Patent Application
20060086549
This invention relates generally to air intake systems for combustion air for utility vehicles such as tractors, and more specifically to mounting air intake system components in the engine compartment under the front hood of a small tractor.
Packaging space for under-hood components of compact tractors is very limited. Packaged components include the air intake system, exhaust system, fuel supply system, engine cooling system, HVAC system, and electrical system. It is desirable to provide easy access to frequently serviced items in the engine compartment such as the engine air filter, fuel filter, oil level fill and check, coolant water level check, etc. It also would be desirable to perform frequent service activities without special tools, and without having to remove components that are not being serviced.
One such component that requires service is the air intake filter for combustion air. Performance of the air intake system affects the power output of an internal combustion engine. For example, power output may be reduced if the air intake system allows entry of heat and/or moisture into the inlet air during its path through the intake system inside of the engine compartment. Additionally, power output may be reduced if the air intake system permits a pressure drop of the air flow traveling through the intake system. Air intake systems typically have several components and connections that potentially allow entry of heat or moisture, or pressure drops due to air leaks.
There is a need for an air intake system for a compact tractor or similar vehicle that requires less space under the hood. There is a need for an air intake system that helps improve power output of an internal combustion engine by minimizing the entry of heat and/or moisture into the inlet air. There is a need for an air intake system that has fewer components, connectors, and potential leak paths. There is a need for an air intake system that is less costly to assemble and service.
The integrated fan shroud air intake system provides an air passage through the cooling system fan shroud of a compact tractor upstream of the air filter. The air filter is mounted directly to the fan shroud in an alignment transverse to the longitudinal axis of the vehicle. The air filter inlet is plugged directly into the fan shroud. The integrated fan shroud air intake system reduces air filter mounting costs, improves serviceability of the air filter, reduces intake plumbing, reduces heat added to the inlet air, and improves packaging efficiency of the air filter.
In one embodiment, the integrated fan shroud air intake system may be used in a small or compact tractor, but also may be used in other work vehicles such as off-road or mowing vehicles. The integrated fan shroud air intake system receives and filters a sufficient volume of air for fuel combustion in an internal combustion engine. The integrated fan shroud air intake system requires less space under the hood than previous systems, helps improve power output of the internal combustion engine by minimizing the entry of heat and/or moisture into the intake air, and has fewer components, connectors, and potential leak paths than previous air intake systems. Additionally, the integrated fan shroud air intake system is less costly to assemble and service.
In one embodiment, as shown in
In one embodiment, radiator 10 and fan shroud 19 are positioned in front of and adjacent to an internal combustion engine under a tractor hood. The fan shroud has a first face 32 that may be attached or fastened to the radiator, and a second face 33 that faces the engine. The fan shroud may have a generally cylindrical or circular central opening 31 that may surround a cooling fan (not shown) that rotates on a generally longitudinal axis. The fan may be driven by an internal combustion engine, or may be electrically or hydraulically powered, and may have a plurality of blades which rotate to cause air to move through a radiator.
The radiator and fan shroud may have a generally vertical alignment, or may. be at an angle of less than about 30 degrees from vertical. In one embodiment, at least part of the radiator may be aluminum, copper or bronze material, with a releasable radiator cap 18. The fan shroud may be molded or formed from a polymeric material such as glass fiber mineral reinforced, highly chemically coupled polypropylene. The fan shroud may have a nominal material wall thickness of between about 2 mm and about 10 mm, and most preferably about 3.5 mm. Alternatively, the fan shroud may be formed of sheet metal.
In one embodiment, air filter 11 may be mounted to second face 33 of the fan shroud at or near the uppermost edge 51 of the fan shroud. When mounted to the fan shroud, the air filter may be aligned so that the axis of cylindrical housing 39 is transverse to the longitudinal axis of the vehicle. In one embodiment, releasable securing hardware, such as strap 14 and bracket 26, may extend at least partially around the cylindrical housing of the air filter and help secure the housing to the fan shroud. The securing hardware allows the air filter to be easily removed and re-attached manually for replacement, servicing or cleaning.
In one embodiment, passage 30 extends through fan shroud 19 upstream of the air filter. Passage 30 may be positioned at or near the uppermost edge 51 of the fan shroud. At least part of passage 30 may be transverse to the longitudinal axis of the vehicle, providing for a lateral air flow path. Passage 30 extends through the fan shroud and/or may project from one or both faces of the fan shroud. Passage 30 may have a small orifice at the lower surface thereof for removal of entrapped water from the system. In one embodiment, passage 30 may include a plenum having an internal volume of between about 0.01 cubic meters and about 0.1 cubic meters.
In one embodiment, the passage and/or plenum may have an air intake and an outlet. Intake 34 may project from the first face of the fan shroud at or near the uppermost edge of the fan shroud. Outlet 35 may project from the second face of the fan shroud at or near the uppermost edge. Intake 34 may be laterally spaced from outlet 35. For example, intake 34 may be spaced laterally between about 1 cm and about 20 cm from outlet 35. At least one of the intake 34 and outlet 35 may be integral with and molded together with the fan shroud. The intake 34 and outlet 35 each may project between about 1 cm and about 10 cm from the respective faces of the fan shroud. Intake 34 may have a generally oblong flange in cross section, and outlet 35 may have a generally cylindrical flange.
In one embodiment, as shown in
In one embodiment, one or more air filter mounting ribs 20, 27 may project from the second face of the fan shroud and/or plenum. Mounting ribs 20, 27 may be shaped or contoured to match and correspond to the housing or outer surface of air filter 11, helping to position and secure the air filter to the fan shroud. For example, mounting ribs 20, 27 may have arced surfaces to match the cylindrical housing 39 of air filter 11.
In one embodiment, cylindrical housing 39 may have a first end 41 and a second end 42, and cover 29 releasably attached to the second end. Dirty air inlet 21 may be adjacent the first end 41. Dirty air may enter the air filter through inlet 21 and be filtered with filtration elements before exiting through clean air outlet 24. In one embodiment, inlet 21 may be transverse to and extend outwardly from the cylindrical body of the housing. Dirty air inlet 21 may plug directly into outlet 35 extending from the second face of the fan shroud, and may have a snug fit to allow manual insertion or removal from outlet 35 without tools. For example, inlet 21 may have an external diameter the same or not more than about 5 mm less than the internal diameter of outlet 35.
In one embodiment, clean air outlet 24 may extend axially from first end 41 of the air filter housing. Valve 16 in the clean air outlet may be operable to control and/or restrict the air flow. Outlet 24 may be secured to hose 25 with a conventional clamping device, which routes clean filtered air to one or more fuel delivery components of the internal combustion engine.
The integrated fan shroud air intake system may be serviced by raising the vehicle engine compartment cover, removing the air filter housing cover and then removing the filtration elements. Advantages of the system may include reduced air filter mounting costs, improved serviceability of the air filter, reduced intake plumbing, reduced heat added to the inlet air, and improved packaging efficiency of the air filter. The improved packaging efficiency may allow additional space for other engine compartment components such as air conditioning, fuel tank, etc.
Having described the preferred embodiment, it will become apparent that various modifications can be made without departing from the scope of the invention as defined in the accompanying claims.
The entire right, title and interest in and to this application and all subject matter disclosed and/or claimed therein, including any and all divisions, continuations, reissues, etc., thereof are, effective as of the date of execution of this application, assigned, transferred, sold and set over by the applicant(s) named herein to Deere & Company, a Delaware corporation having offices at Moline, Ill. 61265, U.S.A., together with all rights to file, and to claim priorities in connection with, corresponding patent applications in any and all foreign countries in the name of Deere & Company or otherwise.
