The present disclosure relates generally to common rail fuel injection systems for engines for machines and vehicles and, more particularly, to an accumulator assembly having a centering mechanism aligning an accumulator body within a bore of a cylinder head and allowing flow of cooling fluid past the centering mechanism.
Common rail direct fuel injection is a direct fuel injection system for gasoline and diesel engines in various applications, such as in providing power to machines and vehicle. In diesel engines for example, a common rail fuel injection system may feature a high-pressure fuel rail having a plurality of fuel lines each feeding an individual accumulator assembly with a valve to provide the high-pressure fuel to a corresponding fuel injector for one of the combustion cylinders of the engine.
The cylinder head 14 shown in cross-section includes an accumulator bore surface 40 defining an accumulator bore 42 extending inwardly into the cylinder head 14 from an accumulator bore opening 44 in a cylinder head outer surface 46. The accumulator bore 42 has a shape that is complimentary to a shape of the accumulator body 16 with a series of bore sections 48, 50, 52, 54 corresponding to the body sections 26, 28, 30, 32, respectively, and having an accumulator bore inner diameter that increases relative to an accumulator bore longitudinal axis 56. The cylinder head 14 may further include a drain passage 58 connecting a drain port 60 of the cylinder head 14 to the accumulator bore 42. The accumulator bore surface 40 intersects a fuel injector bore surface 62 defining a fuel injector bore 64 extending inwardly into the cylinder head 14 from an injector bore opening 66 in the cylinder head outer surface 46 at a bore intersection area 68.
The accumulator body 16 is inserted into the accumulator bore 42 until the injector interface end 34 reaches the bore intersection area 68 (
In one aspect of the present disclosure, an accumulator body for an accumulator assembly in an engine assembly of a machine is disclosed. The engine assembly further includes a fuel injector having a high pressure fluid inlet port, and a cylinder head having a fuel injector bore surface defining a fuel injector bore in which the fuel injector is disposed, and an accumulator bore surface defining an accumulator bore having an accumulator bore inner diameter and an accumulator bore longitudinal axis and intersecting the fuel injector bore at a bore intersection area at which the high pressure fluid inlet port is aligned. The accumulator body includes an injector interface end dimensioned to be received by the high pressure fluid inlet port of the fuel injector, and an accumulator body outer surface having a shape that is complimentary to the accumulator bore surface, an accumulator body longitudinal axis and an accumulator body outer diameter that is less than the accumulator bore inner diameter so that the accumulator bore surface and the accumulator body outer surface define an annular gap there between when the accumulator body is disposed within the accumulator bore and the accumulator body longitudinal axis is aligned coincident with the accumulator bore longitudinal axis. The accumulator body further includes an alignment groove surface defining an alignment groove in the accumulator body outer surface having an alignment groove depth that is radially inward from the accumulator body outer surface and an alignment groove longitudinal width, and a first fluid flow channel surface defining a first fluid flow channel in the accumulator body that is disposed at the alignment groove. The first fluid flow channel has a fluid flow channel depth that is radially inward from the accumulator body outer surface and is greater than the alignment groove depth, and a fluid flow channel longitudinal length that is at least equal to the alignment groove longitudinal width.
In another aspect of the present disclosure, an accumulator assembly for an engine assembly of a machine is disclosed. The engine assembly further includes a fuel injector having a high pressure fluid inlet port, and a cylinder head having a fuel injector bore surface defining a fuel injector bore in which the fuel injector is disposed, and an accumulator bore surface defining an accumulator bore having an accumulator bore inner diameter and an accumulator bore longitudinal axis and intersecting the fuel injector bore at a bore intersection area at which the high pressure fluid inlet port is aligned. The accumulator assembly includes an accumulator body and a seal member disposed on the accumulator body. The accumulator body includes an injector interface end dimensioned to be received by the high pressure fluid inlet port of the fuel injector, an accumulator body outer surface having a shape that is complimentary to the accumulator bore surface, an accumulator body longitudinal axis and an accumulator body outer diameter that is less than the accumulator bore inner diameter so that the accumulator bore surface and the accumulator body outer surface define an annular gap there between when the accumulator body is disposed within the accumulator bore and the accumulator body longitudinal axis is aligned coincident with the accumulator bore longitudinal axis, and an alignment groove surface defining an alignment groove in the accumulator body outer surface having an alignment groove depth that is radially inward from the accumulator body outer surface and an alignment groove longitudinal width. The seal member is disposed within the alignment groove and has a seal inner edge surface engaging the alignment groove surface to prevent fluid flow there between, and a seal outer edge surface having a plurality of accumulator bore engagement portions that extend radially outwardly beyond the accumulator body outer surface and engage the accumulator bore surface to align the accumulator body for insertion of the injector interface end into the high pressure fluid inlet port of the fuel injector. The seal outer edge surface does not engage the accumulator bore surface between adjacent accumulator bore engagement portions so that cooling fluid can flow past the seal member between the seal outer edge surface and the accumulator bore surface.
