The present disclosure is directed to a pre-cleaner and, more particularly, to a pre-cleaner for use with an internal combustion engine.
Machines used in the farming, construction, mining, power generation, and other like industries commonly include a frame that supports an internal combustion engine, a work tool movably connected to the frame, and at least one hydraulic cylinder connected between the frame and the work tool and driven by the engine. Such machines typically operate in harsh environments characterized by large amounts of airborne dust, dirt, and debris. In such environments, it is desirable to remove such debris from the air before directing the air to the engine. To assist with this process, such machines typically include an intake air filter or other like air cleaner configured to remove airborne debris upstream of the engine. Further, to assist in prolonging the useful life of such air cleaners, some machines may also include a pre-cleaner configured to remove relatively large debris from the intake air stream prior to cleaning the intake air with the air cleaner.
An exemplary air intake system employing a pre-cleaner is disclosed in U.S. Pat. No. 8,177,872 (“the '872 patent”), issued May 15, 2012. The pre-cleaner taught in the '872 patent includes a plurality of intertial separators disposed within a housing that is fluidly connected upstream of an engine air cleaner. As intake air is drawn into the housing, the inertial separators remove relatively large debris particles from the air and deposit them within the housing. These particles are then removed from the housing via a scavenge pipe fluidly connected to the exhaust system of the engine.
While the system of the '872 patent may be configured to remove relatively large debris particles from intake air, such systems are known to have several drawbacks. For example, in relatively high-debris environments, the inertial separators used in such systems are easily clogged. Once clogged, such separators can be difficult to clean due to their size, location, and configuration. Additionally, as such separators become clogged, air flow through the pre-cleaner is reduced. If left unchecked, this reduction in air flow can create an area of low pressure within the pre-cleaner strong enough to draw high temperature exhaust into the pre-cleaner. Such high temperature exhaust can damage the pre-cleaner and can have unwanted effects on the combustion process within the engine.
Moreover, scavenge pipes of the type disclosed in the '872 patent often have difficulty removing debris that has been collected within the pre-cleaner housing. Since the vacuum flow through such scavenge pipes is typically dictated by engine speed, the debris removal capabilities of such scavenge pipes can be significantly reduced at engine idle or other modes of engine operation characterized by relatively low engine speed. As a result, collected debris can accumulate within the housing over time. Due to the number and close proximity of inertial separators employed by such pre-cleaners, operators may have difficulty manually removing such accumulated debris from the pre-cleaner housing, and this built-up debris can reduce the efficiency of the pre-cleaner.
The exemplary embodiments of the present disclosure are directed toward overcoming one or more of the problems set forth above and/or other problems of the prior art.
In an exemplary embodiment of the present disclosure, a pre-cleaner for use with an internal combustion engine includes a base having a substantially planar interior surface, a scavenge port, and a plurality of separators extending substantially perpendicularly from the interior surface. The pre-cleaner also includes a baffle removably connected to the base, the baffle having a plurality of separator features configured to mate with the plurality of separators. The pre-cleaner further includes a deck disposed between the interior surface and the baffle. The deck is positioned at an acute angle relative to the interior surface such that a first portion of the deck is disposed closer to the interior surface than a second portion of the deck.
In another exemplary embodiment of the present disclosure, a pre-cleaner for use with an internal combustion engine includes a base having a substantially planar interior surface, a plurality of scavenge ports fluidly connected to the interior surface, and a plurality of separators extending substantially perpendicularly from the interior surface. The pre-cleaner also includes a baffle removably connected to the base opposite the interior surface and configured to mate with the plurality of separators. The pre-cleaner further includes a plenum fluidly connected to the plurality of scavenge ports and disposed proximate an exterior surface of the base opposite the interior surface.
In a further exemplary embodiment of the present disclosure, an intake system for use with an internal combustion engine includes a pre-cleaner having a base including an inlet, an outlet, and a scavenge port. The inlet is configured to receive intake air, and the scavenge port includes an orifice formed by a substantially planar interior surface of the base. The intake system also includes an air filter fluidly connected to the outlet and configured to receive pre-cleaned air from the outlet. The intake system further includes an exhaust passage fluidly connected to the engine and the scavenge port. The exhaust passage is configured to receive combustion exhaust from the engine and to receive debris removed from the intake air by the pre-cleaner. The intake system further includes a fan fluidly connected to the exhaust passage and configured to direct the debris from the pre-cleaner to the exhaust passage via the orifice of the scavenge port.
