The present description relates generally to an air intake system for an internal combustion engine.
Engines have, in the past, utilized multiple air inlets to feed air to airboxes. Using multiple inlets provides a high flowrate of filtered air to internal combustion engines. High intake flowrates may be particularly desirable in compression ignition engines, which may require during certain operating conditions, a large amount of intake airflow to drive combustion. However, depending on the location of the air inlet the inlet may be susceptible to damage, clogging, etc., from external road debris (e.g., snow, ice, rocks, etc.).
Previous intake systems have attempted to protect air inlets by placing the inlet in a more shielded vehicle location to reduce the inlet's exposure to road debris. One example approach shown by MacKenzie et al., in U.S. Pat. No. 9,062,639, is a dual inlet air induction system. In MacKenzie's air induction system, one air inlet is positioned under an engine compartment hood and another air inlet is located in a fender panel. The inventors have recognized several drawbacks with MacKenzie's system. For instance, in MacKenzie's system, the inlet positioned under the hood receives air at elevated temperatures, due to the inlet's proximity to hot engine components. Elevated intake air temperatures can decrease combustion efficiency and in some cases may lead to pre-ignition, knock, etc. Therefore, MacKenzie's system as well as other intake systems have in the past made tradeoffs between the degree of air inlet shielding and the temperature of the air drawn into the inlet.
Other attempts have been made to actively control airflow through different air inlets. For instance, one example approach shown by Miller et al., in U.S. Pat. No. 8,048,179, includes an intake system having two air inlets with one of the inlets having a flow valve positioned therein. The valve is opened during cold weather conditions to draw hot air into a portion of the intake system that may be obstructed by snow. However, the active control system, described in Miller, may be prone to malfunction or in some cases failure due to the complexity of the control system used to adjust the flow valve. Furthermore, active flow valves may be costly and as a result the production costs of vehicles using active valves may be unduly increased. Additionally, Miller's system only allows a single airflow path to be opened at any one time.
The inventors have recognized the aforementioned problems and confronting these problems developed an air intake system. The air intake system includes a first air inlet duct providing intake air to an engine intake conduit. The first air inlet duct includes an opening positioned external to an engine compartment. The air intake system also includes a second air inlet duct positioned upstream of the engine intake conduit and external to the engine compartment. The second air inlet duct includes a foam plug selectively impeding airflow through the second air inlet duct and the foam plug spans an opening of the second air inlet duct. In this way, one air inlet may provide air to the engine regardless of operating conditions, on the one hand. While on the other hand, another air inlet can provide selective airflow to the engine. The foam plug in the second air inlet enables an increase in airbox inflow, during low hazard conditions. Conversely, during high hazard conditions (e.g., cold weather), the foam plug inhibits airflow through an exposed air inlet duct to reduce the likelihood of damage to the system caused by external debris.
In one example, the second air inlet duct may be positioned in a less protected location than the first air inlet duct to enable an increased amount of air to be drawn into the second duct. For instance, the second air inlet duct may be positioned below and/or in a more forward location than the first air inlet duct. In this way, the second air inlet duct may draw in a large amount of low temperature air when the foam plug is above a threshold temperature. Consequently, the air intake system may provide a greater amount of airflow to the engine, to increase combustion efficiency, when inclement conditions are not occurring. Conversely, during snowy conditions, for instance, the foam plug may adapt to block the second air inlet duct to prevent snow, ice, etc., from entering the air intake system. Consequently, the air intake system can be protected from external debris during selected conditions, thereby decreasing the likelihood of engine degradation and in some cases shutdown during inclement conditions. Moreover, the foam plug may be less costly and more robust than mechanical flow control valves that act to block inlet conduits during inclement conditions. Consequently, the manufacturing costs of the system may be reduced when a foam plug is incorporated into an inlet duct.
It should be understood that the summary above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.