In a further aspect of the present disclosure, an engine assembly of a machine is disclosed. The engine assembly may include a fuel injector having a high pressure fluid inlet port, a cylinder head having a fuel injector bore surface defining a fuel injector bore in which the fuel injector is disposed, and an accumulator bore surface defining an accumulator bore having an accumulator bore inner diameter and an accumulator bore longitudinal axis and intersecting the fuel injector bore at a bore intersection area at which the high pressure fluid inlet port is aligned, an accumulator body and a seal member disposed on the accumulator body. The accumulator body includes an injector interface end dimensioned to be received by the high pressure fluid inlet port of the fuel injector, an accumulator body outer surface having a shape that is complimentary to the accumulator bore surface, an accumulator body longitudinal axis and an accumulator body outer diameter that is less than the accumulator bore inner diameter so that the accumulator bore surface and the accumulator body outer surface define an annular gap there between when the accumulator body is disposed within the accumulator bore and the accumulator body longitudinal axis is aligned coincident with the accumulator bore longitudinal axis, and an alignment groove surface defining an alignment groove in the accumulator body outer surface having an alignment groove depth that is radially inward from the accumulator body outer surface and an alignment groove longitudinal width. The seal member is disposed within the alignment groove and having a seal inner edge surface engaging the alignment groove surface and a seal outer edge surface engaging the accumulator bore surface to align the accumulator body for insertion of the injector interface end into the high pressure fluid inlet port of the fuel injector. The alignment groove and the seal member are configured so that cooling fluid can flow past the seal member when the accumulator body is installed in the accumulator bore and the seal outer edge surface engages the accumulator bore surface.
Additional aspects are defined by the claims of this patent.
The alignment groove 94 extends radially inwardly from the accumulator body outer surface 24 as seen in
The fluid flow channel 98 also extends radially inwardly from the accumulator body outer surface 24. In this embodiment, the accumulator body 90 has a first fluid flow channel surface 96 defining a first fluid flow channel 98, and a second fluid flow channel surface 96 located diametrically opposite the first fluid flow channel surface 96 and defining a second fluid flow channel 98. The fluid flow channels 98 are disposed longitudinally at the alignment groove 94. In the illustrated embodiment, the alignment groove 94 and the fluid flow channels 98 are longitudinally centered with respect to each other, but the fluid flow channels 98 may be longitudinally offset from the illustrated centered positions so long as fluid flow is provided as discussed further below. Each fluid flow channel 98 has a fluid flow channel radius rC (
Referring to
The seal member 100 has a seal radial thickness tS from the seal inner edge surface 104 to the seal outer edge surface 102 when the seal member 100 is installed within the alignment groove 94 that is greater than the alignment groove depth dG so that the seal outer edge surface 102 extends radially outwardly beyond the accumulator body outer surface 24. Moreover, the sum of the alignment groove radius rG and the seal radial thickness tS is greater than an accumulator bore radius rBORE from the accumulator bore longitudinal axis 56 to the accumulator bore surface 40 so that the seal outer edge surface 102 engages the accumulator bore surface 40 when the body section 26 is disposed within the corresponding bore section 48. The engagement between the seal outer edge surface 102 and the accumulator bore surface 40 aligns the accumulator body 90 within the accumulator bore 42 for insertion of the injector interface end 34 into the bore intersection area 68 and the high pressure fluid inlet port 72 of the fuel injector 70. The longitudinal axes 22, 56 may be approximately coincidentally aligned, and the annular gap 80 may be formed about the entire circumference of the accumulator body 90.