Air filter 14 may comprise any type of air cleaner known in the art configured to sufficiently condition intake air for use by the engine. In exemplary embodiments, pre-cleaner 12 may be configured to remove relatively large debris from the intake air and to direct such “pre-cleaned air” to the filter 14 for further cleaning. Filter 14 may be configured to remove relatively smaller debris from the pre-cleaned air. Accordingly, filter 14 may comprise paper, mesh, or other like filtration media that is relatively less porous than like filtration components of pre-cleaner 12. In exemplary embodiments, such media may be corrugated to assist in removing debris from the pre-cleaned air, and may be substantially linear, substantially cylindrical, and/or any other known shape or configuration.
Fan 22 may comprise any type of air movement device configured to apply a negative pressure (i.e., a vacuum) to pre-cleaner 12. In exemplary embodiments, fan 22 may include one or more blades, impellers, or other like air movement components (not shown), and fan 22 may be driven by any known power source associated with the engine and/or with the machine (not shown) to which the engine is operably connected. For example, fan 22 may be driven by and/or otherwise operably connected to one or more electric motors disposed on the machine. Alternatively, fan 22 may be mechanically connected to the engine by one or more belts, gears, shafts, and/or other like components. In such embodiments, fan 22 may be operably driven by and/or otherwise operably connected to the engine. Such connections may enable selective operation of fan 22, at any constant or variable speed, independent of, for example, engine speed or mode of engine operation.
Although not illustrated in
As shown in at least
Base 26 may comprise a substantially cylindrical housing configured to receive intake air via inlet 13, and to remove debris from the intake air via one or more filtration components disposed therein. Such intake air may enter base 26 via inlet 13 in the direction of arrows 38 shown in
Separators 32 may include one or more components configured to assist in separating debris from the intake air. Such components may include one or more vanes, fins 34, venturiis, restrictions, screens, meshes, or other like components. As shown in at least
Base 26 may further include one or more scavenge ports 44 configured to direct debris removed from the intake air out of pre-cleaner 12. In exemplary embodiments, base 26 may include a debris collection cavity 45, and the one or more scavenge ports 44 of base 46 may be fluidly connected to collection cavity 45 and/or components thereof. For example, collection cavity 45 may be at least partially defined by interior surface 36 of base 26 and one or more interior sidewalls of base 26 extending substantially perpendicularly from interior surface 36. In such embodiments, one or more scavenge ports 44 may be fluidly connected to interior surface 36. It is understood that collection cavity 45 may comprise a substantially annular channel within which debris removed from the intake air by separators 32 may collect. One or more separators 32 of the plurality of separators 32 may be disposed within and/or may otherwise assist in forming collection cavity 45. Similarly, when baffle 28 is connected to base 26, one or more surfaces of baffle 28 (such as a substantially planar bottom surface of baffle 28 as described below) may assist in forming a top portion of collection cavity 45 opposite surface 36 and/or deck 60.
Scavenge ports 44 may each comprise an orifice 47 formed by internal surface 36 of base 26, and a substantially hollow channel 46 fluidly connected to orifice 47. In exemplary embodiments, channel 46 may be fluidly connected to scavenge passage 20 and may be configured to direct debris disposed within collection cavity 45 to exhaust passage 24 via scavenge passage 20. As will be discussed in greater detail below with respect to
As most clearly illustrated in
In exemplary embodiments, deck 60 may be positioned within base 26 between interior surface 36 and baffle 28, and may be positioned at an acute angle relative to the interior surface 36. For example, top surface 67 and/or the bottom surface of deck 60 may be disposed at an acute included angle relative to interior surface 36. In such embodiments, a first portion 62 of deck 60 may be disposed closer to interior surface 36 than a second portion 64 of deck 60. As shown in the exemplary embodiment of
As noted above, deck 60 may be shaped, sized, and/otherwise configured to substantially block debris, removed from intake air by the plurality of separators 32, from contacting interior surface 36. Instead, such debris may pass from separators 32 to top surface 67, and may be directed to the one or more scavenge ports 44 of base 26 by top surface 67. Deck 60 may be dimensioned such that a negligible gap may be formed between an outer perimeter of deck 60 and the one or more interior sidewalls of base 26. In such embodiments, the size of such a gap may be minimized to reduce and/or substantially eliminate the amount of debris passing therethrough and onto interior surface 36.
