Patent Grant
11598432
Valves are used in a variety of applications, such as piping, vehicles, and machinery, to regulate, direct, or otherwise control the flow of a fluid. In some cases, it may be desirable to allow the fluid to flow in a particular direction at a particular flow rate. Due to varying viscosities of fluid and to systems downstream of the valve that may create interference to the flow of the fluid (e.g., back pressure in a system), it may be difficult to quickly and efficiently allow fluid to flow through the valve. Thus, there is a need for a valve that allows fluid to flow in a particular direction at a desired flow rate.
The detailed description is set forth with reference to the accompanying figures. The use of the same reference numbers in different figures indicates similar or identical items.
Overview
As discussed above, mechanical assemblies, such as those found in vehicle engines, may include systems that require fluid to flow against back pressure. For example, some vehicle engines may require oil to drain out of an oil filtration system. Back pressure in the system may cause the oil to drain slowly out of the oil filtration system when an oil change is being performed. Existing valves, such as check valves, respond to flow and pressure disturbances such as turbulence in an upstream piping system. This can result in a disc of the check valve oscillating back and forth on a pin support. When turbulence becomes severe and the oscillations are of a large enough amplitude, the disc may continually move, banging against the stop, and the pin eventually fails.
This application describes a check valve having a hollow cylindrical body and a threaded portion on an exterior wall of the hollow cylindrical body such that the check valve may be coupled with an assembly, such as an oil filter adapter for a vehicle engine. The check valve may include a plunger having a dome shaped portion (e.g., cone shaped, semi-hemispherical shaped, rounded cone shaped, etc.) that extends out of the hollow cylindrical body into free space when the check valve is in an open position and forms a seal with the hollow cylindrical body when the check valve is in a closed position. The dome of the plunger may prevent turbulence of the check valve as fluid flows through the hollow cylindrical body of the check valve and into the attached assembly.
In some cases, the plunger includes a dome shaped portion (i.e., the end that extends into free space) and a stem portion with a threaded interior configured to couple with a screw. The stem portion of the plunger may be inserted through a spring and into a first end of the hollow cylindrical body such that the stem portion and the spring are located on an interior of the hollow cylindrical body. The interior of the hollow cylindrical body may include an interior edge located approximately midway of the hollow cylindrical body that contacts the spring such that the spring may not pass through the interior of the hollow cylindrical body. In some examples, the plunger may include a tapered portion interposed between the stem portion and the dome portion such that a seat of the tapered portions is configured to seal against an opening of the hollow cylindrical body.
In some cases, the screw may be inserted through a second portion of the hollow cylindrical body and be coupled through a first triad, a spacer and a second triad. The first triad and the second triad may be sized such that they fit into the interior portion of the hollow cylindrical base but are wide enough to make contact with the interior edge. In some examples, when the plunger and the spring are inserted into the first end of the hollow cylindrical base and when the screw, the first triad, the spacer, and the second triad are inserted through the second end of the hollow cylindrical base, the spring may compress against the interior edge and the screw may couple with the threaded interior of the stem portion of the plunger. In this way, the screw may hold the plunger in a closed position while compressing the spring against the interior edge. The first triad and the second triad may keep the screw linearly aligned with the plunger (i.e., in the center of the interior of the hollow cylindrical base) so that the plunger my freely move from a closed position to an open position, and vice versa, without any pieces of the check valve getting caught on an interior wall of the hollow cylindrical base. Thus, the first triad and the second triad may prevent canting and/or binding that may otherwise prevent the plunger from retracting into a closed position. In some cases, the first triad, the spacer, and the second triad may be a single piece that may couple with the screw.
In some cases, the exterior portion of the check valve may include a thread locking mechanism located in the threaded portion of the check valve to enable the check valve to be securely locked to an assembly such that the check valve does not turn when another part is being attached or removed. The thread locking mechanism may also be un-locked when it is desirable for the check valve to turn and be removed from, or further secured to, the assembly. In some cases, the check valve may be attached to an oil filter adapter that can be used in an engine to enable an oil filter system that is designed for using cartridge oil filters to use spin-on oil filters. The oil filter adapter may be configured to attach to an oil filter housing of a vehicle, form a seal with the oil filter housing, and couple with the check valve in order to attach to a spin-on oil filter. The check valve may have a first end that attaches to the oil filter adapter and a second end that attaches to a spin-on oil filter. When the check valve is attached to the oil filter adapter, threads on an exterior of the check valve may make contact with threads that are on an interior of the oil filter adapter. As the check valve is coupled with the oil filter adapter and turned clockwise, the check valve may recede into the oil filter adapter and the exterior threads of the check valve may interlace with the interior threads of the oil filter adapter as the check valve and the oil filter adapter tighten together and are coupled. Once the check valve is coupled with the oil filter adapter, the thread locking mechanism may be adjusted such that the check valve is unable to further spin clockwise or counter-clockwise, thereby uninstalling itself from the oil filter adapter. For example, the thread locking mechanism may be an adjustable portion of the first end of the check valve that attaches to an oil filter adapter. The adjustable portion may be adjustable via a screw that extends from the second end of the check valve into the adjustable portion located in the first end of the check valve that attaches to an oil filter adapter, with a head of the screw being accessible via the second end of the check valve when the check valve is coupled with the oil filter adapter. The adjustable portion may be coupled with the screw via threads located on an interior of the adjustable portion such that, when the screw is turned clockwise, the adjustable portion moves closer to the screw head, and when the screw is turned counter clockwise, the adjustable portion moves away from the screw head. In some case, the interior portion of the adjustable portion may include spring such that when the screw is inserted through the interior of the adjustable portion, the screw may travel through the spring and as the screw is turned clockwise and/or counter clockwise, the spring may compress and/or decompress. The adjustable portion may also include threads on an exterior portion of the adjustable portion such that, when the adjustable portion is properly aligned, the threads on an exterior portion of the adjustable portion line up with the exterior threads of the check valve. When the threads on the exterior portion of the adjustable portion and the exterior threads of the check valve are aligned, the check valve may freely be installed or un-installed with the oil filter adapter (i.e., may turn freely). Once the check valve is coupled with the oil filter adapter, and it is desirable to secure the check valve to the oil filter adapter (e.g., an oil filter is needed to be installed or un-installed from the oil filter adapter), the screw head may be turned clock wise causing the adjustable portion of the check valve to move closer to the screw head. When the check valve is coupled with the oil filter adapter and the adjustable portion of the check valve moves closer to the screw head, the threads located on the exterior portion of the adjustable portion become misaligned with the threads located on the exterior portion of the check valve, which causes a tension on the threads located on the interior portion of the oil filter adapter. This tension locks the check valve in place such that any torque on the check valve, e.g., adding or removing oil filters from the second end of the check valve, does not cause the check valve to move.
