US20140102483A1 - System and method to remove debris from a chamber - Google Patents
System and method to remove debris from a chamber Download PDFInfo
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- US20140102483A1 US20140102483A1 US13/650,582 US201213650582A US2014102483A1 US 20140102483 A1 US20140102483 A1 US 20140102483A1 US 201213650582 A US201213650582 A US 201213650582A US 2014102483 A1 US2014102483 A1 US 2014102483A1
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- Prior art keywords
- debris
- tab
- exhaust pipe
- gas
- conduit
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M35/00—Combustion-air cleaners, air intakes, intake silencers, or induction systems specially adapted for, or arranged on, internal-combustion engines
- F02M35/02—Air cleaners
- F02M35/022—Air cleaners acting by gravity, by centrifugal, or by other inertial forces, e.g. with moistened walls
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M35/00—Combustion-air cleaners, air intakes, intake silencers, or induction systems specially adapted for, or arranged on, internal-combustion engines
- F02M35/02—Air cleaners
- F02M35/08—Air cleaners with means for removing dust, particles or liquids from cleaners; with means for indicating clogging; with by-pass means; Regeneration of cleaners
- F02M35/086—Dust removal by flushing, blasting, pulsating or aspirating flow, washing or the like; Mechanical dust removal, e.g. by using scrapers
Definitions
- the present disclosure relates generally to debris removal systems. Specifically, an embodiment of the present invention relates to a debris removal system for removing debris from a chamber.
- Some components of machines can be damaged if dust or debris come in contact with or enter the component. For example, if dust enters an intake manifold of an engine, it may damage the combustion cylinders. Often machines working in dusty, or debris filled environments are equipped with air filtration systems. The air filtration systems protect sensitive components by removing dust and/or debris from air entering or having contact with the components.
- U.S. Pat. No. 7,004,987 issued to Pikesh et al. discloses a pre-cleaner for an air induction system of an internal combustion engine including a housing enclosing an upper chamber and an aspirator port chamber.
- the upper chamber contains a plurality of particulate separator tubes arranged in a predetermined array. Each of the tubes includes a particulate outlet through which particles removed from air flowing through the tube en route to the engine are discharged.
- the aspirator port chamber is located beneath, and is upwardly open to, the particulate outlets and includes an upwardly facing particle collecting surface located directly beneath the particulate outlets. Particles can fall from the tubes into the aspirator port chamber and onto the upwardly facing particle collecting surface.
- the housing includes a generally horizontally facing aspirator port in the aspirator port chamber adjacent to and facing the particle collecting surface.
- the housing also includes an element disposed for connecting the aspirator port to an exhaust tract of the internal combustion engine such that the exhaust flow through the exhaust tract will generate a suction condition in the aspirator port when the engine is operated.
- the particle collecting surface is positioned and oriented such that the suction generated by the exhaust flow during the operation of the engine will draw a flow of air from the upper chamber across the particle collecting surface such that particles collected on the surface will be drawn in an at least generally horizontal direction into the aspirator port.
- airflow created through a pre-cleaner by a flow of gas through an exhaust pipe and an air outlet, to draw debris out of a debris chamber, through a debris conduit, and through the air outlet may not be sufficient to remove enough debris from the chamber.
- a system to remove debris from a chamber including a debris chamber, an exhaust pipe, a debris conduit, an air outlet, and a tab.
- the exhaust pipe directs a flow of gas into the air outlet and includes an exhaust pipe interior.
- the debris conduit connects the chamber with at least one of the exhaust pipe interior and the air outlet and includes a debris conduit end disposed in at least one of the exhaust pipe interior and the air outlet.
- the tab has at least three outer edges forming at least two outer corners, and an adjacent edge, the adjacent edge adjacent to the debris conduit end.
- a machine including a body, an air filtration system, an exhaust pipe, an engine, a debris conduit, and a tab.
- the body defines a compartment with an air inlet and an air outlet.
- the air filtration system includes a pre-cleaner with a debris collection area disposed, the pre-cleaner configured to filter and trap debris in the debris collection area.
- the air filtration system is disposed in the air inlet.
- An air outlet stack is disposed in the air outlet.
- the exhaust pipe directs exhaust gas into and out of the air outlet, and includes an interior and an exhaust pipe end having a venturi portion.
- the engine is disposed in the compartment and is configured to exhaust gases through the exhaust pipe.
- the engine includes an intake manifold fluidly connected to the air inlet through the air filtration system.
- the debris conduit connects the debris collection area with at least one of the interior of the exhaust pipe and the air outlet, and includes a debris conduit end.
- the debris conduit end is disposed in at least one of the interior of the exhaust pipe and the air outlet.
- the debris conduit is configured for directing debris from the debris chamber through and out of at least one of the exhaust pipe and the air outlet.
- the tab with at least three outer edges forming at least two outer corners and an adjacent edge, is adjacent to the debris conduit end.
- a method for removing debris from a debris chamber includes directing a first gas through an exhaust pipe; over an outer surface, and around at least three outer edges, and two corners formed by the at least three outer edges of a tab; and through an air outlet.
- the method further includes flowing a second gas through the debris chamber and a debris conduit; and over an inner surface, and around the at least three outer edges, and two corners formed by the three outer edges of the tab. Additionally, the method includes creating vortex flow between the first gas and the second gas, and drawing debris out of the debris chamber, through the debris conduit, and through the air outlet.
- FIG. 1 depicts an exemplary machine including an embodiment of a debris removal system.
- FIG. 2 schematically depicts an exemplary debris removal system.
- FIG. 3 depicts a portion of an exemplary tab.
- FIG. 4 depicts a portion of an exemplary debris conduit from a perspective.
- FIG. 5 depicts an embodiment of an exemplary tab assembly.
- FIG. 6 depicts another embodiment of an exemplary tab assembly.
- FIG. 7 depicts another embodiment of a tab.
- FIG. 8 is a flow chart of an exemplary debris removal method.
- FIG. 9 schematically depicts an embodiment of a portion of a debris conduit disposed in the interior of an exhaust pipe with a cross section depicting vortex flow.
- the machine 100 is a vehicle 102 , and in particular a wheel loader 104 .
- the vehicle 102 may perform a type of operation associated with a particular industry such as mining, construction, farming, transportation, etc. and operates between or within work environments (e.g. construction site, mine site, power plants, on-highway applications, marine applications, etc.).
- work environments e.g. construction site, mine site, power plants, on-highway applications, marine applications, etc.
- Non-limiting examples of vehicle 104 include cranes, earthmoving vehicles, mining vehicles, backhoes, excavators, material handling equipment, dredgers, and farming equipment.
- machine 100 may include a stationary machine, such as an electric power generator or a pumping station for oil or gas (not shown).
- the wheel loader 104 includes a body 106 which defines a compartment 108 including an air outlet 110 , and an air inlet 114 .
- the air outlet includes an air outlet stack 112 .
- the air inlet 114 includes an air filtration system 116 , with a debris chamber 133 (shown in relation to FIG. 2 ).
- the air filtration system may also include a rain cap 115 , pre-cleaner 119 , and air filter 121 (shown in relation to FIG. 2 ).
- the pre-cleaner 119 may include the debris chamber 133 in the form of a debris collection area 134 (shown in relation to FIG. 2 ).
- the wheel loader 104 includes a power source 117 .
- the power source 117 includes an engine 118 disposed in the compartment 108 .
- the engine 118 may include an internal combustion engine.
- the wheel loader 104 is equipped with systems that facilitate the operation of the wheel loader 104 at a worksite 126 .
- these systems include a work implement system 124 , and a drive system 120 , both of which are powered by the engine 118 .
- the drive system 120 propels the wheel loader 104 on ground engaging devices 122 (depicted as wheels) to move the wheel loader 104 from one location to another.
- the work implement system 124 includes a bucket 128 and actuators and linkages 130 to move the bucket 128 to perform work at the worksite 126 .
- Wheel loader 104 includes an embodiment of a debris removal system 132 , depicted in FIG. 2 .
- the debris removal system 132 includes a debris chamber 133 , an exhaust pipe 136 , a debris conduit 142 , and a tab 146 .
