The present disclosure relates generally to devices for filtering fluids. More particularly, the present disclosure relates to fuel filter cartridges for removing particulates and separating water from fuel being delivered to an internal combustion engine.
Significant quantities of contaminants such as abrasive particles and water are found in diesel fuel. Abrasive particles may damage sensitive engine components such as the fuel injection pump. Likewise, in addition to corroding metal components, water may obstruct the fuel lines when environmental temperatures fall below freezing. It is necessary to remove particulates and water from fuel before the fuel is supplied to an engine in order to ensure that the engine operates properly and has a long service life.
Fuel filter cartridges are a well-known solution for removing particulates and water from fuel before the fuel is pumped into sensitive engine systems. These known filter cartridges typically have a housing which defines an axial opening at one end to provide fuel communication between the fuel delivery system and a filter element disposed within the filter cartridge housing. Customarily, the filter cartridge housing comprises two separate shell portions, one of which defines the axial opening. Filter elements typically comprise a ring of fuel filter media and a pair of end caps. The filter media typically comprises non-woven material, while one end cap is typically an imperforate cover to which one end of the fuel filter media is permanently affixed.
In some filter cartridge configurations, two metal cans are connected by a roll seam to form the filter cartridge housing. Here, the filter cartridge housing may then be attached by a separate collar member of a filter head having an inlet and an outlet port adapted for attachment of fluid lines directing fluid into and away from the filter cartridge. In other configurations, there may be threads on the filter cartridge itself that allow for the filter cartridge to threadably mount to the filter head.
In cases where the filter cartridge itself is threadably mounted to the filter head, it is desirable to prevent the filter element from backing off or becoming detached from the filter head. For this, the construction of the housing of such filter cartridges requires some form of positive locking assembly to maintain the integrity of the housing when the filter cartridge is spun-on to the filter head. Prior art locking assemblies include disadvantages associated with complexity and practicality of manufacturing.
It is desirable to provide an improved filter cartridge locking assembly in a manner that fulfills one or more of the needs described above.
According to aspects illustrated herein, the filter cartridge locking assembly (hereafter, “the locking assembly”) is configured to couple and secure parts of a filter cartridge without the use of excess components and/or complex manufacturing. Specifically, the locking assembly rotationally and axially locks a collar member within a housing.
The housing of the locking assembly defines a cavity and includes first and second ends and an annular sidewall extending therebetween. A circumferential retainer is included at the first end of the housing for securing the collar. A filter element is situated within the cavity of the housing and an annular filtration space is defined between the filter element and the housing for filling with dirty fluid. The filter element includes a cylindrical ring of filter media disposed about a longitudinal axis and extends axially between a first endcap and a second endcap. The first endcap defines an outlet having a first gland that receives a first annular seal which seals against an outlet passage defined by the filter head to separate clean and dirty fluid.
The collar includes first and second ends and fits into the circumferential retainer included at the first end of the housing. At least one notch is formed between the first and second ends of the collar for mating with at least one complimentary bead included on the circumferential retainer. Mounting threads are positioned between the first and second ends of the collar for threadably attaching to the filter head. An annular outwardly extending flange is positioned between the mounting threads and the second end for preventing overtightening of the collar to the filter head. A first annular gap having a first axial length is defined between the mounting threads and the flange for receiving a bottom surface of the filter head. A second annular gap having a second axial length is defined between the flange and the second end for receiving the circumferential retainer. The first end of the collar includes a second gland that receives a second annular seal which seals against the interior of the filter head to separate dirty fluid from an area outside of the filter cartridge. The second end of the collar includes a third gland that receives a third annular seal which seals against the housing to prevent leakage from the filter cartridge.
The circumferential retainer is included at the first end of the housing and receives the second end of the collar. The retainer is comprised of a first leg that extends radially outwardly, a second leg that extends substantially perpendicular to the first leg, and the at least one peripheral bead. The retainer extends outwardly to define an outwardly flared annular clearance for fitting around the third gland.
In this arrangement, the second leg interacts surface-to-surface with the second annular gap and the at least one bead engages the at least one notch to form an axially and rotationally locked coupling between the housing and the collar without excess components and/or complex manufacturing.