The following description relates to an air intake system providing airflow to an engine. The air intake system may include, in one example, a first air inlet duct spaced away from the second air inlet duct. Additionally, the second air inlet duct may include a temperature sensitive piece of foam extending across an opening of the second air inlet duct. The foam may be designed to block the opening when below a threshold temperature (e.g., at or near freezing) and drawing in snow and allow airflow therethrough when above the threshold temperature. In this way, when external environmental factors (e.g., snowy/icy conditions) are likely to cause intake system degradation airflow through the second air inlet duct may be inhibited. For instance, while driving in snowy conditions, previous systems, may suck snow into an air inlet which may cause significant engine degradation or even shut-down, in some instances. However, in the air intake system described herein pores in the temperature dependent foam may clog up with snow and/or ice particles to block the snow from traveling into the intake system, during cold temperature conditions. However, during lower hazard conditions (e.g., above freezing ambient temperature conditions) pores in the foam may become unblocked to permit airflow therethrough to provide increased intake airflow. In this way, the foam passively adapts to changing environmental conditions. Consequently, during higher risk conditions the foam acts to reduce the likelihood of engine degradation and during lower risk conditions the foam allows airflow therethrough to facilitate an increase in combustion efficiency. The foam, in one example, may be constructed out of polyether to enable the aforementioned temperature dependent duct blocking capabilities. Additionally, providing the temperature dependent foam plug in the inlet duct may enable the inlet duct to be positioned in a less protected location spaced away from hot engine components, if desired. For instance, the second air inlet duct may be placed near a front grille of the vehicle. As a result, the air delivered to the engine may have a lower temperature, thereby increasing the engine's combustion efficiency. Moreover, the foam plug may reduce the construction cost of the system when compared to system's using costly active mechanical control valves.
Turning to
The air intake system 14 specifically provides intake air to a cylinder 16. The cylinder 16 is formed by a cylinder block 18 coupled to a cylinder head 20. Although,
The air intake system 14 includes a first air inlet duct 22 and a second air inlet duct 24. Each of the first and second air inlet ducts, 22 and 24, provide intake air to an airbox 26 having a filter 28 configured to remove particulates from air flowing therethrough. The first and second air inlet ducts may be spaced away from one another and positioned in strategic locations that provide varying degrees of protection from external debris, described in detail herein.
The second air inlet duct 24 includes a foam plug 30 designed to selectively impede airflow through the second air inlet duct 24. Specifically, the foam plug 30 may selectively impede airflow through the second air inlet duct 24 based on the temperature of the foam. For instance, the foam plug 30 may impede (e.g., inhibit) airflow therethrough when the plug is below a threshold temperature (e.g., 0 degrees Celsius, 2 degrees Celsius, 5 degrees Celsius, in the range between −5 degrees Celsius and 5 degrees Celsius, in the range between 1 degrees Celsius and 3 degrees Celsius, etc.) and snow and/or ice particulates have been drawn into the opening of the duct. Thus, when the foam plug is below the threshold temperature pores in the plug may clog with snow particles and freeze to block airflow therethrough. On the other hand, when the foam plug 30 is above the threshold temperature the foam adapts to permit airflow through pores in the foam. In this way, when above the threshold temperature, the foam plug essentially thaws and returns to a porous state where air can travel through the plug. To enable the aforementioned temperature dependent adaptation, the foam plug 30 may be include a foam material, such as polyether. Specifically, in one example, the foam plug 30 may be constructed solely out of polyether. However, other foam materials have been contemplated. Further, in one example, a porosity of the foam plug may be between 30 and 80 pores per square inch, to provide the plug with desired temperature dependent airflow characteristics. When the foam plug has a porosity between 30 and 80 pores per square inch a desired amount of airflow may flow therethrough when above a threshold temperature and conversely when the foam plug is below the threshold temperature the foam may substantially inhibit airflow therethrough, due to snow particulates blocking pores in the foam. In another example, the porosity of the foam may be between 40 and 60 pores per square inch. It will be appreciated that the foam plug 30 may also assist in blocking large debris (e.g., pebbles, leaves, insects, etc.) and rain droplets from entering a downstream air filter. Additionally, in one specific example, the density of the foam plug may be selected to address specific vehicle working applications (e.g., mining vehicles, border patrol vehicles, etc.) such as vehicles subjected to large amounts of dust, dirt, and/or sand. In one example, such as in air intake systems designed for dusty and sandy environments, the foam plug may include foam having a density around 30 pores per square inch. In another example, such as in air intake systems designed for cold weather environments, the foam plug may include foam having a density around 80 pores per square inch. However, foam plugs with other densities may be used, in other examples.
The airbox 26 feeds intake air to an engine intake conduit 32. The engine intake conduit 32, in turn, provides air to an intake valve 34 coupled to the cylinder 16. A throttle 36 may be positioned in an engine intake conduit 35 positioned downstream of the engine intake conduit 32. It will be appreciated that in other examples, such as in the case of a multi-cylinder engine, an intake manifold may be coupled to the engine intake conduit and provide intake air to a plurality of intake valves.