- exhaust pipe 136 directs the flow of a first gas into an air outlet 110 and includes an exhaust pipe interior 137 .
- a flow of the first gas is illustrated in FIG. 2 with the arrows labeled “1”.
- the debris conduit 142 connects the debris chamber 133 with at least one of the exhaust pipe interior 137 and the air outlet 110 , and includes a debris conduit end 144 disposed in at least one of the exhaust pipe interior 137 and the air outlet 110 .
- the debris conduit 142 is configured to direct debris from the debris chamber 133 into at least one of the exhaust pipe 136 and the air outlet 110 .
- a tab 146 is adjacent the debris conduit end 144 .
- the system 132 includes a housing 148 which defines the compartment 108 , the air outlet 110 , and an air inlet 114 .
- the debris chamber 133 , debris conduit 142 , and at least a portion of the exhaust pipe 136 may be substantially enclosed by the housing 148 .
- the debris chamber 133 may include any substantially enclosed space or cavity for collecting dust and/or debris.
- the debris may include tiny pieces of rock, mud, seeds, chaff, ash, or other substances which may become airborne.
- the debris chamber 133 includes a debris collection area 134 which is contained in, and is an element of, the precleaner 119 .
- a flow of a second gas is illustrated in FIG. 2 with the arrows labeled “2”.
- a non-limiting example of an embodiment of air filtration system 116 includes the Donaldson STB StrataTM Air Cleaner including the DonaspinTM Pre-Cleaner.
- the second gas may include air from outside the compartment.
- the second gas may include air from the worksite 126 surrounding the machine 100 .
- the debris chamber 133 may include embodiments where additional filtering elements are not necessary, or embodiments in which the debris chamber 133 is not a component of the air filtration system 116 .
- the engine 118 includes an air intake manifold 150 fluidly connecting the engine 118 to the outside of the compartment 108 through the air filtration system 116 .
- a portion of the second gas flowing through the air inlet 114 may flow through the pre-cleaner 119 and the air filter 121 and into the intake manifold 150 .
- the pre-cleaner 119 may remove larger pieces of debris from the second gas by trapping them in the collection area 134 , and then remove additional dust and smaller debris particles through the air filter 121 , before the second gas is allowed to flow into the intake manifold 150 .
- Another portion of the second gas flowing through the inlet 114 may flow through the collection area 134 of the pre-cleaner 119 and then into the debris conduit 142 .
- the flow of the first gas from the exhaust pipe 136 may include a flow of heated gas, for example, a flow of heated exhaust gas from the engine 118 .
- the exhaust pipe 136 fluidly connects the engine 118 , with the air outlet 110 to expel exhaust gas.
- the exhaust gas from the engine 118 may flow through one or more aftertreatment devices 154 , and through one or more sound suppression devices 156 , before flowing into the exhaust pipe 136 and then through the air outlet 110 .
- engine 118 is depicted disposed in the compartment 108 , in other embodiments, engine 118 may be located outside or only partially disposed in the compartment 108 .
- engine 118 exhausts the flow of the first gas in the illustrated embodiment
- the flow of the first gas may originate and be directed through the exhaust pipe 136 by other devices or processes known in the art.
- a turbine may exhaust the flow of the first gas into the exhaust pipe 136
- a manufacturing process may create heat and a series of fans, air conduits, and/or valves may direct the flow of the first gas through the exhaust pipe 136 .
- the exhaust pipe 136 includes an exhaust pipe end 138 including a venturi portion 140 .
- the venturi portion 140 includes a neck portion 141 providing a restriction such that the velocity of the flow of the first gas is increased upon exiting the neck portion 141 , as is known in the art.
- the debris conduit 142 connects the debris chamber 133 to the exhaust pipe interior 137 .
- a portion of the debris conduit 142 including the debris conduit end 144 may be inserted into the exhaust pipe interior 137 through an aperture in the wall of the exhaust pipe 136 .
- the debris conduit 142 or a portion of the debris conduit 142 , and the exhaust pipe 136 or a portion of the exhaust pipe 136 may be manufactured as a single component.
- the debris conduit 142 and the debris conduit end 144 are positioned in relation to the exhaust pipe 136 , such that debris from the debris chamber 133 is directed into at least one of the exhaust pipe 136 and the air outlet 110 .
- the air outlet 110 includes the air outlet stack 112 .
- the exhaust pipe end 138 and debris conduit end 144 are positioned in the air outlet stack 112 such that the flow of the first gas from the exhaust pipe 136 into the air outlet stack 112 creates a low pressure area proximate the debris conduit end 144 .
- the low pressure area may be created above the debris conduit end 144 .
- the second gas from outside the compartment 108 , entering the compartment 108 through the air filtration system 116 may be at a higher pressure than the low pressure area created proximate the debris conduit end 144 .
- the second gas may flow from the higher pressure area outside the compartment, through the collection area 134 , and through the debris conduit 142 .
- the second gas may carry dust and/or debris from the collection area 134 , through the debris conduit 142 , through the outlet stack 112 , and out of the compartment 108 .
- the housing 148 defines an aperture 158 fluidly connecting the compartment 108 with air outside the housing 148 .
- a flow of a third gas is illustrated in FIG. 2 with the arrows labeled “3”.
- the third gas may flow in the aperture 158 , through the compartment 108 , and out the air outlet 110 .
- Heat energy may transfer from the engine 118 , aftertreatment devices 154 , sound suppression devices 156 , and/or other components in the compartment 108 to the third gas to cool these components.
- the flow of the first gas through the exhaust pipe 136 and out the air outlet 110 may increase the velocity of the flow of the third gas through the compartment 108 , as is known in the art.
- the increased velocity of the third gas may provide improved cooling of the components in the compartment 108 .
- aperture 158 may include vents, cracks, or an open side of the compartment 108 .
- the third gas is drawn through these apertures 158 , through the compartment 108 , and through the air outlet 110 .
- FIGS. 3 and 4 a perspective view of a portion of an exemplary embodiment of the debris conduit 142 , including debris conduit end 144 , having multiple tabs 146 ; and a view of an exemplary tab 146 are illustrated.
- Debris conduit 142 includes debris conduit end 144 .
- the debris conduit end 144 is illustrated with four tabs, it is contemplated that there may be embodiments with one, two, three, or more than four tabs 146 .
- debris conduit end 144 includes a circle shape with a diameter marked as “D” in FIG. 4 .
- the debris conduit end 144 may include other shapes, for example an ellipse, an octagon, a square, or any other shape known in the art.
- the debris conduit 142 includes an exterior wall 164 and an interior wall 174 .
- debris conduit 142 is substantially cylindrical.
- the debris conduit 142 may be any elongated tube type shape known in the art to be operable to fluidly connect the debris chamber 133 with one of the interior of the exhaust stack 136 and the air outlet 110 .
- Non-limiting examples include a tube like structure with cross sections in the shapes of ellipses or polygons such as octagons, or rectangles.
- the debris conduit 142 may include cross sections which differ in shape and size at different points.
- the debris conduit 142 may, for example, include a venturi type shape.
- tabs 146 are attached to, and spaced around the debris conduit end 144 .
- the tabs 146 are angled out from the exterior wall 164 and circumferentially spaced around the circular debris conduit end 142 .
- Each tab 146 includes an adjacent edge 162 adjacent the debris conduit end 144 , and at least three outer edges 160 angled out from the exterior wall 164 of the debris conduit 142 .
- the outer edges 160 form at least two corners 161 .
- tabs 146 are circumferentially evenly spaced around the debris conduit end 144 . In alternative embodiments, different numbers of tabs 146 may be evenly, or unevenly, spaced around the debris conduit end 144 . There may be, for example, as few as one tab 146 , or as many as eight tabs 146 .
- the number of tabs 146 , the shape of tabs 146 , the size of tabs 146 , and the orientation of the tabs in relation to the debris conduit 142 may be determined as a function of a number of factors. Non-limiting examples of factors to be considered include estimates of the range of velocities and temperatures, the velocity profile, and the range of other characteristics of the flow of the first gas.
- Other examples may include the geometry of the debris conduit 142 , the debris conduit end 144 , the debris chamber 133 , the air inlet 114 , and the filter 116 ; the possible characteristics of the second gas; and the size and configuration of the air outlet stack 112 .