Although the example provided above in which the check valve may be used pertains to an oil filter adapter, any assembly in which the flow of a fluid is desired at a particular flow rate and with minimal turbulence may utilize the check valve.
Example Check Valve
Turning now to the figures, details are provided concerning various example embodiments. In general, the embodiments disclosed in the figures are presented by way of example. The components disclosed in the figures may be combined as desired to create a check valve having various configurations. The components disclosed in the figures may be rearranged, modified, duplicated, and/or omitted in some configurations.
With reference to
In some cases, the plunger 104 includes a dome 106 (i.e., the end that extends into free space) and a stem portion 108 with a threaded interior configured to couple with a screw 110. The stem portion 108 of the plunger 104 may be inserted through a spring 112 and into a first end of the hollow cylindrical body 102 such that the stem portion 108 and the spring 112 are located on an interior of the hollow cylindrical body 102 (e.g., slidably disposed into the interior) and the dome 106 of the plunger is located in an interior of an assembly, such as an oil filter adapter 120, when the check valve is coupled with the assembly. The interior of the hollow cylindrical body 102 may include an interior edge 122 located approximately midway of the hollow cylindrical body 102 that contacts the spring 112 such that the spring 112 may not pass through the interior of the hollow cylindrical body 102. In some examples, the plunger 104 may include a tapered portion interposed between the stem portion 108 and the dome 106 such that a seat of the tapered portions is configured to seal against an opening of the hollow cylindrical body 102. The tapered portion may change from a first diameter of an outer circumference of the dome 106 to a second diameter of an outer circumference of the stem portion 108.
In some cases, the screw 110 may be inserted through a second portion of the hollow cylindrical body 102 and be coupled through a first triad 114, a spacer 116, and a second triad 118. The first triad 114 and the second triad 118 may be sized such that they fit into the interior portion of the hollow cylindrical body 102 but are wide enough to make contact with the interior edge 122. In some examples, when the plunger 104 and the spring 112 are inserted into the first end of the hollow cylindrical body 102 and when the screw 110 the first triad 114, the spacer 116 and the second triad 118 are inserted through the second end of the hollow cylindrical body 102, the spring 112 may compress against the interior edge 122 and the screw 110 may couple with the threaded interior of the stem portion 108 of the plunger 104. In this way, the screw 110 may hold the plunger 104 in a closed position while compressing the spring 112 against the interior edge 122. The first triad 114 and the second triad 118 may keep the screw 110 linearly aligned with the plunger 104 (i.e., in the center of the interior of the hollow cylindrical body 102) so that the plunger 104 may freely move from a closed position to an open position, and vice versa, without any pieces of the check valve 100 getting caught on an interior wall of the hollow cylindrical body 102. Thus, the first triad 114 and the second triad 118 may prevent canting and/or binding that may otherwise prevent the plunger 104 from retracting into a closed position. In some cases, the first triad 114, the spacer 116, and the second triad 118 may be a single piece that may be coupled with the screw 110.
While various examples and embodiments are described individually herein, the examples and embodiments may be combined, rearranged and modified to arrive at other variations within the scope of this disclosure.
Although embodiments have been described in language specific to structural features and/or methodological acts, it is to be understood that the disclosure is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed herein as illustrative forms of implementing the claimed subject matter. Each claim of this document constitutes a separate embodiment, and embodiments that combine different claims and/or different embodiments are within the scope of the disclosure and will be apparent to those of ordinary skill in the art after reviewing this disclosure.
Although the disclosure describes embodiments having specific structural features and/or methodological acts, it is to be understood that the claims are not necessarily limited to the specific features or acts described. Rather, the specific features and acts are merely illustrative of some embodiments that fall within the scope of claims of the application.
This application claims priority to U.S. Provisional Patent Application No. 63/124,449, filed on Dec. 11, 2020, the entire contents of which are incorporated herein by reference.
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