealed to the fuel tank wall 24, or the flange 18 may be formed from metal or any other suitable material. The mounting flange 18 may have a radially outwardly extending lip 26 adapted to overlie and be sealed to the lower fuel tank wall 24 surrounding the opening 25, such as at or to an outer surface 28 of the wall.
As shown in
To permit fluid flow through the flange 18, the flange may include one or more fluid fittings that define passages through the flange and facilitate connecting conduits thereto so that fuel may be routed in the fuel system as desired. As shown in
As shown in at least
The carrier 20 may be coupled to the flange 18 by one or more supports 54. As shown in
In at least some implementations, the supports 54 may be coupled to the flange 18 and carrier 20 without any additional fasteners, to facilitate assembly and reduce complexity and cost of the fuel pump assembly 10. For example, where the coupling features 48, 56 include protrusions, the supports 54 may include cavities or passages sized to be press-fit over or onto the protrusions. And where the coupling features 48, 56 includes a cavity (e.g. a blind bore), the supports 54 may be pressed or otherwise received in the cavity. In some implementations, the first or second coupling features 48, 56 may be defined by a cylindrical and tubular wall having an axis, and the associated support 54 may be pressed into the cavity defined within the wall, or over the exterior surface of the wall, such that the wall is received within the support. The support(s) 54 may be separate from the flange 18 and/or carrier 20, or at least one support 54 may be formed integrally with either the carrier 20 or the flange 18, if desired. The connection between the mated components 48, 54, 56 may be maintained with an interference or friction fit to inhibit unintended separation of the components, if desired. Adhesives, threads, welds, clamps, snap/locking features or other modes of connection may be used to maintain the connection between the components, but are not needed in all implementations.
At least one of the second coupling features 56 may be aligned with or define at least part of an opening or passage 58 (shown, for example, in
The carrier 20 may include a base 60 that generally overlies at least part of an upper end 62 or rim of the reservoir 22, and from which other components or features of the carrier 20 may extend. The other features include sockets, recesses, fittings or projections that receive or mount components like a secondary fuel pump 64 (
The first carrier fitting 70, which receives the outlet 72 of the fuel pump 14, defines part of a passage 79 (
The passage 79 in the carrier 20 may also communicate with the fuel pressure regulator 66 or other fluid flow control valve. As shown in
As shown in
The third carrier fitting 78 may be coupled to another fuel system component, and is shown as being communicated with an outlet 109 of the vent valve 46 via a connecting tube 110. The vent valve 46 may have a body 111 with an inlet 112 located generally adjacent to an upper wall or upper portion of fuel tank wall 24 so that the inlet 112 is communicated with gaseous fluid above the level of fuel in the fuel tank interior 11. The vent valve body 111 may be coupled to the fuel tank wall 24, or it may be held in an upper portion of the fuel tank interior 11 (where upper relates to the direction of gravity) by the tube 110, or by a support or bracket of the carrier 20, as desired. The support or bracket of the carrier 20 may be integrally formed in the same piece of material as other portions of the carrier 20, or may be separate and attached of the carrier 20, as desired. The vent valve 46 may be of conventional construction, and may have a valve (not shown) that closes when acted upon by liquid fuel to prevent fuel from flowing through the outlet 109 and tube 110, even in the event of an inversion of the fuel tank 12. When the valve is open, gaseous matter (e.g. fuel vapor and air) may flow into the vent valve inlet 112, through the valve, out of the vent valve outlet 109, through the tube 110, carrier opening 58, support 54 and through the second fitting 42 in the flange. In this way, the fuel tank interior may be vented while liquid fuel is inhibited or prevented from flowing out of the tank through this flow path.
As noted above, the reservoir 22 defines at least part of an interior space 114 in which a supply of liquid fuel is retained. The reservoir 22 may be generally cup-shaped with a sidewall 116 extending vertically from a generally horizontally arranged lower wall 118 which may be integrally formed in the same piece of material, if desired. The other or upper end 62 of the reservoir 22, opposite to the lower wall 118, may be open, and the carrier 20 may be coupled to or arranged adjacent to the upper end 62 of the reservoir 22. In at least some implementations, the reservoir 22 may be open at both ends, that is, may comprise only the sidewall 116, the sidewall 116 may be coupled to the flange 18, and the interior 114 may be defined partially by the flange 18. The reservoir 22 may include a seat 119 (
In at least some implementations, to maximize the internal volume of the reservoir 22 while still permitting the reservoir 22 and remainder of the fuel pump assembly (other than at least a portion of the flange 18) to be received through the opening 25 in the fuel tank wall 24, the reservoir 22 may include recesses 122 (
At least part of the fuel level sender 36 may be coupled directly to the exterior 114 of the reservoir 22, and/or carrier 20 and/or mounting flange 18. The fuel level sender 36 may likewise be arranged for receipt within the fuel tank opening 25 in which the reservoir 22 is received. The fuel level sender 36 may include a float 130 coupled to an arm 132 that is also coupled to a sensor assembly 134. As the level of fuel in the fuel tank 12 changes, the float 130 moves (the float is buoyant in fuel and thus, remains on the surface of the fuel in the tank). Movement of the float 130 causes the arm 132 to move and movement of the arm 132 is sensed by the sensor assembly 134 with provides a signal indicative of the fuel level in the tank, in a known manner. The sensor assembly 134 may be coupled to the reservoir 22, and may also be located within the minimum diameter of the mounting flange 18 sealing area. In at least some implementations, the reservoir sidewall 116 includes a portion closer to the center/axis 126 and the fuel lever sender 36 is coupled to that portion of the sidewall 116. In at least some implementations, part of the arm 132 and float 130 may be located outboard of that minimum diameter in some positions of the arm 132 and within the minimum diameter in other positions of the arm 132. In the example shown, when the arm 132 is positioned so that the float 130 is farther from the mounting flange 18, the float 130 and arm 132 may be within the minimum diameter of the sealing area 128 for easy receipt of the fuel pump assembly 10 through the fuel tank opening 25.
The jet pump intake tube 104 may extend outward of the minimum sealing area of the mounting flange 18 so that a free end 136 of the tube 104 is spaced from the reservoir 22, as noted above. The tube 104 may be flexible so that it may be bent or flexed during installation of the fuel pump assembly 10 into the fuel tank 12 and received through the tank opening 25. And the tube 104 may be resilient so that the tube returns to or toward its unflexed position when received in the fuel tank to permit the free end to again be spaced from the reservoir 22 as desired.
Likewise, the vent valve 46 may be received within the minimum diameter of the sealing area, directly above (relative to the direction of gravity) the area circumscribed by the sealing area. Or the tube 110 coupled to the vent valve outlet 109 may be flexible to facilitate movement of the vent valve 46 relative to the flange 18 and receipt of the vent valve 46 into the tank opening 25 during installation of the fuel pump assembly 10.
The fuel pump 14 may be supported by the carrier 20 and/or the reservoir 22 and/or the flange 18, or any combination of these components. In the example shown, at least part of the fuel pump 14, including an inlet of the fuel pump, is received within the interior 114 of the reservoir 22 so that the fuel pump 14 can draw in fuel from the interior of the reservoir 22. The fuel pump 14 may extend through an opening 138 (
In at least some implementations, the reservoir 22 may be coupled to the carrier 20 and/or one or more supports 54. In the example shown in
In at least some implementations, fuel not consumed by an engine may be routed back to the fuel tank 12 via a fuel return conduit (shown at 146 in phantom, in
The forms of the invention herein disclosed constitute presently preferred embodiments and many other forms and embodiments are possible. It is not intended herein to mention all the possible equivalent forms or ramifications of the invention. It is understood that the terms used herein are merely descriptive, rather than limiting, and that various changes may be made without departing from the spirit or scope of the invention.
This application claims the benefit of U.S. Provisional Application Ser. No. 62/846,004 filed on May 10, 2019, the entire contents of which is incorporated herein by reference in its entirety
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Number | Date | Country | |
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Number | Date | Country | |
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62846004 | May 2019 | US |