Patent Application
20070012511
The present invention relates to improving the efficiency of an internal combustion engine and in particular to a muffler which reduces exhaust system back pressure to improve engine performance.
The increasing cost of oil has motivated car owners and manufacturers to seek means to improve vehicle mileage. In particular, auto manufacturers seek to increase their market share and to satisfy government mileage requirements. Improvements to exhaust systems in the form of reduced restriction and tuned lengths have become commonplace and vehicle mileage has somewhat benefitted from such efforts. However, meeting federally mandated mileage requirements remains a challenge and further improvements are necessary.
Reducing pollution continues to be an important societal objective. Pollution levels in metropolitan areas remain unacceptably high at times, and create an immediate direct health issue for humans, and a longer term issue due to the damage to plant life. Automotive-based pollution remains an issue, and auto makers are continually challenged to reduce the emissions from new automobiles. Further, the emissions from older vehicles continue even if new vehicles achieve significant emission reductions.
Modern automobiles greatly benefit from Electronic Fuel Injection (EFI) systems and efficient intake manifold and head designs. As a result, new automobiles have greatly improved economy and reduced emissions. But while the intake aspect of engine design has advanced drastically, exhaust systems have not similarly advanced. U.S. Pat. No. 6,213,251 issued Apr. 10, 2001 for “Self Tuning Exhaust Muffler,” describes a muffler having an outer tube and an inner louver tube, wherein a spiral vane extends outwardly from the louver tube to the outer tube and forms a helical passage for a flow between the louver tube and the outer tube. A multiplicity of “scoops” on the inside wall of the louvered tube “scoop” an outer portion of the flow through the louvered tube into the helical passage.
U.S. Pat. No. 6,679,351 issued Jan. 20, 2004 for “Air Turbine for Combustion Engine,” describes an “air turbine” apparatus creating a rotational flow which creates a muffling effect without restricting flow. The apparatus of the '351 patent includes annular recesses (or convolutions) at the forward end (i.e., before the diameter increases) of the apparatus, which are intended to create a cyclone or vortex effect in the air flow. Following the annular recesses, the air flow enters an expansion chamber, wherein an airfoil is positioned at the front of the expansion chamber to split the air flow into a high velocity lower pressure outer vortex, and a lower velocity higher pressure inner vortex. The air foil is shown in several figures of the '351 patent, and clearly plays the dominant role in the flow characteristics of a muffler according to the '351 patent and is essential to the described invention. Further, in column 4, lines 22-25, the '351 patent states that “the ratio of air passing around the airfoil compared to the air passing through the airfoil for a six inch diameter expansion chamber is approximately 2.7 to 1,” indicating that the air foil plays the dominant role on controlling air flow through the muffler. Additionally,
Although attempts have been made to improve performance and efficiency through modifications to exhaust systems, there remains a need to improve overall engine performance, improve mileage, and reduce pollution.
The present invention addresses the above and other needs by providing a muffler which includes an inner passage residing in an outer shell, and a stationary fan residing in the inner passage. The fan creates a vortex in a flow through the inner passage thus improving the flow and reducing the exhaust sound level. The inner passage includes an inner passage shell and the fan comprises vanes extending inward from the inner passage shell and turned at approximately a 45 degree angle to a centerline of the inner passage. Pinch zones at the entrance and exit from the inner passage further reduce the exhaust sound level. The inner passage shell is preferably a perforated inner passage shell, and a sound deadening material resides between perforated inner passage shell and the outer shell.
In accordance with one aspect of the invention, there is provided an engine muffler comprising an outer shell, an inner passage residing inside the outer shell, and a stationary fan residing inside the inner passage. The inner passage includes a perforated inner passage shell and a centerline. A space is defined between the inner passage shell and the outer shell and sound deadening material resides in the space. The fan comprises vanes angled at between approximately 30 degrees and approximately 60 degrees relative to the centerline of the inner passage, attached to the inner passage shell, and extending inwardly substantially reaching the centerline.
In accordance with another aspect of the invention, there is provided an engine muffler comprising an outer shell and an inner passage residing inside the outer shell. The inner passage has a perforated inner passage shell and a centerline. A first pinch zone resides at an inlet to the inner passage and a second pinch zone resides at an outlet to the inner passage. A space resides between the inner passage shell and the outer shell and a sound deadening material resides in the space. A stationary fan resides inside the inner passage. The fan comprises “D” shaped vanes angled at approximately 45 degrees relative to the centerline of the inner passage, attached to the inner passage shell, and extending inwardly, substantially reaching the centerline.
The above and other aspects, features and advantages of the present invention will be more apparent from the following more particular description thereof, presented in conjunction with the following drawings wherein:
Corresponding reference characters indicate corresponding components throughout the several views of the drawings.
The following description is of the best mode presently contemplated for carrying out the invention. This description is not to be taken in a limiting sense, but is made merely for the purpose of describing one or more preferred embodiments of the invention. The scope of the invention should be determined with reference to the claims.
A vehicle 10 including a body 12, an engine 14, and wheels 16 is shown in
A side view of the muffler 20 is shown in
The inner tube 22 includes an inlet portion 22a, a center portion 22b, and an outlet portion 22c. The inlet portion 22a may include a first pinch zone 23a and/or the outlet portion 22c may include a second pinch zone 23b to further reduce sound levels. The muffler 20 has a diameter D1 which, for example, may be approximately five inches for a typical car muffler. The inner tube center portion 22b has a diameter D2 which, for example, may be approximately 3.5 inches for a typical car muffler. The pinch zones 23a and 23b have a diameter D3 which, for example, may be approximately two inches for a typical car muffler. The muffler inlet 20a and outlet 20b have diameters D4 which, for example, may be approximately 2.5 inches for a typical car muffler. The muffler 20 has an overall length L1 which, for example, may be approximately thirteen inches for a typical car muffler, and the inner tube center portion 22b has a length L2 which, for example, may be approximately six inches for a typical car muffler.
A fan comprising vanes 26 resides inside the inner passage 22 and creates a vortex in an air flow through the inner passage 22. The fan is preferably in a front half 22b′ of the center portion 22b, and preferably, trailing edges 26a of the vanes 26 are approximately longitudinally centered in the center portion 22b. The vanes 26 are preferably flat and are preferably “D” shaped (see
The various angling of the blades 26 may correspond to the number of blades 26 in the muffler 20. For example, a four vane fan may preferably have blades angled at 45 degrees relative to the centerline CL, and a twelve vane fan may preferably have blades angled at 15 degrees (i.e., closer to parallel to the centerline CL) relative to the centerline CL. Further, greater sound attenuation may be achieved where necessary by greater angling (closer to perpendicular) relative to the centerline CL. In another example, a four vane fan may provide adequate sound attenuation for a turbocharged motor, and provide reduced back pressure, thus reducing turbo lag.
The inner passage 22 is preferably unobstructed except for the fan, but other objects may reside in the inner passage 22 which do not prevent the fan from creating a vortex in the flow through the inner passage 22, thus leaving the center passage 22 effectively unobstructed except for the fan.
A cross-sectional view taken along line 4-4 of
A side view of the inner passage 22 including a perforated inner passage shell 30 is shown in
In industrial applications such as generators, trucks, buses, heavy equipment, locomotives, and the like, vane counts of more than 12, (for example, 16 to as many as 36) may be preferred due to the size of the exhaust pipe, the amount of exhaust flow, and/or to obtain greater sound attenuation.
While the invention herein disclosed has been described by means of specific embodiments and applications thereof, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope of the invention set forth in the claims.