Each thru hole 66 of the plurality of thru holes 66 may be configured to mate with a corresponding separator 32 of base 26. For example, each separator 32 of the plurality of separators 32 may pass substantially through a respective thru hole 66 of the plurality of thru holes 66. Thru holes 66 may be shaped, sized, and/or otherwise configured to accept passage of a respective separator 32 therethrough. For example, as described above with respect to the gap formed between the one or more interior sidewalls of base 26 and the outer perimeter of deck 60, each thru hole 66 may be positioned and dimensioned such that a negligible gap is formed between the outer wall of a respective separator 32 and an inner diameter of the thru hole 66. In such embodiments, the size of such a gap may be minimized to reduce and/or substantially eliminate the amount of debris passing therethrough and onto interior surface 36. Moreover, in exemplary embodiments, each thru hole 66 may be formed in deck 60 at an angle, relative to top surface 67, that is complementary with the acute angle at which deck 60 is disposed within base 26. Such a complementary angle may be formed between the outer wall of each separator 32 and top surface 67 in embodiments in which deck 60 is positioned at an acute angle relative to interior surface 36 and in which separators 32 extend substantially perpendicularly from interior surface 36. Thus, forming thru holes 66 at such a complementary angle relative to top surface 67 may assist in minimizing the size of the gaps formed between the outer wall of each respective separator 32 and the inner diameter of each corresponding thru hole 66.
As shown in
It is understood that disposing deck 60 within collection cavity 45 at an acute angle relative to interior surface 36 may affect fluid flow within collection cavity 45 and, in particular, proximate top surface 67. For example, when disposed as shown in
In exemplary embodiments, deck 60 may be formed as a separate component of base 26 and may be disposed within collection cavity 45 during assembly of pre-cleaner 12. In further exemplary embodiments, deck 60 may be configured as a substantially annular inclined plane. In such embodiments, first portion 62 of deck 60 may have a first axial thickness and second portion 64 may have a second axial thickness greater than the first axial thickness of first portion 62. In still further exemplary embodiments, deck 60 may be formed directly onto interior surface 36 of base 26. For example, in such embodiments deck 60 may be formed of any known curable material. Such materials may include, for example, molten and/or substantially liquid rubber, plastic, polymers, resins, and the like. In forming deck 60 from such materials, the material may be disposed onto interior surface 36 while in substantially liquid form. The substantially liquid material may then be allowed to cool, harden, solidify, and/or otherwise substantially cure on interior surface 36, thereby forming top surface 67, first portion 62, second portion 64, and other components of deck 60. It is understood that, as part of the curing process, the substantially liquid material may be guided to surround each separator 32 of the plurality of separators 32 such that the formed deck 60 substantially surrounds each separator 32 with substantially no gap therebetween. Likewise, during the curing process, the substantially liquid material may be guided to about the one or more interior sidewalls of base 26 such that deck 60 is formed substantially adjacent the one or more interior sidewalls with substantially no gap therebetween. Additionally, in exemplary embodiments base 26 may be maintained at the acute angle described above during the curing process such that first portion 62 of the formed deck 60 may be formed with a first axial thickness and second portion 64 may be formed with a second axial thickness greater than the first axial thickness of first portion 62.
