Active air dam notification method and system

An active air dam notification method includes, among other things, transitioning an air dam of a vehicle between a first position and a second position, and providing an alert to a user. The alert indicates that the air dam is transitioning. The air dam is vertically higher when the air dam is in the first position than when the air dam is in the second position.

TECHNICAL FIELD

This disclosure relates generally to an active air dam for a vehicle and, more particularly, to providing an alert when the active air dam is being lowered, being raised, or both.

BACKGROUND

Some vehicles include an active air dam. The active air dam can be lowered and raised to manage airflow. The active air dam can be located at a front of a vehicle.

SUMMARY

An active air dam notification method according to an exemplary aspect of the present disclosure includes, among other things, transitioning an air dam of a vehicle between a first position and a second position, and providing an alert to a user. The alert indicates that the air dam is transitioning. The air dam is vertically higher when the air dam is in the first position than when the air dam is in the second position

Another example of the foregoing method includes providing a first type of alert when the active air dam is transitioning from the first position to the second position, and providing a second, different type of alert when the active air dam is transitioning from the second position to first position.

In another example of any of the foregoing methods, the alert is an audible alert.

In another example of any of the foregoing methods, the alert is a visual alert.

In another example of any of the foregoing methods, the visual alert is displayed within an instrument cluster of the vehicle.

Another example of any of the foregoing methods includes providing the alert by adjusting light emitted by an illumination system of the vehicle.

In another example of any of the foregoing methods, adjusting the light comprises flashing the light.

In another example of any of the foregoing methods, adjusting the light comprises changing a color of the light.

In another example of any of the foregoing methods, the illumination system is an ambient lighting system of the vehicle.

Another example of any of the foregoing methods includes providing the alert by vibrating a steering wheel of the vehicle.

Another example of any of the foregoing methods includes providing the alert by vibrating a seat of the vehicle.

Another example of any of the foregoing methods includes providing the alert by inflating or deflating a seat of the vehicle.

Another example of any of the foregoing methods includes providing the alert by cinching a restraint device.

Another example of any of the foregoing methods includes providing the alert to the user within a passenger compartment of the vehicle.

In another example of any of the foregoing methods, the vehicle is moving during the transitioning and the providing.

Another example of any of the foregoing methods includes predicting that the vehicle will drive from a first area through a second area and, in response, transitioning the air dam by raising the air dam from the lowered position to the raised position prior to reaching the second area.

In another example of any of the foregoing methods, the transitioning is based on the second area having rougher terrain than the first area based on a previous drive through the second area.

In another example of any of the foregoing methods, the transitioning is based on the vehicle needing to turn when traveling through the second area.

In another example of any of the foregoing methods, an amount that the air dam is raised during the transitioning depends on a speed of the vehicle, a roughness of terrain in the second area, or both.

An active air dam system according to another exemplary aspect of the present disclosure includes, among other things, an air dam of a vehicle, an actuator assembly that transitions the air dam between a raised position and a lowered position; and a notification system that provides an alert to a user. The alert indicates that the air dam is transitioning.

DETAILED DESCRIPTION

This disclosure details exemplary methods and systems that notify a user, such as a driver of a vehicle, that an active air dam is being lowered or being raised.

With reference toFIG.1, a vehicle10includes an air dam14beneath a front bumper18of the vehicle10. The air dam14is an active air dam that can be transitioned back and forth between a first position and a second position.

In the exemplary embodiment, the air dam14extends continuously from a passenger side of the vehicle10to a driver side of the vehicle10. In another example, the air dam14includes a first air dam portion on the passenger side, and a second air dam portion on the driver side. The first and second air dam portions could be located, respectively, in front of a passenger side front wheel and a driver side front wheel. The first and second air dam portions can be independently controlled.

In the exemplary embodiment, the air dam14is vertically higher when in the first position shown inFIG.2than when in the second position shown inFIGS.1and3. The first position is thus a raised position, and the second position is a lowered position. The first position can be a fully raised or fully retracted position, but that is not required. The second position can be a fully lowered or fully extended position, but that is not required.