The intake valve 34 may be actuated by an intake valve actuator 38. Likewise, an exhaust valve 40 may be actuated by an exhaust valve actuator 42. In one example, both the intake valve actuator 38 and the exhaust valve actuator 42 may employ cams coupled to intake and exhaust camshafts, respectively, to open/close the valves. Continuing with the cam driven valve actuator example, the intake and exhaust camshafts may be rotationally coupled to a crankshaft. Further in such an example, the valve actuators may utilize one or more of cam profile switching (CPS), variable cam timing (VCT), variable valve timing (VVT) and/or variable valve lift (VVL) systems to vary valve operation. Thus, cam timing devices may be used to vary the valve timing, if desired. In another example, the intake and/or exhaust valve actuators, 38 and 42, may be controlled by electric valve actuation. For example, the valve actuators, 38 and 42, may be electronic valve actuators controlled via electronic actuation. In yet another example, the cylinder 16 may alternatively include an exhaust valve controlled via electric valve actuation and an intake valve controlled via cam actuation including CPS and/or VCT systems. In still other embodiments, the intake and exhaust valves may be controlled by a common valve actuator or actuation system.
An ignition system 44 may provide spark to the cylinder 16 via an ignition device 46 (e.g., spark plug) at desired time intervals. However, in compression ignition configurations the engine 10 may not include the ignition system 44. Additionally, a fuel delivery system 48 is also shown in
An exhaust system 56 configured to manage exhaust gas from the cylinder 16 is also included in the vehicle 12, depicted in
Additionally, the controller 100 may be configured to trigger one or more actuators and/or send commands to components. For instance, the controller 100 may trigger adjustment of the throttle 36, intake valve actuator 38, exhaust valve actuator 42, ignition system 44, and/or fuel delivery system 48. Therefore, the controller 100 receives signals from the various sensors and employs the various actuators to adjust engine operation based on the received signals and instructions stored in memory of the controller.
During engine operation, the cylinder 16 typically undergoes a four stroke cycle including an intake stroke, compression stroke, expansion stroke, and exhaust stroke. It will be appreciated that the cylinder may also be referred to as a combustion chamber. During the intake stroke, generally, the exhaust valves close and intake valves open. Air is introduced into the cylinder via the corresponding intake conduit, and the piston moves to the bottom of the cylinder so as to increase the volume within the cylinder. The position at which the piston is near the bottom of the cylinder and at the end of its stroke (e.g., when the cylinder is at its largest volume) is typically referred to by those of skill in the art as bottom dead center (BDC). During the compression stroke, the intake valves and exhaust valves are closed. The piston moves toward the cylinder head so as to compress the air within cylinder. The point at which the piston is at the end of its stroke and closest to the cylinder head (e.g., when the cylinder is at its smallest volume) is typically referred to by those of skill in the art as top dead center (TDC). In a process herein referred to as injection, fuel is introduced into the cylinder. In a process herein referred to as ignition, the injected fuel in the cylinder is ignited by a spark from an ignition device (e.g., spark plug), resulting in combustion. It will be appreciated that in other examples the engine may employ compression ignition. Therefore, the ignition system may be omitted from the engine, in some instances. A crankshaft converts this piston movement into a rotational torque of the rotary shaft. During the exhaust stroke, in a traditional design, exhaust valves are opened to release the residual combusted air-fuel mixture to the corresponding exhaust passages and the piston returns to TDC.
Turning to
Continuing with
In one example, the first air inlet duct 216, the first flow channel 304, the second flow channel 306, shown in
Turning again to
As shown in
Further, in one example, a cross-sectional area of the opening 602 of the first air inlet duct 216 may be greater than a cross-sectional area of the opening 600 of the second air inlet duct 220. In this way, the first air inlet duct 216 may provide a greater amount of airflow to downstream components than the second air inlet duct 220 to enable the engine to achieve a desired vacuum pressure. The cross-sectional areas of the openings may be measured on a plane perpendicular to the direction of airflow into the ducts, in one example. Additionally, the first air inlet duct 216 includes a section 604 extending in a downward direction toward the airbox 232. The second air inlet duct 220 is show including a section 606 extending in a rearward direction toward the airbox 232. Section 606 may also curve away from a side of the vehicle toward the front grille 222, shown in
Additionally,
Continuing with
Continuing with
The invention will further be described in the following paragraphs. In one aspect, an air intake system for an engine is provided. The air intake system comprises a first air inlet duct providing intake air to an engine intake conduit and including an opening positioned external to an engine compartment; and a second air inlet duct positioned upstream of the engine intake conduit and external to the engine compartment, the second air inlet duct including a foam plug selectively impeding airflow through the second air inlet duct, the foam plug spanning an opening of the second air inlet duct.