- the tabs 146 include an inner surface 176 and an outer surface 178 .
- the tabs may be held stationery such that the first gas flows over the outer surface 178 and around the outer edges 160 and corners 162 ; and the second gas flows over the inner surface 176 and around the outer edges 160 and corners 162 ; in any manner known in the art.
- the tabs 146 are fixedly attached to the debris conduit end 144 such that the adjacent edge 162 is adjacent the debris conduit end 144 .
- the tabs 146 may, for example, be welded onto the exterior wall 164 or interior wall 174 of the debris conduit 142 with attachment portions 168 as shown and explained in relation to FIGS. 5 and 6 .
- the tabs 146 may be formed integral to the debris conduit 142 .
- the tabs 146 may be fixedly attached to the debris conduit end 144 with a one or more bolts (not shown), snap ring (not shown), clamp arrangement (not shown), and/or adhesives.
- the tabs 146 may be fixedly attached to the debris conduit 142 such that the adjacent edge 162 is adjacent the debris conduit end 144 in any way known in the art. It is also contemplated that in some embodiments, the tabs 146 may be fixedly attached to another component(s) different than the debris conduit 142 , and held stationary against the debris conduit 142 , such that the adjacent edges 162 are adjacent the debris conduit end 144 .
- the aftertreatment 118 , muffler 119 , exhaust pipe 136 , and/or debris conduit 142 may be at least partially enclosed by a housing (not shown).
- the tabs 146 may be fixedly attached to the housing by, for example, brackets, such that the adjacent edges 162 are adjacent the debris conduit end 144 .
- the tabs 146 may be fixedly attached to another component(s) different than the debris conduit 142 , but not adjacent the debris conduit end 144 , such that the first gas flows over the outer surface 178 and around the outer edges 160 and corners 162 , and the second gas flows over the inner surface 176 and around the outer edges 160 and corners 162 .
- each tab 146 is substantially flat.
- the adjacent edge 162 and outer edges 160 form the outline of the inner surface 176 and the outer surface 178 .
- Both the inner surface 176 and the outer surface 178 are generally planar.
- the tabs 146 may be curved as opposed to flat.
- each tab 146 is a generally a trapezoidal shape with a semi-circular adjacent edge 162 , and three outer edges 160 .
- the debris conduit end 144 includes a diameter (indicated by “D”).
- Each tab 146 includes a tab width (indicated by “W”), a tab length (indicated by “L”), and a trapezoid angle (indicated by “ ⁇ ”).
- the tab width (W) is approximately three tenths (0.3) of the debris conduit end 144 diameter, (D), the tab length (L) is between eight tenths (0.8) to one and two tenths (1.2) the tab width (W), and the trapezoidal angle ( ⁇ ) is between eight (8) and twelve (12) degrees.
- a plane perpendicular to the exterior wall 164 of the debris conduit 142 (indicated by “P”) and the tab 146 define a conduit-tab angle (indicated by “ ⁇ ”).
- the conduit-tab angle ( ⁇ ) is between twenty and eighty degrees (20°-80°).
- each tab 146 is generally the same size and shape, and adjacent the debris conduit end 144 at the same conduit-tab angle ( ⁇ ). In alternative embodiments, the tabs 146 may be different shapes and sizes, and adjacent the debris conduit end 144 at different conduit-tab angles ( ⁇ ).
- each figure illustrates an exemplary embodiment of a tab assembly 166 , 266 .
- the tab assembly 166 , 266 includes one of the tabs 146 and a tab attachment piece 168 , 268 for attaching the tab 146 to the debris conduit 142 .
- the tab attachment piece 168 , 268 includes a first side 170 and a second side 172 (not shown on FIG. 6 ).
- the tab 146 may be attached to the debris conduit end 144 by attaching the first side 170 to the debris conduit interior wall 174 such that the adjacent edge 162 of the tab is adjacent to the debris conduit end 144 .
- the tab 146 may be attached to the debris conduit end 144 by attaching the second side 172 to the debris conduit exterior wall 164 such that the adjacent edge 162 of the tab is adjacent to the debris conduit end 144 .
- the tab assembly 166 , 266 may be fixedly attached to the debris conduit 142 through welding, adhesive, clamps, snap rings, bolts, or any other means known in the art.
- the tab 146 and the tab attachment piece 268 may be formed as one integral piece through molding or from bending and shaping sheet metal. In other embodiments, the tab 146 and the tab attachment piece 168 , 268 may be welded together, riveted together, bolted together or fixedly attached together by any means known in the art.
- FIG. 5 illustrates a tab assembly 166 formed to be attached to the debris conduit 142 .
- FIG. 6 illustrates an embodiment of a tab assembly 266 including a generally flat piece of metal. This embodiment may be bent and shaped to attach to debris conduit 142 .
- FIG. 7 illustrates another exemplary embodiment of a tab 146 .
- the tab 146 in FIG. 7 is similar to the embodiments of the tab 146 illustrated and described in relation to FIGS. 3 and 4 , except tab 146 in this embodiment includes a sawtooth end 380 .
- the sawtooth end instead of three outer edges 160 (as shown in relation to FIGS. 3 and 4 ), tab 146 includes six outer edges 360 ; and instead of two corners 161 (as shown in relation to FIGS. 3 and 4 ), tab 146 includes five corners 361 .
- Air filtration systems to remove debris and dust from air entering or having contact with components of a machine may include a debris chamber to trap larger pieces of debris.
- the debris chamber may be fluidly connected, through a debris conduit, to a flow of gas from an exhaust pipe, to create a low pressure area and a flow of air through the debris conduit from a higher pressure area, to draw the debris out of the chamber, and expel it outside the machine. In some operating conditions, the flow created may not be sufficient to remove enough debris from the chamber.
- Tabs at the end of the debris conduit may create vortex flow between the gas being drawn through the debris conduit and the gas flowing from the exhaust pipe. This vortex flow may enhance the mixing of the two gases and increase the velocity of the gas flowing through the debris conduit, and increase the amount of debris removed from the chamber. Experimentation, modeling, and simulation have indicated that the tab can increase the vortex flow and thus the amount of debris removed from the debris chamber.
- the method 200 includes directing the flow of the first gas through the exhaust pipe 136 ; directing the flow of the first gas over the outer surface 178 , and around at least three outer edges 160 , and two corners 161 formed by the at least three outer edges 160 , of a tab 146 ; and directing the flow of the first gas through an air outlet 110 .
- the method 200 further includes directing the flow of the second gas through the debris chamber 133 and the debris conduit 142 ; and directing the flow of the second gas over the inner surface 176 , and around the at least three outer edges 160 , and two corners 161 formed by the three outer edges 160 of the tab 146 .
- the method 200 includes creating vortex flow between the first gas and the second gas; and drawing debris out of the debris chamber 133 , through the debris conduit 142 , and through the air outlet stack 112 .
- the method 200 starts at step 202 and proceeds to step 204 .
- step 204 the flow of the first gas is directed through the exhaust pipe 136 .
- the flow of the first gas includes a heated gas, and more specifically exhaust gas from the engine 118 .
- the exhaust gas flows from the engine 118 , through one or more aftertreatment devices 154 , through one or more sound suppression devices 156 , through the exhaust pipe 136 , through the venturi portion 140 , out the exhaust pipe end 138 , into the air outlet stack 112 , and out the air outlet stack 112 .
- the flow of the first gas may narrow as it passes through the neck portion 141 of the venturi portion 140 and increase in velocity. As the flow of the first gas may widen as it exits the neck portion 141 .
- the first gas may include gas from other sources in other embodiments.
- the method 200 proceeds to step 206 .
- the flow of the first gas is directed over the outer surface 178 of a tab 146 , and over at least three outer edges 160 and two corners 161 formed by the outer edges 160 of the tab 146 .
- multiple tabs 146 are attached to, and angled out from, the debris conduit end 144 .
- the debris conduit end 144 is disposed in the exhaust pipe interior 137 .
- the tabs 146 may be fixed in the flow of the first gas in other ways and locations.