According to aspects illustrated herein, a method of making the locking assembly comprises providing a filter housing that defines a cavity and includes first and second ends and an annular sidewall extending therebetween. A filter element is inserted into the housing and includes a cylindrical ring of filter media that is disposed about a longitudinal axis. The filter media extends axially between first and second endcaps. The first endcap defines an outlet having a first gland that receives a first annular seal which seals against an outlet passage defined by the filter head to separate clean and dirty fluid.
A collar having first and second ends fits into the first end of the housing. At least one notch is formed between the first and second ends of the collar. Mounting threads are positioned between the first and second ends of the collar and an annular outwardly extending flange is positioned between the mounting threads and the second end. A first annular gap having a first axial length is defined between the mounting threads and the flange and a second annular gap having a second axial length is defined between the flange and the second end. The first end of the collar includes a second gland that receives a second annular seal which seals against the interior of the filter head to separate dirty fluid from an area outside of the filter cartridge. The second end of the collar includes a third gland that receives a third annular seal which seals against the housing to prevent leakage from the filter cartridge.
A circumferential retainer is formed at the first end of the housing and receives the second end of the collar. The retainer is comprised of a first leg that extends radially outwardly, a second leg that extends substantially perpendicular to the first leg, and at least one peripheral bead.
In this arrangement, positioning the second leg into the second annular gap and engaging the at least one bead with the at least one notch forms an axially and rotationally locked coupling between the housing and the collar.
Aspects of an embodiment will be described in reference to the drawings, where like numerals reflect like elements:
An embodiment of a filter cartridge locking assembly (hereafter, “the cartridge”) according to aspects of the disclosure will now be described with reference to
As shown in
Referring to
As illustrated by
In the above arrangement, dirty fluid flows through the inlet 62 and fills the filtration space 32. The dirty fluid flows radially inward through the filter media 52 separating particulates and water from the fluid. Clean fluid flows into the center tube 54 and upwardly through the outlet 60 to the outlet passage 220 (see
As shown in
Referring to
As shown in
Referring to
The clearance 92 is configured to receive and securely fit around the outer gland 71 included on the collar 70. The first leg 94 is positioned within the lower annular gap 81 and extends outwardly substantially perpendicular to the annular sidewall 76 in a surface-to-surface relationship with the shoulder 75 of the outer gland 71. The second leg 96 is also positioned within the lower annular gap 81 and extends toward the flange 82 perpendicularly from the first leg 94 in a surface-to-surface relationship with the annular sidewall 76 of the collar 70. In this arrangement, the retainer 90 functions to exert an inward force FA (see
In the disclosed embodiment, the lower end of the housing 30 is a gravitational bottom and provides for a sump 38. This arrangement is advantageous in certain liquid filter applications such as fuel filtration where heavier water can fall to the sump 38 where it is collected. Water droplets coalesced and separated outside of the filter media 52 collect in the sump 38 over time. To allow for drainage of water collected in the sump 38, the housing 30 may include a drain opening 40 that is formed through an otherwise closed lower end wall of the housing 30. A drain cock (i.e. valve) can be connected to the lower end and has an open position for allowing drainage through the drain opening 40 and a closed position for preventing drainage through drain opening 40. Alternatively, a water collection bowl may be connected at drain opening 40.
In the disclosed embodiment, the housing 30 is constructed of steel sheet metal and the collar 70 is made of plastic but a person having ordinary skill in the art would appreciate that other materials are compatible with the disclosed filter cartridge 10.
While an embodiment of the disclosed filter cartridge locking assembly 10 has been set forth for purposes of illustration, the foregoing description should not be deemed a limitation of the invention. Accordingly, various modifications, adaptations and alternatives may occur to one skilled in the art without departing from the spirit of the disclosure and the scope of the claimed coverage.
Filing Document | Filing Date | Country | Kind |
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PCT/US2019/031136 | 5/7/2019 | WO | 00 |
Number | Date | Country | |
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62668308 | May 2018 | US |