The present disclosure relates to marine drives and particularly to air intake plenums having features for attenuating sound emanating from a marine drive.
The following U.S. Patents are incorporated herein by reference:
U.S. Pat. No. 10,344,719 discloses an intake system for a marine drive. The intake system comprises a throttle device that receives intake air for combustion; an intake conduit that conveys the intake air to the throttle device, wherein the intake conduit has an upstream inlet end, a downstream outlet end, and a radially outer surface that extends from the upstream inlet end to the downstream outlet end; and an intake silencer coupled to the radially outer surface and configured to attenuate sound emanating from the intake system.
U.S. Pat. No. 10,180,121 discloses an outboard motor having 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 which 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.
U.S. Pat. No. 9,909,545 discloses an outboard motor having 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 in acoustic communication with the intake structure 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. A method for modifying sounds produced by an air intake system of an internal combustion engine powering an outboard motor is also disclosed. The method includes positioning a sound enhancement assembly in acoustic communication with an air intake passageway located downstream of the engine's throttle body.
U.S. Pat. No. 9,784,218 discloses an air intake system for a marine engine having a throttle body and a throttle plate that is rotatably supported within the throttle body. The throttle plate is rotatable to regulate air flow through the throttle body from a first region on a first side of the throttle plate to a second region on a second side of the throttle plate. An air conduit has an air conduit inlet and an air conduit outlet. A noise cancelling device comprises a pass-through chamber. The pass-through chamber has a chamber inlet that receives the air flow from the air conduit, a chamber outlet that discharges the air flow to the idle air control valve, and a pass-through interior between the chamber inlet and chamber outlet. The pass-through chamber is configured to cancel noise emanating from the idle air control valve.
U.S. Pat. No. 9,359,981 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, are then amplified. The amplified first subset of sounds are then transmitted to an area outside a cowl covering the engine.
U.S. Pat. No. 6,752,240 discloses a sound attenuating system which allows a relatively unobstructed airflow conduit to be associated with chambers that reflect various frequencies of sound back towards the source of the sound. The chambers are arranged in a coaxial association with the primary airflow conduit and are sized to reflect a certain range of frequencies of sound. Holes extend through the airflow conduit, in a radial direction, to place the airflow conduit in fluid communication with the chambers which surround portions of the conduit.
This Summary is provided to introduce a selection of concepts that are further described herein 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. In examples herein disclosed, an intake plenum is for a marine engine, the marine engine having first and second throttle devices for controlling flow of intake air to the marine engine. The intake plenum has an airbox providing an expansion volume; first and second inlets that convey the intake air in parallel to the expansion volume; first and second outlets that convey the intake air in parallel from the expansion volume to the first and second throttle devices; and first and second Helmholtz-style attenuator devices at the first and second outlets, respectively. Together the first and second inlets, the expansion volume, and the first and second Helmholtz-style attenuator devices are configured to attenuate different frequencies of sound emanating from the marine engine via the first and second outlets.
The present disclosure is described with reference to the following Figures.
During research and experimentation, the present inventors recognized a need for an improved air intake plenum for a marine engine, and in particular non-limiting examples for an outboard motor configuration having an engine with an odd firing order and throttle bodies that emit sounds having broad range of frequencies, including at least between 200 Hz and 800 Hz. The inventors endeavored to invent such an air intake plenum for use within a relatively small available area in the powerhead compartment 18, in particular without interfering with other engine components. The inventors found it was quite challenging to achieve the above objectives, particularly with respect to attenuation of sounds in a mid-frequency range of about 500 Hz to 800 Hz. The present disclosure provides inventions that overcome these challenges.
A novel air intake plenum 30 according to the present disclosure is specially configured to convey the intake air from inside the powerhead compartment 18 to the engine 16 via port and starboard throttle devices 32, 34, and also to effectively attenuate a wide range of sounds emanating from the engine 16 via the respective throttle devices 32, 34, including high, low, and mid-range sound frequencies, as will be further explained herein below with reference to
Referring to
Referring to
The airbox 36 generally has an elongated inlet portion 76 that houses the port and starboard inlet air ducts 66, 68, and an elongated outlet portion 78 that depends from the inlet portion 76, extending in the axial direction 54, generally transversely to the inlet portion 76. As can be seen in
Referring to
Referring to
The geometry (i.e., shape and size) of the air intake plenum 30 and its components are specially tuned to attenuate a certain range of frequencies. For example, the length of the port and starboard inlet air ducts 66, 68 is tuned to attenuate certain frequencies. Similarly, the length of the outlet ducts 90 are tuned to attenuate a certain range of frequencies. The shape (e.g. height and width) of the airbox 36 is also tuned to attenuate a certain range of frequencies. The number and configuration (size and alignment) of the attenuation chambers 92, 94 and attenuation holes 94, 96 are configured to attenuate certain ranges of frequencies. The geometry of the airbox 36, including the inside upper surface 80, rounded shoulder 84, and bell mouth 108 are configured to together prevent recirculation within the airbox 36 and facilitate improved flow of intake air with less restriction. The inventors further determined that division of the inflow of intake air via the port and starboard inlet ducts 66, 68 to the common expansion volume 59, and the division of the outflow of the intake air via the Helmholtz-style attenuator devices 86, 88 surprisingly effectively attenuated sound having a wide range of frequencies.
The present inventors determined that minor changes to the shape and/or size of the airbox 36 that were necessary to accommodate the above-described size constraints had a significant impact on attenuation of sounds in the mid-frequency range of 500 HZ to 800 Hz compared to a relatively less significant impact on attenuation of sounds in the low frequency range of 200 Hz to 500 Hz. To overcome this challenge, the inventors conceived of the port and starboard Helmholtz-style attenuator devices 86, 88 having the extended air ducts 90, which advantageously increased attenuation of sounds in the mid frequency range and reduced the sensitivity of the airbox geometry changes to this frequency range. The inventors also realized that the elongated port and starboard (inlet) air ducts 66, 68 and elongated port and starboard outlet air ducts 90 can be shaped and sized (i.e. tuned) to attenuate particular ranges of sound frequencies that are not otherwise attenuated by the expansion volume 59. However, tuning of these features is somewhat limited by the overall geometry (size and shape) of the airbox 36, particularly in view of the above-noted design space constraints. There are physical limits on the length of these features, as well as practical limits where flow restrictions result in performance loss. Thus added functional benefit of the Helmholtz-style attenuator devices 86, 88 is that they provide minimal flow restriction. The attenuation chambers 92, 94 are advantageously located radially outside of the air duct 90 and thus outside of the main flow of intake air. Thus the Helmholtz-style attenuator devices 86, 88 are efficiently packaged with the expansion volume 59, which minimizes packaging space and provides a wider range of frequency reductions, particularly with respect to the mid-frequency range, compared to what a larger expansion volume would provide on its own.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to make and use the invention. 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. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have features or structural elements that do not differ from the literal language of the claims, or if they include equivalent features or structural elements with insubstantial differences from the literal languages of the claims.
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Number | Date | Country |
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2743848 | Jul 1997 | FR |