- a portion of the debris conduit 142 may extend through the exhaust pipe 136 and extend into the air outlet stack 112 , such that although the debris conduit end 144 is not disposed in the exhaust pipe interior 137 , the debris conduit end 144 is disposed in the flow of the first gas in the air outlet stack 112 .
- the multiple tabs 146 may not be fixedly attached to the debris conduit end 144 , but rather fixed in another manner in the flow of the first gas. The method 200 proceeds to step 208 .
- step 208 the first gas is directed through the air outlet 110 .
- the air outlet 110 includes the air outlet stack 112 .
- the method proceeds to step 210 .
- the flow of the second gas flows through the debris conduit 142 .
- the second gas includes air from outside the compartment 108 , a portion of which is filtered through the air filtration system 116 and directed into the intake manifold 150 of the engine 118 . Another portion of the second gas flows through the debris chamber 133 , and through the debris conduit 142 .
- the air filtration system 116 includes a pre-cleaner 119
- the debris chamber 133 includes a collection area 134 of the pre-cleaner.
- the debris chamber 133 may not be an element of the air filtration system 116 , and the debris may not have been filtered from the second gas.
- the debris may be ash created as a result of some type of combustion in a chamber.
- Ducts and valves may be actuated to permit the flow of the second gas through the chamber with the ash and through the debris conduit 142 .
- the flow of the first gas around the debris conduit end may create a low pressure area proximate the debris conduit end. In the depicted embodiment, the low pressure area may be above the debris conduit end.
- the flow of the second gas outside the compartment 108 may be at a higher pressure than the low pressure area proximate the debris conduit end 144 .
- a flow of the second gas may be created by the pressure differential through the collection area 134 , and the debris conduit.
- the method 200 proceeds to step 212 .
- step 212 the flow of the second gas passes over the inner surface 176 of the multiple tabs 146 , and over and around the outer edges 160 and corners 161 .
- the flow of the second gas disperses as it exits the debris conduit end 144 .
- the flow of the second gas passes over the inner surface 176 , and around the outer edges 160 and corners 161 .
- the method 200 proceeds to step 214 .
- step 214 vortex flow 184 is created between the first gas and the second gas.
- FIG. 9 a cross section 182 of gas flow at the end of the exhaust pipe 138 is depicted for the embodiment of FIG. 2 .
- the vortex flow 184 is created between the first gas and the second gas.
- the vortex flow 184 may be increased.
- Vortex flow 184 may, in turn, increase the mixing of the first gas and the second gas, and thus the velocity of the flow of the second gas through the collection area 134 and the debris conduit 142 .
- the method 200 proceeds to step 216 .
- step 216 debris is drawn through the debris conduit 142 and expelled out the air outlet 110 .
- flow of air from outside the compartment 108 may be created through the collection area 134 and debris conduit 142 .
- This flow may be strong enough to draw debris from the collection area 134 , through the debris conduit 142 , and out the air outlet stack 112 .
- this flow may not be strong enough to draw all debris out of the collection area 134 .
- Creating vortex flow as the first gas and the second gas meet at the corners 161 of the tabs 146 increases the mixing of the first gas and the second gas and thus the velocity of the second gas. Increasing the velocity of the second gas may increase the amount of debris drawn out of the debris chamber 133 .
- the method 200 proceeds to step 218 and ends.
Abstract
A system to remove debris from a chamber includes a debris chamber, an exhaust pipe, a debris conduit, and a tab. The exhaust pipe may direct a flow of gas into an air outlet, and include an exhaust pipe interior. The debris conduit connects the chamber with at least one of the exhaust pipe interior and the air outlet, and includes a debris conduit end disposed in at least one of the exhaust pipe interior and the air outlet. The tab includes at least three outer edges forming at least two corners, and an adjacent edge. The adjacent edge is adjacent to the debris conduit end.
Description
- The present disclosure relates generally to debris removal systems. Specifically, an embodiment of the present invention relates to a debris removal system for removing debris from a chamber.
- Some components of machines can be damaged if dust or debris come in contact with or enter the component. For example, if dust enters an intake manifold of an engine, it may damage the combustion cylinders. Often machines working in dusty, or debris filled environments are equipped with air filtration systems. The air filtration systems protect sensitive components by removing dust and/or debris from air entering or having contact with the components.
- Some filtration systems trap larger debris in a debris chamber and then filter the remaining air. The chamber may be fluidly connected with an air outlet through an exhaust pipe which may draw the debris out of the chamber and expel it through the air outlet into the air surrounding the machine. U.S. Pat. No. 7,004,987 issued to Pikesh et al., discloses a pre-cleaner for an air induction system of an internal combustion engine including a housing enclosing an upper chamber and an aspirator port chamber. The upper chamber contains a plurality of particulate separator tubes arranged in a predetermined array. Each of the tubes includes a particulate outlet through which particles removed from air flowing through the tube en route to the engine are discharged. The aspirator port chamber is located beneath, and is upwardly open to, the particulate outlets and includes an upwardly facing particle collecting surface located directly beneath the particulate outlets. Particles can fall from the tubes into the aspirator port chamber and onto the upwardly facing particle collecting surface. The housing includes a generally horizontally facing aspirator port in the aspirator port chamber adjacent to and facing the particle collecting surface. The housing also includes an element disposed for connecting the aspirator port to an exhaust tract of the internal combustion engine such that the exhaust flow through the exhaust tract will generate a suction condition in the aspirator port when the engine is operated. The particle collecting surface is positioned and oriented such that the suction generated by the exhaust flow during the operation of the engine will draw a flow of air from the upper chamber across the particle collecting surface such that particles collected on the surface will be drawn in an at least generally horizontal direction into the aspirator port.
- In some operating conditions, airflow created through a pre-cleaner by a flow of gas through an exhaust pipe and an air outlet, to draw debris out of a debris chamber, through a debris conduit, and through the air outlet may not be sufficient to remove enough debris from the chamber.
- Disclosed is a system to remove debris from a chamber including a debris chamber, an exhaust pipe, a debris conduit, an air outlet, and a tab. The exhaust pipe directs a flow of gas into the air outlet and includes an exhaust pipe interior. The debris conduit connects the chamber with at least one of the exhaust pipe interior and the air outlet and includes a debris conduit end disposed in at least one of the exhaust pipe interior and the air outlet. The tab has at least three outer edges forming at least two outer corners, and an adjacent edge, the adjacent edge adjacent to the debris conduit end.
- In another aspect, disclosed is a machine including a body, an air filtration system, an exhaust pipe, an engine, a debris conduit, and a tab. The body defines a compartment with an air inlet and an air outlet. The air filtration system includes a pre-cleaner with a debris collection area disposed, the pre-cleaner configured to filter and trap debris in the debris collection area. The air filtration system is disposed in the air inlet. An air outlet stack is disposed in the air outlet. The exhaust pipe directs exhaust gas into and out of the air outlet, and includes an interior and an exhaust pipe end having a venturi portion. The engine is disposed in the compartment and is configured to exhaust gases through the exhaust pipe. The engine includes an intake manifold fluidly connected to the air inlet through the air filtration system. The debris conduit connects the debris collection area with at least one of the interior of the exhaust pipe and the air outlet, and includes a debris conduit end. The debris conduit end is disposed in at least one of the interior of the exhaust pipe and the air outlet. The debris conduit is configured for directing debris from the debris chamber through and out of at least one of the exhaust pipe and the air outlet. The tab, with at least three outer edges forming at least two outer corners and an adjacent edge, is adjacent to the debris conduit end.
- In another aspect disclosed is a method for removing debris from a debris chamber. The method includes directing a first gas through an exhaust pipe; over an outer surface, and around at least three outer edges, and two corners formed by the at least three outer edges of a tab; and through an air outlet. The method further includes flowing a second gas through the debris chamber and a debris conduit; and over an inner surface, and around the at least three outer edges, and two corners formed by the three outer edges of the tab. Additionally, the method includes creating vortex flow between the first gas and the second gas, and drawing debris out of the debris chamber, through the debris conduit, and through the air outlet.
