The present disclosure relates to air intake systems for internal combustion engines associated with outboard motor propulsion systems.
U.S. Pat. No. 4,846,300, hereby incorporated by reference, discloses a marine engine with a multi-section injection-molded thermoplastic air box directing air to the fuel system's air intake throat and silencing engine noise emitted back through the throat. The air box has a cover section and a base section mounted to each other solely by a seal along a peripheral seam around the entire perimeter thereof, to prevent fuel leaks. The housing sections are preassembled to each other prior to mounting to the air intake throat. A removeable plug in the cover section allows access through the cover section to bolts mounting the base section to the throat. Access is also enabled to a fuel adjustment screw to enable adjustment, with the air box fully assembled and mounted in place on the throat, to enable adjustment under actual operating conditions. Air guide passages and an air plenum chamber are all molded in place.
U.S. Pat. No. 5,083,538, hereby incorporated by reference, discloses an air intake system for an internal combustion engine associated with the power head of an outboard marine propulsion system. The engine includes a vertical crank shaft and a flywheel mounted to the crank shaft above the engine block. An air manifold is mounted to the forward side of the engine, and includes an air inlet for receiving intake air. The air intake system includes an air flow path or duct defined by a series of walls, a rearwardly facing air intake opening, and a discharge opening for supplying intake air to the air manifold inlet. The engine is enclosed within a cowl assembly, and the air intake opening is located toward the upper end of the cowl assembly interior. The walls defining the air flow duct are formed integrally with a flywheel cover for facilitating assembly of the air flow duct to the engine. The air flow duct minimizes ingestion of water into the engine and reduces engine noise in the boat.
U.S. Pat. No. 9,359,981, hereby incorporated by reference, discloses an outboard motor including a system for enhancement of a first subset of sounds having a desired frequency, and a method for modifying sounds produced by an air intake system for an internal combustion engine powering the outboard motor. The method includes collecting sounds emitted in an area proximate a throttle body of the engine. A first subset of the collected sounds, which have frequencies within desired frequency range, is then amplified. The amplified first subset of sounds is then transmitted to an area outside a cowl covering the engine.
Unpublished U.S. patent application Ser. No. 15/091,007, filed Apr. 5, 2016, and hereby incorporated by reference, discloses an outboard motor including an internal combustion engine and a cowl covering the engine. An air vent allows intake air into the cowl, an air intake duct routes the intake air from the air vent to the engine, and a throttle body meters flow of the intake air from the air intake duct into the engine. A sound enhancement device is located proximate the throttle body. A sound duct is provided, and has an inlet end located proximate the sound enhancement device and an outlet end located proximate an outer surface of the cowl. The sound enhancement device is tuned to amplify a first subset of sounds having a desired frequency that are emitted from the throttle body, and the sound duct transmits the amplified sounds to an area outside the cowl. A method for modifying sounds produced by an air intake system of an outboard motor is also provided.
This Summary is provided to introduce a selection of concepts that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
According to one example of the present disclosure, an outboard motor includes an internal combustion engine powering the outboard motor and a cowl covering the engine and having a vent allowing air under the cowl. A throttle body meters flow of the air into the engine and an intake structure downstream of the throttle body delivers the metered airflow to one or more combustion chambers in a cylinder block of the engine. A sound enhancement assembly including an assembly housing is in acoustic communication with the intake structure and collects sounds emitted by the engine. The sound enhancement assembly is configured to amplify a subset of the collected sounds that have frequencies within a desired frequency range.
Another example of the present disclosure includes a method for modifying sounds produced by an air intake system of an internal combustion engine powering an outboard motor. The method includes positioning a sound enhancement assembly including an assembly housing in acoustic communication with an air intake passageway located downstream of a throttle body of the engine. The method also includes tuning a sound enhancement device of the sound enhancement assembly so that the sound enhancement device amplifies a subset of sounds emitted by the engine that have frequencies within a desired frequency range. The amplified subset of sounds is transmitted as sound pressure pulses through a sound passageway of the sound enhancement assembly to an area outside a cowl covering the engine. Fluid communication between the air intake passageway and the sound passageway is prevented.
The present disclosure is described with reference to the following Figures. The same numbers are used throughout the Figures to reference like features and like components.
In the present description, certain terms have been used for brevity, clarity and understanding. No unnecessary limitations are to be inferred therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes only and are intended to be broadly construed.