In another aspect, an air intake system for an engine is provided. The air intake system comprises a first air inlet duct including an opening positioned external to an engine compartment; and a second air inlet duct positioned external to the engine compartment and below the first air inlet, the second air inlet duct having a foam plug spanning an opening of the second air inlet duct, the foam plug including a temperature adaptive foam.
In yet another aspect, an air intake system for an engine is provided. The air intake system comprises a first inlet flow path routing airflow through a gap between an engine hood and a headlamp, a first air inlet duct, and an air filter in an airbox, an opening of the first air inlet duct positioned external to the engine compartment; and a second inlet flow path routing airflow through a front grille below the engine hood, a foam plug spanning a second air inlet duct external to the engine compartment, and the air filter, the foam plug inhibiting airflow through the second air inlet flow path when the foam plug is below a threshold temperature and allowing airflow through the second air inlet flow path when the foam plug is above the threshold temperature.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may be positioned longitudinally behind the second air inlet duct with regard to a direction of forward travel.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may be positioned vertically above the second air inlet duct.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may be positioned below a section of an engine hood.
In any of the aspects herein or combinations of the aspects, the second air inlet duct may be positioned adjacent to a grille reinforcement structure and behind a front grille.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may receive airflow from a first flow channel extending through a gap between an engine hood and a headlamp.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may receive airflow from a second flow channel traveling through an air conduit extending from a first compartment behind a front grille into a second compartment below an engine hood.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may include a housing lip sealing with the engine hood to form a boundary of an engine compartment.
In any of the aspects herein or combinations of the aspects, the foam plug may include a polyether material.
In any of the aspects herein or combinations of the aspects, a porosity of the foam plug may be between 40 and 60 pores per square inch.
In any of the aspects herein or combinations of the aspects, a porosity of the foam plug may be between 30 and 80 pores per square inch.
In any of the aspects herein or combinations of the aspects, a cross-sectional area of an opening of the first air inlet duct may be greater than a cross-sectional area of an opening of the second air inlet duct.
In any of the aspects herein or combinations of the aspects, selectively impeding airflow through the second air inlet duct may include inhibiting airflow through the second air inlet duct when the foam plug is below a threshold temperature and allowing airflow through the second air inlet duct when the foam plug is above the threshold temperature.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may be positioned longitudinally behind the second air inlet duct with regard to a direction of forward travel.
In any of the aspects herein or combinations of the aspects, the first air inlet duct may be positioned under a section of an engine hood.
In any of the aspects herein or combinations of the aspects, the temperature adaptive foam may include a polyether material and where a porosity of the temperature adaptive foam is between 40 and 60 pores per square inch.
In any of the aspects herein or combinations of the aspects, the second air inlet duct may receive airflow from a flow channel travelling through openings in a front grille.
In any of the aspects herein or combinations of the aspects, the second air inlet duct may include a housing lip sealing with the engine hood to form a boundary of the engine compartment.
In any of the aspects herein or combinations of the aspects, the foam plug may include a polyether material and where a porosity of the foam plug may be between 40 and 60 pores per square inch.
It will be appreciated that the configurations and features disclosed herein are exemplary in nature, and that these specific embodiments are not to be considered in a limiting sense, because numerous variations are possible. For example, the above technology can be applied to V-6, I-4, I-6, V-12, opposed 4, and other engine types. The subject matter of the present disclosure includes all novel and non-obvious combinations and sub-combinations of the various systems and configurations, and other features, functions, and/or properties disclosed herein.
The following claims particularly point out certain combinations and sub-combinations regarded as novel and non-obvious. These claims may refer to “an” element or “a first” element or the equivalent thereof. Such claims should be understood to include incorporation of one or more such elements, neither requiring nor excluding two or more such elements. Other combinations and sub-combinations of the disclosed features, functions, elements, and/or properties may be claimed through amendment of the present claims or through presentation of new claims in this or a related application. Such claims, whether broader, narrower, equal, or different in scope to the original claims, also are regarded as included within the subject matter of the present disclosure.
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