-
FIG. 1 depicts an exemplary machine including an embodiment of a debris removal system. -
FIG. 2 schematically depicts an exemplary debris removal system. -
FIG. 3 depicts a portion of an exemplary tab. -
FIG. 4 depicts a portion of an exemplary debris conduit from a perspective. -
FIG. 5 depicts an embodiment of an exemplary tab assembly. -
FIG. 6 depicts another embodiment of an exemplary tab assembly. -
FIG. 7 depicts another embodiment of a tab. -
FIG. 8 is a flow chart of an exemplary debris removal method. -
FIG. 9 schematically depicts an embodiment of a portion of a debris conduit disposed in the interior of an exhaust pipe with a cross section depicting vortex flow. - Reference will now be made in detail to specific embodiments or features, examples of which are illustrated in the accompanying drawings. Generally, corresponding or similar reference numbers will be used, when possible, throughout the drawings to refer to the same or corresponding parts. Elements in schematics, included in the drawings, and described herein, may not be drawn with dimensions or in relation to other elements to any realistic scale. But, may rather be drawn to illustrate different aspects of the disclosure.
- Referring now to
FIG. 1 , anexemplary machine 100 is illustrated. In the embodiment depicted, themachine 100 is avehicle 102, and in particular awheel loader 104. Thevehicle 102 may perform a type of operation associated with a particular industry such as mining, construction, farming, transportation, etc. and operates between or within work environments (e.g. construction site, mine site, power plants, on-highway applications, marine applications, etc.). Non-limiting examples ofvehicle 104 include cranes, earthmoving vehicles, mining vehicles, backhoes, excavators, material handling equipment, dredgers, and farming equipment. In other embodiments,machine 100 may include a stationary machine, such as an electric power generator or a pumping station for oil or gas (not shown). - The
wheel loader 104 includes abody 106 which defines acompartment 108 including anair outlet 110, and anair inlet 114. The air outlet includes anair outlet stack 112. Theair inlet 114 includes anair filtration system 116, with a debris chamber 133 (shown in relation toFIG. 2 ). The air filtration system may also include arain cap 115, pre-cleaner 119, and air filter 121 (shown in relation toFIG. 2 ). The pre-cleaner 119 may include thedebris chamber 133 in the form of a debris collection area 134 (shown in relation toFIG. 2 ). - The
wheel loader 104 includes apower source 117. In the illustrated embodiment, thepower source 117 includes anengine 118 disposed in thecompartment 108. Theengine 118 may include an internal combustion engine. Thewheel loader 104 is equipped with systems that facilitate the operation of thewheel loader 104 at aworksite 126. In the illustrated embodiment, these systems include a work implementsystem 124, and adrive system 120, both of which are powered by theengine 118. Thedrive system 120 propels thewheel loader 104 on ground engaging devices 122 (depicted as wheels) to move thewheel loader 104 from one location to another. The work implementsystem 124 includes abucket 128 and actuators andlinkages 130 to move thebucket 128 to perform work at theworksite 126.Wheel loader 104 includes an embodiment of adebris removal system 132, depicted inFIG. 2 . - Referring now to
FIG. 2 , adebris removal system 132 is depicted. Thedebris removal system 132 includes adebris chamber 133, anexhaust pipe 136, adebris conduit 142, and atab 146. In the embodiment illustrated,exhaust pipe 136 directs the flow of a first gas into anair outlet 110 and includes anexhaust pipe interior 137. A flow of the first gas is illustrated inFIG. 2 with the arrows labeled “1”. Thedebris conduit 142 connects thedebris chamber 133 with at least one of theexhaust pipe interior 137 and theair outlet 110, and includes a debris conduit end 144 disposed in at least one of theexhaust pipe interior 137 and theair outlet 110. Thedebris conduit 142 is configured to direct debris from thedebris chamber 133 into at least one of theexhaust pipe 136 and theair outlet 110. Atab 146 is adjacent thedebris conduit end 144. - In the illustrated embodiment, the
system 132 includes ahousing 148 which defines thecompartment 108, theair outlet 110, and anair inlet 114. Thedebris chamber 133,debris conduit 142, and at least a portion of theexhaust pipe 136 may be substantially enclosed by thehousing 148. Thedebris chamber 133 may include any substantially enclosed space or cavity for collecting dust and/or debris. The debris may include tiny pieces of rock, mud, seeds, chaff, ash, or other substances which may become airborne. In the illustrated embodiment, thedebris chamber 133 includes adebris collection area 134 which is contained in, and is an element of, theprecleaner 119. A flow of a second gas is illustrated inFIG. 2 with the arrows labeled “2”. Larger pieces of debris and dust, airborne in the second gas flowing through theair filtration system 116, are trapped in thecollection area 134 of the pre-cleaner 119. The second gas, devoid of these larger pieces of debris, is then passed through theair filter 121. A non-limiting example of an embodiment ofair filtration system 116 includes the Donaldson STB Strata™ Air Cleaner including the Donaspin™ Pre-Cleaner. The second gas may include air from outside the compartment. For example, in the embodiment illustrated inFIG. 1 , the second gas may include air from theworksite 126 surrounding themachine 100. Although shown as an element of theair filtration system 116, thedebris chamber 133 may include embodiments where additional filtering elements are not necessary, or embodiments in which thedebris chamber 133 is not a component of theair filtration system 116. - In the embodiment illustrated, the
engine 118 includes anair intake manifold 150 fluidly connecting theengine 118 to the outside of thecompartment 108 through theair filtration system 116. A portion of the second gas flowing through theair inlet 114 may flow through the pre-cleaner 119 and theair filter 121 and into theintake manifold 150. The pre-cleaner 119 may remove larger pieces of debris from the second gas by trapping them in thecollection area 134, and then remove additional dust and smaller debris particles through theair filter 121, before the second gas is allowed to flow into theintake manifold 150. Another portion of the second gas flowing through theinlet 114 may flow through thecollection area 134 of the pre-cleaner 119 and then into thedebris conduit 142. - The flow of the first gas from the
exhaust pipe 136 may include a flow of heated gas, for example, a flow of heated exhaust gas from theengine 118. In the illustrated embodiment, theexhaust pipe 136 fluidly connects theengine 118, with theair outlet 110 to expel exhaust gas. The exhaust gas from theengine 118 may flow through one or moreaftertreatment devices 154, and through one or moresound suppression devices 156, before flowing into theexhaust pipe 136 and then through theair outlet 110. Althoughengine 118 is depicted disposed in thecompartment 108, in other embodiments,engine 118 may be located outside or only partially disposed in thecompartment 108. Althoughengine 118 exhausts the flow of the first gas in the illustrated embodiment, in other embodiments the flow of the first gas may originate and be directed through theexhaust pipe 136 by other devices or processes known in the art. For example, a turbine may exhaust the flow of the first gas into theexhaust pipe 136, or a manufacturing process may create heat and a series of fans, air conduits, and/or valves may direct the flow of the first gas through theexhaust pipe 136. - In the depicted embodiment, the
exhaust pipe 136 includes anexhaust pipe end 138 including aventuri portion 140. Theventuri portion 140 includes aneck portion 141 providing a restriction such that the velocity of the flow of the first gas is increased upon exiting theneck portion 141, as is known in the art. - In the depicted embodiment, the
debris conduit 142 connects thedebris chamber 133 to theexhaust pipe interior 137. In one embodiment, a portion of thedebris conduit 142 including the debris conduit end 144 may be inserted into theexhaust pipe interior 137 through an aperture in the wall of theexhaust pipe 136. In other embodiments thedebris conduit 142 or a portion of thedebris conduit 142, and theexhaust pipe 136 or a portion of theexhaust pipe 136 may be manufactured as a single component. Thedebris conduit 142 and the debris conduit end 144 are positioned in relation to theexhaust pipe 136, such that debris from thedebris chamber 133 is directed into at least one of theexhaust pipe 136 and theair outlet 110. In the depicted embodiment, theair outlet 110 includes theair outlet stack 112. Theexhaust pipe end 138 and debris conduit end 144 are positioned in theair outlet stack 112 such that the flow of the first gas from theexhaust pipe 136 into theair outlet stack 112 creates a low pressure area proximate thedebris conduit end 144. In the depicted embodiment, the low pressure area may be created above thedebris conduit end 144. The second gas from outside thecompartment 108, entering thecompartment 108 through theair filtration system 116, may be at a higher pressure than the low pressure area created proximate thedebris conduit end 144. The second gas may flow from the higher pressure area outside the compartment, through thecollection area 134, and through thedebris conduit 142. The second gas may carry dust and/or debris from thecollection area 134, through thedebris conduit 142, through theoutlet stack 112, and out of thecompartment 108. - In the embodiment illustrated, the