With continued reference to at least
Baffle 28 may include, for example, a substantially planar top surface and a substantially planar bottom surface opposite the top surface. At least a portion of the bottom surface of baffle 28 may be configured to engage and/or otherwise mate with one or more separators 32 of the plurality of separators 32. For example, baffle 28 may include one or more separator features 50, and each separator feature 50 may be configured to mate with a respective separator 32 of base 26. Such separator features 50 may comprise substantially cylindrical or substantially conical protuberances extending from the bottom surface of baffle 28. In exemplary embodiments, such separator features 50 may be disposed at least partially within a top portion of a respective separator 32 when the baffle 28 is connected to base 26. Such separator features 50 may be sized, shaped, and/or otherwise configured to extend around an outer diameter or outer surface of the respective separator 32 or, alternatively, such separator features 50 may be sized, shaped, and/or otherwise configured for insertion within the inner cylindrical wall of the respective separator 32. In exemplary embodiments, a distal end of each separator feature 50 mating with the respective separator 32 may be substantially fluidly closed so as to assist in directing pre-cleaned intake air to outlet 15.
As mentioned above, and as shown in
Plenum 70 may comprise a substantially hollow, substantially cylindrical, tube-like manifold configured to transfer debris and/or air from the one or more scavenge ports 44 to scavenge passage 20. As shown in
In exemplary embodiments, each of the scavenge ports 44 described herein may have substantially the same shape, size, inner diameter, and/or other configuration to assist in directing debris, removed from the intake air by separators 32, from collection cavity 45 to plenum 70. Alternatively, as shown in at least
The intake systems 10 of the present disclosure have wide application in a variety of machine types including, for example, machines employed in mining, construction, farming, and power generation applications. The disclosed intake systems 10 find particular applicability in machines operating in environments characterized by high levels of airborne dust, dirt, water, particulates, and other known debris. By equipping or retrofitting machines with intake systems 10 of the present disclosure, damage to various components of such machines may be reduced and the operational efficiency of such machines may be improved.
For example, pre-cleaners 12 of the present disclosure may be characterized by improved debris removal capabilities relative to known pre-cleaners. The sloped and/or angled deck 60 described herein may, for example, utilize the effects of gravity to assist in directing debris collected on top surface 67 to the one or more scavenge ports 44 of base 26. First and second flow zones formed by respective first and second portions 64, 64 of deck 60 may further assist in directing such collected debris to the one or more scavenge ports 44. For example, the relatively high flow velocity associated with the second flow zone described herein may assist in removing collected debris disposed in locations within collection cavity 45 remote from primary scavenge port 44.
Moreover, the multi-scavenge port base 26 and/or multi-leg plenum 70 configurations described herein may enable pre-cleaners 12 of the present disclosure to remove collected debris directly from various locations spaced about collection cavity 45. By applying a direct negative pressure (supplied by fan 22 fluidly connected to plenum 70) at multiple locations within collection cavity 45, debris removal may be improved over known single-scavenge port pre-cleaner designs. As a result of the various components and configurations described herein, pre-cleaners 12 of the present disclosure experience reduced levels of separator clogging and require less frequent pre-cleaner maintenance as compared to known pre-cleaners.
Further, by incorporating a fan 22 or other negative pressure supply device capable of operating independently of engine speed, intake system 10 is configured to supply desired levels of negative pressure to pre-cleaner 12 during all modes of engine and/or machine operations. In particular, such independent control of fan 22 facilitates directing required levels of negative pressure to collection cavity 45 for debris removal during engine idle or other modes of engine operation characterized by relatively low engine speed. Known intake systems supplying negative pressure to associated pre-cleaners utilizing, for example, venturi devices disposed within an engine exhaust manifold are not capable of such low-engine speed debris removal. Additionally, whereas such venturi-based intake systems are prone to damage caused by relatively high temperature exhaust being directed to the pre-cleaner and other intake system components, intake system 10 of the present disclosure eliminates the threat of such damage.
It will be apparent to those skilled in the art that various modifications and variations can be made to the intake systems 10 of the present disclosure without departing from the scope of the disclosure. For example, as noted above, one or more of independently controlled fan 22, sloped and/or angled deck 60, multi-scavenge port 44 base 26, and multi-leg plenum 70 may be combined and/or otherwise incorporated into a single intake system 10. Various combinations of such components and/or configurations may further improve the debris removal capabilities of the resulting intake system 10. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.
This application is based on and claims the benefit of priority from U.S. Provisional Application No. 61/777,434, filed Mar. 12, 2013, the contents of which are expressly incorporated herein by reference.
Number | Date | Country | |
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61777434 | Mar 2013 | US |