The seal inner edge surface 104 of the seal member 100 engages the alignment groove surface 92 at locations other than at the fluid flow channels 98 so that cooling fluid from a cooling fluid passage 106 and a cooling fluid opening 108 formed between an outer surface of the fuel injector 70 and the bore intersection area 68 (
During some installations, the fuel injector 70 may be installed with the high pressure fluid inlet port 72 not perfectly aligned with the accumulator bore longitudinal axis 56. The complimentary shapes of the high pressure fluid inlet port 72 and the injector interface end 34 may direct the injector interface end 34 into the high pressure fluid inlet port 72 and form the seal between the parts when the end 34 and the port 72 are not perfectly aligned. The engagement of the injector interface end 34 forces the accumulator body 90 out of alignment with the accumulator bore longitudinal axis 56. At the same time, the flexibility and resiliency of the seal member 100 permits the movement of the accumulator body 90 that is necessary to mate the injector interface end 34 with the high pressure fluid inlet port 72 and form the seal.
As best seen in
As shown, the seal member 126 has three accumulator bore engagement portions or seal nodes 132 circumferentially spaced about the seal outer edge surface 130 and having the maximum seal radial thickness tSMAX. The seal member 126 could have as few as two seal nodes 132 or additional seal nodes 132 if necessary. When the accumulator body 120 is inserted into the accumulator bore 42, the seal nodes 132 engage the accumulator bore surface 40 when the body section 26 is disposed within the corresponding bore section 48. The engagement between the seal nodes 132 and the accumulator bore surface 40 aligns the accumulator body 120 within the accumulator bore 42 for insertion of the injector interface end 34 into the bore intersection area 68 and the high pressure fluid inlet port 72 of the fuel injector 70. The longitudinal axes 22, 56 may be approximately coincidentally aligned, and the annular gap 80 may be formed about the entire circumference of the accumulator body 120.
In the portions of the seal outer edge surface 130 between adjacent seal nodes 132 where the alignment groove radius rG plus the seal radial thickness tS is less than the accumulator bore radius rBORE, the seal outer edge surface 130 does not engage the accumulator bore surface 40, and fluid flow gaps 134 are created that will allow cooling fluid to flow past the seal member 126 between the seal outer edge surface 130 and the accumulator bore surface 40. If the high pressure fluid inlet port 72 is not aligned with the accumulator bore longitudinal axis 56, the flexibility and resiliency of the seal member 126 will permit movement of the accumulator body 120 to allow the injector interface end 34 and the high pressure fluid inlet port 72 to mate and seal in a similar manner as the seal member 100 discussed above.
The seal member 146 as shown is an O-ring seal having a circular cross-section, but may be any other appropriate annular seal, gasket or washer having other cross-sectional shapes. The seal radial thickness tS of the seal member 146 between a seal inner edge surface 150 and a seal outer edge surface 152 may be constant when the seal member 146 is not installed on the accumulator body 140 in the alignment groove 144. The seal radial thickness tS may vary, however, when the seal member 146 is installed within the alignment groove 144 and the groove nodes 148 stretch the seal member 146 to conform to the shape of the alignment groove 144. The seal inner edge surface 150 may conform to the shape of the alignment groove surface 122 and engage the alignment groove surface 122 to prevent fluid flow there between. The seal member longitudinal width wS of the seal member 146 may be greater than or less that the alignment groove longitudinal width wG to engage or not engage both sides of the alignment groove 144 depending on the requirements for a particular implementation of the accumulator assembly 12.
The maximum alignment groove depth dGMAX may be greater than or equal to the seal radial thickness tS of a corresponding portion of the seal member 146 so that portions of the seal member 146 with the radial seal thickness tS being less than or equal to the alignment groove depth dG do not extend past the accumulator body outer surface 24. The minimum alignment groove depth dGMIN is less than the seal radial thickness tS of a corresponding portion of the seal member 146 so that portions of the seal member 146 with the seal radial thickness tS greater than the alignment groove depth dG extend radially outwardly past the accumulator body outer surface 24. Where the alignment groove radius rG plus the seal radial thickness tS is greater than the accumulator bore radius rBORE, such as at the groove nodes 148, corresponding accumulator bore engagement portions of the seal outer edge surface 152 will engage the accumulator bore surface 40 when the longitudinal axes 22, 56 are aligned.