housing 148 defines anaperture 158 fluidly connecting thecompartment 108 with air outside thehousing 148. A flow of a third gas is illustrated inFIG. 2 with the arrows labeled “3”. The third gas may flow in theaperture 158, through thecompartment 108, and out theair outlet 110. Heat energy may transfer from theengine 118,aftertreatment devices 154,sound suppression devices 156, and/or other components in thecompartment 108 to the third gas to cool these components. The flow of the first gas through theexhaust pipe 136 and out theair outlet 110 may increase the velocity of the flow of the third gas through thecompartment 108, as is known in the art. The increased velocity of the third gas may provide improved cooling of the components in thecompartment 108. Although oneaperture 158 is shown in the embodiment ofFIG. 2 , many embodiments ofcompartments 108, such as those defined by amachine body 106, may havemultiple apertures 158. Theapertures 158 may include vents, cracks, or an open side of thecompartment 108. The third gas is drawn through theseapertures 158, through thecompartment 108, and through theair outlet 110. - Referring now to
FIGS. 3 and 4 , a perspective view of a portion of an exemplary embodiment of thedebris conduit 142, includingdebris conduit end 144, havingmultiple tabs 146; and a view of anexemplary tab 146 are illustrated.Debris conduit 142 includesdebris conduit end 144. Although the debris conduit end 144 is illustrated with four tabs, it is contemplated that there may be embodiments with one, two, three, or more than fourtabs 146. In the embodiment illustrated, debris conduit end 144 includes a circle shape with a diameter marked as “D” inFIG. 4 . In other embodiments the debris conduit end 144 may include other shapes, for example an ellipse, an octagon, a square, or any other shape known in the art. - In the illustrated embodiment, the
debris conduit 142 includes anexterior wall 164 and aninterior wall 174. In the illustrated embodiment,debris conduit 142 is substantially cylindrical. In alternative embodiments, thedebris conduit 142 may be any elongated tube type shape known in the art to be operable to fluidly connect thedebris chamber 133 with one of the interior of theexhaust stack 136 and theair outlet 110. Non-limiting examples include a tube like structure with cross sections in the shapes of ellipses or polygons such as octagons, or rectangles. In some embodiments, thedebris conduit 142 may include cross sections which differ in shape and size at different points. Thedebris conduit 142 may, for example, include a venturi type shape. -
Multiple tabs 146 are attached to, and spaced around thedebris conduit end 144. In the illustrated embodiment, thetabs 146 are angled out from theexterior wall 164 and circumferentially spaced around the circulardebris conduit end 142. Eachtab 146 includes anadjacent edge 162 adjacent thedebris conduit end 144, and at least threeouter edges 160 angled out from theexterior wall 164 of thedebris conduit 142. Theouter edges 160 form at least twocorners 161. - In the illustrated embodiment four
tabs 146 are circumferentially evenly spaced around thedebris conduit end 144. In alternative embodiments, different numbers oftabs 146 may be evenly, or unevenly, spaced around thedebris conduit end 144. There may be, for example, as few as onetab 146, or as many as eighttabs 146. The number oftabs 146, the shape oftabs 146, the size oftabs 146, and the orientation of the tabs in relation to thedebris conduit 142 may be determined as a function of a number of factors. Non-limiting examples of factors to be considered include estimates of the range of velocities and temperatures, the velocity profile, and the range of other characteristics of the flow of the first gas. Other examples may include the geometry of thedebris conduit 142, thedebris conduit end 144, thedebris chamber 133, theair inlet 114, and thefilter 116; the possible characteristics of the second gas; and the size and configuration of theair outlet stack 112. - The
tabs 146 include aninner surface 176 and anouter surface 178. The tabs may be held stationery such that the first gas flows over theouter surface 178 and around theouter edges 160 andcorners 162; and the second gas flows over theinner surface 176 and around theouter edges 160 andcorners 162; in any manner known in the art. - In the illustrated embodiment, the
tabs 146 are fixedly attached to the debris conduit end 144 such that theadjacent edge 162 is adjacent thedebris conduit end 144. Thetabs 146 may, for example, be welded onto theexterior wall 164 orinterior wall 174 of thedebris conduit 142 withattachment portions 168 as shown and explained in relation toFIGS. 5 and 6 . In other embodiments thetabs 146 may be formed integral to thedebris conduit 142. In still other embodiments, thetabs 146 may be fixedly attached to the debris conduit end 144 with a one or more bolts (not shown), snap ring (not shown), clamp arrangement (not shown), and/or adhesives. Thetabs 146 may be fixedly attached to thedebris conduit 142 such that theadjacent edge 162 is adjacent the debris conduit end 144 in any way known in the art. It is also contemplated that in some embodiments, thetabs 146 may be fixedly attached to another component(s) different than thedebris conduit 142, and held stationary against thedebris conduit 142, such that theadjacent edges 162 are adjacent thedebris conduit end 144. For example, theaftertreatment 118,muffler 119,exhaust pipe 136, and/ordebris conduit 142 may be at least partially enclosed by a housing (not shown). Thetabs 146 may be fixedly attached to the housing by, for example, brackets, such that theadjacent edges 162 are adjacent thedebris conduit end 144. In still other embodiments, it is contemplated that thetabs 146 may be fixedly attached to another component(s) different than thedebris conduit 142, but not adjacent thedebris conduit end 144, such that the first gas flows over theouter surface 178 and around theouter edges 160 andcorners 162, and the second gas flows over theinner surface 176 and around theouter edges 160 andcorners 162. - In the illustrated embodiment, each
tab 146 is substantially flat. Theadjacent edge 162 andouter edges 160 form the outline of theinner surface 176 and theouter surface 178. Both theinner surface 176 and theouter surface 178 are generally planar. In alternative embodiments, thetabs 146 may be curved as opposed to flat. - In the embodiment illustrated, each
tab 146 is a generally a trapezoidal shape with a semi-circularadjacent edge 162, and threeouter edges 160. As depicted inFIGS. 4 and 5 , the debris conduit end 144 includes a diameter (indicated by “D”). Eachtab 146 includes a tab width (indicated by “W”), a tab length (indicated by “L”), and a trapezoid angle (indicated by “β”). In some embodiments the tab width (W) is approximately three tenths (0.3) of the debris conduit end 144 diameter, (D), the tab length (L) is between eight tenths (0.8) to one and two tenths (1.2) the tab width (W), and the trapezoidal angle (β) is between eight (8) and twelve (12) degrees. In the illustrated embodiment ofFIG. 4 , a plane perpendicular to theexterior wall 164 of the debris conduit 142 (indicated by “P”) and thetab 146 define a conduit-tab angle (indicated by “α”). In some embodiments, the conduit-tab angle (α) is between twenty and eighty degrees (20°-80°). - In the embodiment illustrated, each
tab 146 is generally the same size and shape, and adjacent the debris conduit end 144 at the same conduit-tab angle (α). In alternative embodiments, thetabs 146 may be different shapes and sizes, and adjacent the debris conduit end 144 at different conduit-tab angles (α). - Referring now to
FIGS. 5 and 6 , each figure illustrates an exemplary embodiment of atab assembly tab assembly tabs 146 and atab attachment piece tab 146 to thedebris conduit 142. Thetab attachment piece first side 170 and a second side 172 (not shown onFIG. 6 ). In one embodiment, thetab 146 may be attached to the debris conduit end 144 by attaching thefirst side 170 to the debris conduitinterior wall 174 such that theadjacent edge 162 of the tab is adjacent to thedebris conduit end 144. In another embodiment, thetab 146 may be attached to the debris conduit end 144 by attaching thesecond side 172 to the debris conduitexterior wall 164 such that theadjacent edge 162 of the tab is adjacent to thedebris conduit end 144. Thetab assembly debris conduit 142 through welding, adhesive, clamps, snap rings, bolts, or any other means known in the art. - In one embodiment of the
tab assembly tab 146 and thetab attachment piece 268 may be formed as one integral piece through molding or from bending and shaping sheet metal. In other embodiments, thetab 146 and thetab attachment piece -
FIG. 5 illustrates atab assembly 166 formed to be attached to thedebris conduit 142.FIG. 6 illustrates an embodiment of atab assembly 266 including a generally flat piece of metal. This embodiment may be bent and shaped to attach todebris conduit 142. -
FIG. 7 illustrates another exemplary embodiment of atab 146. Thetab 146 inFIG. 7 is similar to the embodiments of thetab 146 illustrated and described in relation toFIGS. 3 and 4 , excepttab 146 in this embodiment includes asawtooth end 380. With the sawtooth end, instead of three outer edges 160 (as shown in relation toFIGS. 3 and 4 ),tab 146 includes sixouter edges 360; and instead of two corners 161 (as shown in relation toFIGS. 3 and 4 ),tab 146 includes fivecorners 361. - Air filtration systems to remove debris and dust from air entering or having contact with components of a machine may include a debris chamber to trap larger pieces of debris. The debris chamber may be fluidly connected, through a debris conduit, to a flow of gas from an exhaust pipe, to create a low pressure area and a flow of air through the debris conduit from a higher pressure area, to draw the debris out of the chamber, and expel it outside the machine. In some operating conditions, the flow created may not be sufficient to remove enough debris from the chamber. Tabs at the end of the debris conduit may create vortex flow between the gas being drawn through the debris conduit and the gas flowing from the exhaust pipe. This vortex flow may enhance the mixing of the two gases and increase the velocity of the gas flowing through the debris conduit, and increase the amount of debris removed from the chamber. Experimentation, modeling, and simulation have indicated that the tab can increase the vortex flow and thus the amount of debris removed from the debris chamber.