In the system shown in
Product noise requirements and/or expectations of a given outboard motor can vary greatly depending on the application. For example, performance boaters may desire a louder and/or more powerful sound quality than recreational boaters. However, expectations for sound quality and refinement are universal, and dictated in some geographical areas by law, regardless of the noise level expectations of the customer. The system and method of the present disclosure, described below with respect to
The outboard motor 10 of the present disclosure, shown in
A sound enhancement assembly 32 is provided in the outboard motor 10. The sound enhancement assembly 32 is in acoustic communication with the intake structure 24 and collects sounds emitted by the engine 14, for example sounds emitted by air passing through the throttle body 16, through the intake passages 28, into the combustion chambers 20, etc. The sound enhancement assembly 32 is configured to amplify a subset of the collected sounds that have frequencies within a desired frequency range. As will be described further herein below, the sound enhancement assembly 32 includes an inlet pipe 34 coupled to or integral with the intake structure 24 that collects the sounds emitted by the engine 14. The sound enhancement assembly 32 also includes an outlet pipe 36 that transmits the amplified subset of the collected sounds to an area outside the cowl 12, 13. A specific example, which is not limiting on the present disclosure, will be described below.
Turning to
Now turning to
The sound enhancement device 54 acts as a passive speaker that is tuned to amplify a subset of sounds that have been collected from the area where the sound enhancement assembly 32 is coupled to the air intake structure 24. The sound enhancement device 54 adjusts the spectral frequency (sound amplitude vs. frequency) of the subset of sounds without the use of active components such as, for example, electronic amplifiers. Because the sound enhancement assembly 32 is passive, it relies on acoustic excitation of the sound enhancement device 54 by sounds radiating from the air intake structure 24 to provide amplification. This subset of sounds can be defined in any way desired by the manufacturer/installer/operator. For example, the subset of sounds may be sounds that have frequencies within a desired frequency range, such as those that produce what might be considered a pleasant “rumble” that conveys the power of the engine 14 to the operator of the vessel. The sound enhancement device 54 can be tuned to amplify this pleasant rumble such that the operator can hear it better.
In one example, the sound enhancement device 54 extends generally transversely across the aperture 35 (see
The sound enhancement assembly 32 also includes the above-noted outlet pipe 36. The outlet pipe 36 has an upstream end, here designed as the elbow piece 52 having the second mounting flange 55, which is coupled to the first mounting flange 51 downstream of the sound enhancement device 54. The outlet pipe 36 also includes a downstream pipe 53 coupled to the elbow piece 52 that transmits the amplified subset of the collected sounds to an area outside of the cowl 12, 13. The downstream end of the outlet pipe 36 is located proximate an outer surface of the upper or lower portions of the cowl 12, 13 (
Returning to
The spacing of each travel guard 63, 62 is set to prevent contact between the sound enhancement device 54 and the travel guards 63, 62 under typical steady-state operating conditions. This can be a number of millimeters, such as for example 5 millimeters, but depends on the desired steady state movement of the sound enhancement device 54 in response to sound pressure pulses in the air intake system. Although the tensioner 60 and downstream travel guard 62 are shown herein as comprising circular disks having central circular spines and support arms that radiate from the central circular spine to an outer edge of the disk, other shapes and configurations for the tensioner 60 and downstream travel guard 62 could be provided. The support arms are spaced apart such that sound pressure pulses in the plenum 42 can act on the sound enhancement device 54 and amplified sound pressure pulses created by the sound enhancement device 54 can travel unhindered to the outlet pipe 36. The tensioner 60 and downstream travel guard 62 can be made from a reinforced polymer or alternative materials. Ideally, the materials of the tensioner/travel guard are not elastic and do not vibrate in response to sound pressure pulses within the system. Thus, both of the tensioner 60 and downstream travel guard 62 are acoustically transparent and do not significantly affect the sounds traveling through the sound enhancement assembly 32.
The sound enhancement assembly 32 may also include an acoustically transparent shield 64 including an upper domed roof 65 positioned above a lower tubular portion 67 of the shield 64 that makes up a portion of inlet pipe 34. The shield 64 is located upstream of the sound enhancement device 54 and protects the sound enhancement device 54 from particulates in the intake structure 24 (i.e., plenum 42). This prevents the sound enhancement device 54 from accumulating unwanted substances, which is especially useful if the sound enhancement assembly 32 is positioned vertically within the intake structure 24. Here, the shield 64 comprises the above-mentioned lower tubular portion 67 that sits atop the outer flange and lip 61 of the tensioner 60 and fits into the inner diameter of the first mounting flange 51. A number of circumferentially-spaced columns 69 extend upwardly from the lower tubular portion 67 and support the upper domed (or conical) roof 65 that extends into the plenum 42 and sheds any particulates that settle on it. The columns 69 are spaced apart such that sound pressure pulses in the plenum 42 can act on the sound enhancement device 54. Of course, other constructions for the shield 64 are within the scope of the present disclosure. The shield 64 could be made of a reinforced polymer or other materials. Ideally, the material of the shield 64 is not elastic, does not vibrate in response to sound pressure pulses within the system, and thus does not have a significant effect on the sounds emitted from the sound enhancement assembly 32.