When the air dam14is in the first, raised position, the air dam14does not block as much airflow A beneath the vehicle10as when the air dam14is in the second, lowered position. At some speeds, the vehicle10may operate more efficiently when the airflow A beneath the vehicle10is reduced. Accordingly, it may be desirable to transition the air dam14to the second position when the vehicle10is operating at these speeds.

As can be appreciated, the air dam14is closer to the ground G when the air dam14is in the second, lowered position than when in the first, raised position. The air dam14is thus more likely to contact the ground G when the air dam14is in the second position than when the air dam14is in the first position.

The vehicle10includes an actuator assembly22and a control module26. The actuator assembly22can transition the air dam14back and forth between the first and second positions. The actuator assembly22can transition the air dam14in response to a command from the control module26.

In the exemplary embodiment, a user of the vehicle10, such as the driver of the vehicle10, is provided with an alert when the air dam14is transitioning. The components providing the alert can be considered a notification system. The transitioning is cannot be easily viewed by a user when the user is seated in the vehicle10and the vehicle10is moving. The alert informs the user that the transitioning is occurring and reinforces that the vehicle10is equipped with an active air dam, which may be an optional feature the user has paid for. The alert can also, in some examples, indicate that the air dam14is moving to the first position or moving to the second position. The user may desire the air dam14to be in the first, raised position when the vehicle10is stopped for aesthetic reasons. The alert can reinforce that the air dam14has moved or is moving to the desired position as the vehicle10completes its journey.

The alert indicates that the air dam14is transitioning. The user is thus continually reminded that the vehicle10includes the air dam14that is able to transition between the first and second positions. Since the air dam14is typically transitioning when the user is driving the vehicle10, the user does not observe the air dam14transitioning. Providing the alert informs the user that the transitioning is occurring. Thus, the vehicle10can be moving during the transitioning and during the providing of the alert.

The user may drive the vehicle10differently if the user knows about the positioning of the air dam14. When the air dam14is deployed, the user may be more cautious when operating the vehicle10over some types of terrain. If the user knows that the air dam10is retracted, the user can confidently proceed with off-road operation or low-speed maneuvers over uneven or rough conditions, including parking lots with railroad ties, snowbanks, etc.

The user may drive the vehicle10differently if the user knows about the positioning of the air dam14. When the air dam14is deployed, the user may be more careful when operating over some types of terrain. If the user knows that the air dam14is retracted, the user can confidently proceed with off-road operation or low-speed maneuvers over uneven or rough conditions, including parking lots with railroad ties, snowbanks, etc.

With reference now to the schematic view ofFIG.4and continuing reference toFIGS.1-3, the alert could be an audible alert, a visual alert, a tactile alert, or some combination of these. The user can, in some examples, disable the alert feature, or customize the type of alert.

Generally, audible alerts can be heard by the user. Exemplary audible alerts could be an audible ding or chime that is emitted from a speaker30. The audible alerts can be heard by the user within a passenger compartment34of the vehicle10in this example.

Generally, visual alerts can be seen by user. Exemplary visual alerts could include illuminating an icon38within an instrument cluster42of the vehicle10. Another example visual alert could be an adjustment to light emitted by an illumination system46of the vehicle10. Such an adjustment could be a flashing of one or more lights50of the vehicle10, such as cupholder lights. Another adjustment could be changing a color of the lights50—blue to red, for example. Another adjustment could be changing an intensity or color of lights50within the vehicle10, such as ambient lights or outside decorative signature lighting of the vehicle10.

Generally, tactile alerts can be felt by the user. Exemplary tactile alerts could include vibrating a device, such as a steering wheel54or seat58within the vehicle10. Other exemplary tactile alerts could include raising or lowering a steering column62of the vehicle10, or inflating or deflating an air bladder66within the seat58of the vehicle10such that an area of the seat58inflates or deflates and can be felt by a person seated in the seat58. Yet another example tactile alert could include cinching a restraint device70tighter around the user, or causing a massager74of the seat58to vibrate the user within the seat58.

In some examples, the type of alert changes based on the transitioning. For example, a first type of alert may be provided when the air dam14is being lowered and transitioning from the first position to the second position. A second, different type of alert can then be provided when the air dam14is being raised and is transitioning from the second position to first position. The first alert could include a single audible beep and the icon38being illuminated within the instrument cluster42. The second alert could include a double audible beep and a different, second icon being illuminated within the instrument cluster42.

Another example of changing the type of alert could include vibrating the seat58of the vehicle10according to a first sequence when the air dam14is being lowered and vibrating the seat58of the vehicle10according to a different, second sequence when the air dam14is being raised. The vibrating of the seat58could occur by actuating the massager system74of the seat58.

The transitioning of the air dam14may be relatively slow in some examples. For example, the actuator assembly22could be relatively small and lack the power necessary for a faster transition of the air dam14. The actuator assembly22could also take considerable time to transition the air dam14due to temperature effects, aging/dirty mechanisms, etc.

If the vehicle10is traveling at high speeds, in may be beneficial for the transitioning to occur more rapidly than if the vehicle10is traveling at lower speeds. That is, if the vehicle10is travelling at a high speed and enters a rough section of road with the air dam14in the second position, there may be very little time to raise the air dam14. r

The example vehicle10is configured to continually retrieve information relating to road conditions, and particularly the roughness of the terrain. For example, during a drive cycle, if the vehicle10traverses over particularly rough terrain that could potentially lead to damaging contact between the road surface and the air dam14, the vehicle10can record information about the location of the rough terrain. The information can be stored as a Global Positioning System coordinates. The information can be saved remotely from the vehicle10, saved within a memory portion78of the vehicle10, or both.

During a subsequent drive cycle, when the vehicle10is approaching the location of the rough terrain, the control module26can command the actuator assembly22to proactively retract the air dam14to avoid damage.

In this example, the control module26initiates the raising of the air dam14based, at least in part, on information obtained during a previous journey of the vehicle10over the rough terrain. In another example, the control module26could obtain the information indicating that rough terrain is upcoming from GPS mapping, which can, in some examples, include road surface information.

In this example, the control module26can thus predict that the vehicle10will drive from a first area through a second area and, in response, transition the air dam14by raising the air dam14from the lowered position to the raised position prior to reaching the second area. The prediction of the vehicle10driving through the second area can be based on a route input by the user, or can be based on a road that the vehicle10is currently traveling on, and an upcoming section of that road. The transitioning can be based on the second area having rougher terrain than the first area based on a previous drive through the second area.

As can be appreciated, braking and cornering of the vehicle10, especially aggressive braking and cornering, can cause the air dam14to move vertically against the road R, which can potentially damage the air dam14. In addition to recalling information about rough terrain, the vehicle10may recall information about areas of the road R that potentially require aggressive cornering or braking. The vehicle10can then proactively raise the air dam14when approaching these areas of the road.

For example, if the vehicle10leans heavily while it goes around a freeway cloverleaf, the air dam14can be raised when the vehicle10is approaching the cloverleaf. The information relating to rough terrain, aggressive cornering, and aggressive braking can be stored in a look-up table within the memory portion78or outside the vehicle10.

Swaying or braking of the vehicle10due to avoiding objects, such as other vehicles, may be recognized by machine learning of Advanced Driver Assistance System camera pictures. These types of maneuvers may not be stored for recalling later in connection with transitioning the air dam14as these types of maneuvers are unlikely to be repeated or associated with a particular area.

A distance that the air dam14is retracted in response to upcoming rough terrain, an upcoming aggressive cornering or braking can be stored in the lookup table and can vary based on, for example, temperature and vehicle speed. The temperature part of the lookup table can be continually updated based on a moving average of retraction time at temperature.

With reference not toFIG.5, an example method100of storing information for air dam transitioning beings at a step110. Next, at a step120, when the vehicle10is travelling, a roughness of the terrain is compared to a roughness threshold value. If the roughness of the terrain does not exceed the roughness threshold value, the method100returns to the start. If the roughness of the terrain does exceed the roughness threshold value, the method100moves to a step130where the location of the rough terrain is stored using GPS coordinates, for example.

With reference not toFIG.6, an example method200of storing information for air dam transitioning beings at a step210. Next, at a step220, when the vehicle10is travelling, swaying and braking of the vehicle10is continually monitored. If the swaying or braking at a particular location causes the air dam14to contact a surface of the road, the method200moves to the step230. At the step230, the method200assesses whether the swaying or braking was due to an object or vehicle in the road. If so, the method200returns to the step210. If the swaying or braking was not due to an object or vehicle in the road, the particular location is saved at a step240.

Referring toFIG.7, a method300of assigning retraction times for the air dam14begins at a step310. Next, at a step320, the method300assesses whether the air dam14has been commanded to retract. If not, the method300returns to the step310. If the air dam14has been commanded to retract, the method300moves to the step330where the time it takes for the air dam14to retract is measured and stored in a look-up table.

As can be appreciated, retracting the air dam14may take more time in cold weather than warm weather. By storing times associated with temperatures in the look up table, the command to transition the air dam14can be issued far enough in advance of approaching a rough section of road to permit the air dam14to be fully transitioned to a raised position. That is, in colder weather, the command to transition to the raised position in response to upcoming rough terrain may be issued sooner than if the vehicle10is traveling in warmer weather.

In addition to commanding the air dam14to retract, the control module26may pre-charge brakes or adjust trailer brake sensitivity in response to an upcoming road condition, such as a sharp corner or rough terrain. Precharging the brakes of the vehicle10can enhance braking readiness, which can in turn reduces stopping distances in emergency situations. The precharging can cause the brake pads to press lightly against the brake discs, ensuring that the brake system is optimally prepared for the upcoming braking.

In addition to commanding the air dam14to retract, the control module26may temporarily close Active Grille Shutters in response to an upcoming road condition such as a sharp corner or rough terrain. Closing the Active Griller Shutters can protect a cooling system of the vehicle from potentially damaging debris.

In addition to commanding the air dam14to retract, the control module26may lock an electrical glove box release and/or prevent seat and steering wheel adjustments in response to an upcoming road condition, such as a sharp corner or rough terrain.

In addition to commanding the air dam14to retract, the control module26may reduce a sensitivity of capacitive switches within the vehicle10in response to an upcoming road condition, such as a sharp corner or rough terrain. Reducing the sensitivity of capacitive switches can prevent inadvertent actuation. The switches may be located in an overhead console or instrument panel of the vehicle10.

The amount that the air dam14is extended or retracted can be varied based on a ride height of the vehicle10. If, for example, the vehicle10is carrying a heavy load, the air dam14may need to be retracted farther to avoid contact with the road than if the vehicle10were carrying a lighter load. The vehicle10could include sensors with shocks of the vehicle10that monitor the position of the shocks to assess a right height of the vehicle. In other examples, the vehicle10could include height sensors that rely on ultrasonic or RADAR to assess a ride height of the vehicle10.

In some examples, the sensors in the shocks can reveal that the vehicle10is heavily loaded in its rear, which can cause a front of the vehicle10to be slightly raised. The air dam14can be extended further when the vehicle10is loaded in this way rather than if the vehicle10were more evenly loaded. Example if vehicle is evenly heavily loaded the air dam may not extend as far.

Some features of the disclosed examples include alerting a user to a transitioning of an air dam using an alert. The user can turn off or on the alert feature via a touch screen interface, for example. The alert can be an audible ding or chime (similar to what is done on an airplane to warn of turbulence) along with visual indication on cluster

The alert can be a change in the interior/exterior lighting, a cinching of a restraint device, or some combination of these.

Features providing improved control of the air dam can include “remembering” rough sections of road via GPS and reacting prior to encountering those rough section again by proactively transitioning the air dam. Another feature is the distinguishing between vehicle sway cause by speed (around a corner for example) remembering this for later use and vehicle sway caused by objects/vehicle in the road which are not remembered.

A distance that air dam begins to retract in advance of a previous rough road section is a SW lookup table based on temperature and vehicle speed. In addition to transitioning the air dam, the vehicle and/or trailer brakes can be precharged, and an active grille system can be closed. The precharging prepares the brakes for use. The closing of the active grille system helps prevent road debris from damaging components of the vehicle. The electrical glove box release can be locked in advance of rough terrain, and adjusting seat or steering wheel positions may be prevented. Further, switch sensitivity of may be reduced to hinder inadvertent actuation. The air dam extension can be varied based on vehicle ride height. Assessing the ride height can take into account both even and uneven loading (back heavily loaded causing front to rise slightly).