- Referring now to
FIG. 8 , a flow chart is shown depicting amethod 200 for removing debris from a debris chamber. Themethod 200 includes directing the flow of the first gas through theexhaust pipe 136; directing the flow of the first gas over theouter surface 178, and around at least threeouter edges 160, and twocorners 161 formed by the at least threeouter edges 160, of atab 146; and directing the flow of the first gas through anair outlet 110. Themethod 200 further includes directing the flow of the second gas through thedebris chamber 133 and thedebris conduit 142; and directing the flow of the second gas over theinner surface 176, and around the at least threeouter edges 160, and twocorners 161 formed by the threeouter edges 160 of thetab 146. Additionally themethod 200 includes creating vortex flow between the first gas and the second gas; and drawing debris out of thedebris chamber 133, through thedebris conduit 142, and through theair outlet stack 112. - The
method 200 starts atstep 202 and proceeds to step 204. Instep 204, the flow of the first gas is directed through theexhaust pipe 136. In the embodiment depicted inFIG. 2 , the flow of the first gas includes a heated gas, and more specifically exhaust gas from theengine 118. The exhaust gas flows from theengine 118, through one or moreaftertreatment devices 154, through one or moresound suppression devices 156, through theexhaust pipe 136, through theventuri portion 140, out theexhaust pipe end 138, into theair outlet stack 112, and out theair outlet stack 112. The flow of the first gas may narrow as it passes through theneck portion 141 of theventuri portion 140 and increase in velocity. As the flow of the first gas may widen as it exits theneck portion 141. Although depicted asengine 118 exhaust gas, the first gas may include gas from other sources in other embodiments. Themethod 200 proceeds to step 206. - In
step 206, the flow of the first gas is directed over theouter surface 178 of atab 146, and over at least threeouter edges 160 and twocorners 161 formed by theouter edges 160 of thetab 146. In the embodiment depicted inFIG. 2 ,multiple tabs 146 are attached to, and angled out from, thedebris conduit end 144. The debris conduit end 144 is disposed in theexhaust pipe interior 137. As the exhaust gas from theengine 118 flows around the debris conduit, it flows over theouter surface 178 of thetabs 146, and over and around theouter edges 160 andcorners 161. In other embodiments, thetabs 146 may be fixed in the flow of the first gas in other ways and locations. For example, a portion of thedebris conduit 142 may extend through theexhaust pipe 136 and extend into theair outlet stack 112, such that although the debris conduit end 144 is not disposed in theexhaust pipe interior 137, the debris conduit end 144 is disposed in the flow of the first gas in theair outlet stack 112. In still other embodiments, themultiple tabs 146 may not be fixedly attached to thedebris conduit end 144, but rather fixed in another manner in the flow of the first gas. Themethod 200 proceeds to step 208. - In
step 208, the first gas is directed through theair outlet 110. In the embodiment depicted inFIG. 2 , theair outlet 110 includes theair outlet stack 112. The method proceeds to step 210. - In
step 210, the flow of the second gas flows through thedebris conduit 142. In the embodiment depicted inFIG. 2 , the second gas includes air from outside thecompartment 108, a portion of which is filtered through theair filtration system 116 and directed into theintake manifold 150 of theengine 118. Another portion of the second gas flows through thedebris chamber 133, and through thedebris conduit 142. In the illustrated embodiment, theair filtration system 116 includes a pre-cleaner 119, and thedebris chamber 133 includes acollection area 134 of the pre-cleaner. In other embodiments thedebris chamber 133 may not be an element of theair filtration system 116, and the debris may not have been filtered from the second gas. For example, the debris may be ash created as a result of some type of combustion in a chamber. Ducts and valves may be actuated to permit the flow of the second gas through the chamber with the ash and through thedebris conduit 142. The flow of the first gas around the debris conduit end may create a low pressure area proximate the debris conduit end. In the depicted embodiment, the low pressure area may be above the debris conduit end. The flow of the second gas outside thecompartment 108 may be at a higher pressure than the low pressure area proximate thedebris conduit end 144. A flow of the second gas may be created by the pressure differential through thecollection area 134, and the debris conduit. Themethod 200 proceeds to step 212. - In
step 212, the flow of the second gas passes over theinner surface 176 of themultiple tabs 146, and over and around theouter edges 160 andcorners 161. In the embodiment depicted inFIG. 2 , the flow of the second gas disperses as it exits thedebris conduit end 144. Where atab 146 is fixed, the flow of the second gas passes over theinner surface 176, and around theouter edges 160 andcorners 161. Themethod 200 proceeds to step 214. - In
step 214,vortex flow 184 is created between the first gas and the second gas. Referring now toFIG. 9 , across section 182 of gas flow at the end of theexhaust pipe 138 is depicted for the embodiment ofFIG. 2 . As the two gases meet at thecorners 161 of thetabs 146,vortex flow 184 is created between the first gas and the second gas. Whentabs 146 includemore corners 160, thevortex flow 184 may be increased.Vortex flow 184 may, in turn, increase the mixing of the first gas and the second gas, and thus the velocity of the flow of the second gas through thecollection area 134 and thedebris conduit 142. Referring back now toFIG. 8 , themethod 200 proceeds to step 216. - In
step 216, debris is drawn through thedebris conduit 142 and expelled out theair outlet 110. When heated exhaust gas is directed through the exhaust pipe and in a flow path direction out theair outlet stack 112, flow of air from outside thecompartment 108 may be created through thecollection area 134 anddebris conduit 142. This flow may be strong enough to draw debris from thecollection area 134, through thedebris conduit 142, and out theair outlet stack 112. However, this flow may not be strong enough to draw all debris out of thecollection area 134. Creating vortex flow as the first gas and the second gas meet at thecorners 161 of thetabs 146 increases the mixing of the first gas and the second gas and thus the velocity of the second gas. Increasing the velocity of the second gas may increase the amount of debris drawn out of thedebris chamber 133. Themethod 200 proceeds to step 218 and ends. - It will be appreciated that the foregoing description provides examples of the disclosed system and technique. However, it is contemplated that other implementations of the disclosure may differ in detail from the foregoing examples. All references to the disclosure or examples thereof are intended to reference the particular example being discussed at that point and are not intended to imply any limitation as to the scope of the disclosure more generally. All language of distinction and disparagement with respect to certain features is intended to indicate a lack of preference for those features, but not to exclude such from the scope of the disclosure entirely unless otherwise indicated.