When the accumulator body 140 is inserted into the accumulator bore 42, the accumulator bore engagement portions of the seal outer edge surface 152 proximate the groove nodes 148 engage the accumulator bore surface 40 when the body section 26 is disposed within the corresponding bore section 48. The engagement between the seal outer edge surface 152 at the groove nodes 148 and the accumulator bore surface 40 aligns the accumulator body 140 within the accumulator bore 42 for insertion of the injector interface end 34 into the bore intersection area 68 and the high pressure fluid inlet port 72 of the fuel injector 70. The longitudinal axes 22, 56 may be approximately coincidentally aligned, and the annular gap 80 may be formed about the entire circumference of the accumulator body 140.
In the portions of the seal outer edge surface 152 between adjacent groove nodes 148 where the alignment groove radius rG plus the seal radial thickness tS is less than the accumulator bore radius rBORE, the seal outer edge surface 152 does not engage the accumulator bore surface 40, and fluid flow gaps 154 are created that will allow cooling fluid to flow past the seal member 146 between the seal outer edge surface 152 and the accumulator bore surface 40. If the high pressure fluid inlet port 72 is not aligned with the accumulator bore longitudinal axis 56, the flexibility and resiliency of the seal member 146 will permit movement of the accumulator body 140 to allow the injector interface end 34 and the high pressure fluid inlet port 72 to mate and seal in a similar manner as the seal members 100, 126 discussed above.
The accumulator centering mechanisms illustrated and described herein center the accumulator bodies 90, 120, 140 within the accumulator bore 42 along the accumulator bore longitudinal axis 56 and with the high pressure fluid inlet port 72 of the fuel injector 70. The centering of the accumulator bodies 90, 120, 140 avoids having the injector interface end 34 of the accumulator bodies 90, 120, 140 hit the accumulator bore surface 40 and the outer surface of the fuel injector 70 and causing damage to the components during installation of the accumulator assembly 12 and the fuel injector 70. At the same time, the resiliency of the seal members 100, 126, 146 allows the accumulator bodies 90, 120, 140 to be forced off center in order for the injector interface end 34 to properly align and be received by the high pressure fluid inlet port 72 of the fuel injector 70 if the port 72 is not aligned with the accumulator bore longitudinal axis 56. The flexibility in alignment allows the injector interface end 34 and the high pressure fluid inlet port 72 to properly mate and form the seal there between. At the same time, the configurations of the alignment grooves 94, 124, 144 and the corresponding seal members 100, 126, 146 allow cooling fluid to flow past the seal members 100, 126, 146 through the annular gap 80, over the accumulator body outer surface 24 and out through the drain port 60 to cool the accumulator assembly 12 during operation of the engine assembly 10.
While the preceding text sets forth a detailed description of numerous different embodiments, it should be understood that the legal scope of protection is defined by the words of the claims set forth at the end of this patent. The detailed description is to be construed as exemplary only and does not describe every possible embodiment since describing every possible embodiment would be impractical, if not impossible. Numerous alternative embodiments could be implemented, using either current technology or technology developed after the filing date of this patent, which would still fall within the scope of the claims defining the scope of protection.
It should also be understood that, unless a term was expressly defined herein, there is no intent to limit the meaning of that term, either expressly or by implication, beyond its plain or ordinary meaning, and such term should not be interpreted to be limited in scope based on any statement made in any section of this patent (other than the language of the claims). To the extent that any term recited in the claims at the end of this patent is referred to herein in a manner consistent with a single meaning, that is done for sake of clarity only so as to not confuse the reader, and it is not intended that such claim term be limited, by implication or otherwise, to that single meaning.
Number | Name | Date | Kind |
---|---|---|---|
6199539 | Pearlman | Mar 2001 | B1 |
6237570 | Denso | May 2001 | B1 |
6279540 | Greaney | Aug 2001 | B1 |
8069842 | Bosch | Dec 2011 | B2 |
20090183713 | Bonfigli | Jul 2009 | A1 |
Number | Date | Country |
---|---|---|
0915253 | May 1999 | EP |
WO-2012102635 | Aug 2012 | WO |
Number | Date | Country | |
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20180202400 A1 | Jul 2018 | US |