In this example, the tensioner 60 and the shield 64 each have a cylindrical inner diameter that together form the inlet pipe 34. Tensioner 60 has an inner diameter defined by lip 61 that defines the lower half of the inlet pipe 34, and shield 64 has an inner diameter defined by tubular portion 67 that defines the upper half of the inlet pipe 34. The length of this inlet pipe 34 is dictated by the sum of the heights of the openings in both the tensioner 60 and the shield 64, and the diameter of the inlet pipe 34 is dictated by the inner diameter of these two parts. In this embodiment, in order adjust the physical dimensions of the inlet pipe 34 such as its length and diameter, these two components 60, 64 would require modification. This is potentially a desirable tuning parameter for the sound enhancement assembly 32.
An O-ring 66 may be provided between the shield 64 and the tensioner 60 in order to seal the tensioner 60 to the first mounting flange 51. An optional tension adjustment ring 68 may be provided between the tensioner 60 and the sound enhancement device 54. This tension adjustment ring 68 is a tuning component that can be provided with different thicknesses in order to stretch the sound enhancement device 54 to different tensions for alternative tuning frequencies. The thickness of the tension adjustment ring 68 adjusts the effective height of the lip 61 on the primary tensioner 60, allowing for various tension settings for the sound enhancement device 54. For example, a thinner tension adjustment ring 68 would effectively create a longer lip 61 and thus cause the sound enhancement device 54 to be stretched tighter across the aperture 35. See
A seal 70 is provided between the downstream side 58 of the sound enhancement device 54 and the outlet portion of the assembly housing 47 (i.e., elbow piece 52). The seal 70 is preferably made of a compressible material in order to provide an airtight seal between the first mounting flange 51 and the second mounting flange 55 on the elbow piece 52. The seal 70 has an inner ring-shaped circumference 73 that holds the outer circumference of the downstream travel guard 62 therein. The seal 70 also has an outer flange 75 for holding the seal 70 to the remainder of the sound enhancement assembly 32. The elbow piece 52 and seal 70 are held to the inlet portion of the assembly housing 47 (first mounting flange 51) by way of one or more fasteners, such as the bolts 72 shown herein, that pass through holes in their respective flanges 55, 75 and into corresponding holes surrounding the aperture 35 in the first mounting flange 51.
The downstream pipe 53 of the outlet pipe 36 can be friction fit over the downstream end of the elbow piece 52. In another example, the outlet pipe 36 is integrally formed from the second mounting flange 55 that sits against the seal 70 and is bolted to the first mounting flange 51 all the way to the downstream end that exits the cowl 12, 13. In another example, the outlet pipe 36 includes a separate or integral flanged piece that is other than an elbow shape. The elbow piece 52 serves as the outlet portion of the sound enhancement assembly housing 47. The outlet portion needs an attachment connection for the outlet pipe, which in this example happens to be a 90 degree elbow. This outlet pipe attachment could instead be oriented at any angle, and its shape could be selected in order to provide ease of routing to the desired outlet location at the cowl. The inner diameter of the outlet pipe 36 is a tuning parameter for the sound enhancement assembly 32, and this could be adjusted to any diameter. Note that the outlet pipe 36 could also be provided with twists, turns, and varying diameters before it exits the cowl 12, 13. This can allow the outlet pipe 36 to snake around other engine components, or can provide different characteristics to the sound emitted from the outlet pipe 36.
For example, the outboard motor 10 shown in
Now turning to
Further, the method may also include providing at least one travel guard 63, 62 in the housing that prevents the sound enhancement device 54 from distending by more than a predetermined distance in response to a pressure pulse, such as that created by backfire or throttle chop. The method may include providing a first travel guard 63 (for example, integral with the tensioner 60) on an upstream side 56 of the sound enhancement device 54 and a second travel guard 62 on a downstream side 58 of the sound enhancement device 54. The method may further comprise shielding the sound enhancement device 54 from particulates in the intake passageway, such as by way of shield 64, as described herein above with respect to
Returning to
Optionally, a sound throttle can be used to control the volume contribution of the amplified sound coming from the sound enhancement assembly 32. For example, see element 74 in
The sound enhancement assembly 32 of the present disclosure has an increased impact on the sound signature produced because the sound source (i.e. the inlet pipe 34 and sound enhancement device 54) can be located at a strategic point downstream of the throttle body 16. Note that when a sound enhancement device is placed upstream of the throttle body 16, pressure pulses from each combustion chamber 20 are more or less combined into a single noise source, meaning a device upstream of the throttle body 16 acts more like a volume knob for the intake sound that is already present. However, by locating the sound device downstream of the throttle body 16, there is a greater potential to locate, identify, and isolate noise contributions from different portions of the engine's air intake passageways. Additionally, attachment of the sound enhancement assembly 32 at various points along the intake passageway can create more packaging options, allowing the sound enhancement assembly 32 to be used with more outboard motor package types.
In the above description, certain terms have been used for brevity, clarity, and understanding. No unnecessary limitations are to be inferred therefrom beyond the requirement of the prior art because such terms are used for descriptive purposes and are intended to be broadly construed. The different systems and method steps described herein may be used alone or in combination with other systems and methods. It is to be expected that various equivalents, alternatives and modifications are possible within the scope of the appended claims.
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