Claims (24)
1. A system to remove debris from a chamber, comprising:
a debris chamber,
an exhaust pipe for directing a flow of gas into an air outlet, the exhaust pipe including an exhaust pipe interior,
a debris conduit connecting the chamber with at least one of the exhaust pipe interior and the air outlet, the debris conduit including a debris conduit end disposed in at least one of the exhaust pipe interior and the air outlet, and
a tab with at least three outer edges forming at least two corners, and an adjacent edge, the adjacent edge adjacent to the debris conduit end.
2. The system of claim 1 , further including multiple tabs.
3. The system of claim 1 , wherein the tab has a trapezoid shape formed by three outer edges and a connecting edge.
4. The system of claim 3 , wherein the trapezoid shape includes a tapering angle of at least eight degrees.
5. The system of claim 3 , wherein the trapezoid shape includes a tapering angle of no more than twelve degrees.
6. The system of claim 1 , wherein at the tab includes an outer surface, the debris conduit includes an exterior wall, and a plane perpendicular to the exterior wall forms a conduit-tab angle with the outer surface of at least twenty degrees.
7. The system of claim 1 , wherein the tab includes an outer surface, the debris conduit includes an exterior wall, and a plane perpendicular to the exterior wall forms a conduit-tab angle with the outer surface of no more than eighty degrees.
8. The system of claim 1 , wherein the tab is fixedly attached to the debris conduit end.
9. The system of claim 8 , wherein the tab is integral to the debris conduit.
10. The system of claim 8 , wherein the tab is welded onto the debris conduit end.
11. The system of claim 8 , wherein the tab is bolted onto the debris conduit end.
12. The system of claim 1 , wherein the debris conduit end includes a debris conduit diameter, the tab includes a tab width, and the tab width is at least three tenths of the debris conduit diameter.
13. The system of claim 1 , wherein the tab includes a tab width and a tab length, and the tab length is at least eight tenths of the tab width.
14. The system of claim 1 , wherein the tab includes a tab width and a tab length, and the tab length is no more than one and two tenths of the tab width.
15. The system of claim 1 , wherein the debris conduit fluidly connects the debris chamber with the interior of the exhaust pipe.
16. The system of claim 1 , wherein the exhaust pipe includes an exhaust pipe end having a venturi portion with a neck portion, and the debris conduit end is disposed in the neck portion.
17. The system of claim 1 , further including a housing defining a compartment; the housing including an air inlet including an air filtration system configured to filter and trap debris in the debris chamber, and the air outlet having an air outlet stack.
18. The system of claim 17 , further including an engine disposed in the compartment with an intake manifold and configured to exhaust gases through the exhaust pipe, and wherein the air inlet is fluidly connected to the intake manifold through the air filtration system.
19. A machine, comprising
a body defining a compartment; and including an air inlet and an air outlet,
an air filtration system including a pre-cleaner with a debris collection area disposed in the air inlet, the pre-cleaner configured to filter and trap debris in the debris collection area,
an air outlet stack disposed in the air outlet,
an exhaust pipe for directing exhaust gas into and out of the air outlet, the exhaust pipe including an interior and an exhaust pipe end having a venturi portion,
an engine disposed in the compartment configured to exhaust gases through the exhaust pipe, and including an intake manifold fluidly connected to the air inlet through the air filtration system,
a debris conduit connecting the debris collection area with at least one of the interior of the exhaust pipe and the air outlet, the debris conduit including a debris conduit end disposed in at least one of the interior of the exhaust pipe and the air outlet, the debris conduit configured for directing debris from the debris collection area through and out of the exhaust pipe and the air outlet, and
a tab with at least three outer edges forming at least two corners, and an adjacent edge, the adjacent edge adjacent the debris conduit end.
20. A method for removing debris from a debris chamber, comprising:
directing a flow of a first gas through an exhaust pipe,
directing the flow of the first gas over an outer surface, and around at least three outer edges, and two corners formed by the at least three outer edges of a tab,
directing the flow of the first gas through an air outlet,
directing a flow of a second gas through the debris chamber and a debris conduit,
directing the flow of the second gas over an inner surface, and around the at least three outer edges, and two corners formed by the three outer edges of the tab,
creating vortex flow between the first gas and the second gas, and
drawing debris out of the debris chamber, through the debris conduit, and through the air outlet.
21. The method of claim 20 , wherein the tab is angled outward from the end of the debris conduit.
22. The method of claim 20 , further including narrowing and increasing the velocity of the flow of the first gas before directing the flow of the first gas over the outer surface of the tab.
23. The method of claim 20 , further including widening the flow of the first gas as or after the flow of the first gas is directed over the outer surface of the tab.
24. The method of claim 20 , further including creating a low pressure area over an end of the debris conduit.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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US13/650,582 US20140102483A1 (en) | 2012-10-12 | 2012-10-12 | System and method to remove debris from a chamber |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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US13/650,582 US20140102483A1 (en) | 2012-10-12 | 2012-10-12 | System and method to remove debris from a chamber |
Publications (1)
Publication Number | Publication Date |
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US20140102483A1 true US20140102483A1 (en) | 2014-04-17 |
Family
ID=50474253
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US13/650,582 Abandoned US20140102483A1 (en) | 2012-10-12 | 2012-10-12 | System and method to remove debris from a chamber |
Country Status (1)
Country | Link |
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US (1) | US20140102483A1 (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9856834B2 (en) | 2015-05-22 | 2018-01-02 | Caterpillar Inc. | Filter pre-cleaner system |
CN109184890A (en) * | 2018-08-31 | 2019-01-11 | 广西柳工机械股份有限公司 | Loading machine engine aftertreatment system |
US10415517B2 (en) * | 2017-12-22 | 2019-09-17 | Caterpillar Inc. | Exhaust scavenging system for an engine system |
US10788000B2 (en) | 2016-03-22 | 2020-09-29 | Cnh Industrial America Llc | System and method for aspirating a pre-cleaner of a work vehicle using a double-walled flow pipe |
Citations (3)
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US4929088A (en) * | 1988-07-27 | 1990-05-29 | Vortab Corporation | Static fluid flow mixing apparatus |
US5800059A (en) * | 1995-05-09 | 1998-09-01 | Labatt Brewing Company Limited | Static fluid flow mixing apparatus |
US20080092533A1 (en) * | 2006-10-20 | 2008-04-24 | Paul Tennison | Exhaust System for an Engine |
-
2012
- 2012-10-12 US US13/650,582 patent/US20140102483A1/en not_active Abandoned
Patent Citations (3)
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US4929088A (en) * | 1988-07-27 | 1990-05-29 | Vortab Corporation | Static fluid flow mixing apparatus |
US5800059A (en) * | 1995-05-09 | 1998-09-01 | Labatt Brewing Company Limited | Static fluid flow mixing apparatus |
US20080092533A1 (en) * | 2006-10-20 | 2008-04-24 | Paul Tennison | Exhaust System for an Engine |
Non-Patent Citations (1)
Title |
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Donaldson Filtration Solutions Engine Intake Systems, 2009. * |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US9856834B2 (en) | 2015-05-22 | 2018-01-02 | Caterpillar Inc. | Filter pre-cleaner system |
US10788000B2 (en) | 2016-03-22 | 2020-09-29 | Cnh Industrial America Llc | System and method for aspirating a pre-cleaner of a work vehicle using a double-walled flow pipe |
US10415517B2 (en) * | 2017-12-22 | 2019-09-17 | Caterpillar Inc. | Exhaust scavenging system for an engine system |
CN109184890A (en) * | 2018-08-31 | 2019-01-11 | 广西柳工机械股份有限公司 | Loading machine engine aftertreatment system |
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Legal Events
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AS | Assignment |
Owner name: CATERPILLAR INC., ILLINOIS Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:HONG, HAIPING;SCOLTON, CHRIS J.;REEL/FRAME:029120/0760 Effective date: 20121011 |
|
STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |