U.S. patent application number 12/985167 was filed with the patent office on 2012-07-05 for aerodynamic package for an automotive vehicle.
This patent application is currently assigned to FORD GLOBAL TECHNOLOGIES, LLC. Invention is credited to Kemal Curic, Andrea Di Buduo, Stefan Lamm, Patrick Verhee.
Application Number | 20120169085 12/985167 |
Document ID | / |
Family ID | 46320074 |
Filed Date | 2012-07-05 |
United States Patent
Application |
20120169085 |
Kind Code |
A1 |
Verhee; Patrick ; et
al. |
July 5, 2012 |
AERODYNAMIC PACKAGE FOR AN AUTOMOTIVE VEHICLE
Abstract
A vehicle having an aerodynamic splitter for the front of a
vehicle is provided. The splitter includes a splitter panel which
has a top surface adapted to be mounted to a front fascia of a
vehicle. The top surface is contoured and offset from the front
fascia in order to define an airflow opening between the front
fascia and the splitter panel. The airflow opening directs air
under the vehicle therethrough in order to create a down force on
the vehicle
Inventors: |
Verhee; Patrick; (Koeln,
DE) ; Lamm; Stefan; (Koeln, DE) ; Di Buduo;
Andrea; (Koeln, DE) ; Curic; Kemal; (Dortmund,
DE) |
Assignee: |
FORD GLOBAL TECHNOLOGIES,
LLC
Dearborn
MI
|
Family ID: |
46320074 |
Appl. No.: |
12/985167 |
Filed: |
January 5, 2011 |
Current U.S.
Class: |
296/180.1 ;
296/181.5 |
Current CPC
Class: |
Y02T 10/82 20130101;
B62D 35/005 20130101; B62D 35/007 20130101; Y02T 10/88 20130101;
B62D 35/02 20130101 |
Class at
Publication: |
296/180.1 ;
296/181.5 |
International
Class: |
B62D 35/00 20060101
B62D035/00; B60J 9/04 20060101 B60J009/04 |
Claims
1. A splitter comprising a splitter panel having a top surface
adapted to be mounted to a front fascia of a vehicle and contoured
and offset from the front fascia to define an airflow opening
between the front fascia and the splitter panel to direct air under
the vehicle therethrough in order to create a down force on the
vehicle, wherein the bottom surface is contoured to define an
elongate recess along a central portion the elongate recess defined
by a pair of convex protrusions extending from the bottom surface
along a pair of distal ends of the splitter panel.
2. The vehicle according to claim 11 wherein a leading edge of the
splitter panel does not extend forward of the bumper.
3.-4. (canceled)
5. The splitter according to claim 4 wherein the wherein the convex
protrusions are defined by a first wall portion angled outboard and
downward from the central recess and a second wall portion
connected to the first wall portion, the second wall portion angled
outboard and upward from the first wall portion to define the pair
of convex protrusions along the bottom surface.
6. The splitter according to claim 1 wherein the airflow opening is
defined at least along the top surface corresponding to the
elongate recess.
7. The splitter according to claim 1 wherein the splitter includes
at least two attachment arms extending from the top surface adapted
to attach the splitter to the bumper.
8. The splitter according to claim 7 wherein the airflow opening is
defined between the attachment arms.
9. The splitter according to claim 1 wherein the top surface is
contoured to be generally parallel to the bottom surface.
10. The splitter according to claim 1 wherein the convex
protrusions are angled forward.
11. A vehicle comprising: a front fascia have a front grille and a
front bumper; a front splitter panel adapted to be mounted adjacent
a lower surface of the front fascia along a top surface of the
splitter panel, the splitter panel mounted an offset distance from
the front bumper to define an airflow opening between the front
fascia and the top surface of splitter panel in order to direct air
under the vehicle through the airflow opening, wherein the bottom
surface is contoured to define an elongate recess along a central
portion the elongate recess defined by a pair of convex protrusions
extending from the bottom surface along a pair of distal ends of
the splitter panel.
12. The vehicle according to claim 11 wherein the splitter panel
has a bottom surface contoured to define an elongated recess along
a central portion.
13. The vehicle according to claim 11 further comprising rear fins
disposed below the rear bumper.
14. The vehicle according to claim 11 further comprising a rear
spoiler mounted adjacent a roof of the vehicle.
15. The vehicle according to claim 14 wherein the rear spoiler is
integrally formed in a rear body panel to define a rear airflow
opening.
16. The vehicle according to claim 15 wherein the rear spoiler is
formed with a high-mount stoplight, the airflow opening formed
between the stoplight and the rear body panel.
17. A splitter comprising a splitter panel adapted to be mounted to
a front fascia of a vehicle along a top surface, a bottom surface
contoured to define an elongated recess along a central portion,
the panel mounted an offset distance from the fascia to define an
airflow opening between the fascia and the panel to direct air
under the vehicle through the airflow opening wherein the panel
does not extend forward of the fascia.
18. (canceled)
19. The splitter according to claim 17 wherein the bottom surface
is contoured to define an elongate recess along a central portion
the elongate recess defined by a pair of convex protrusions
extending from the bottom surface along a pair of distal ends of
the splitter panel.
20. The splitter according to claim 17 wherein the top surface is
contoured to create a downward force on the vehicle.
21. The vehicle according to claim 11 wherein the wherein the
convex protrusions are defined by a first wall portion angled
outboard and downward from the central recess and a second wall
portion connected to the first wall portion, the second wall
portion angled outboard and upward from the first wall portion to
define the pair of convex protrusions along the bottom surface.
22. The splitter according to claim 11 wherein the splitter panel
does not extend forward of the front fascia.
Description
TECHNICAL FIELD
[0001] The present invention relates to an aerodynamic package for
an automotive vehicle.
BACKGROUND
[0002] Aerodynamic airflow considerations are a priority of vehicle
body design. Effective airflow management over a vehicle body can
be critical in meeting functional demands for passenger compartment
acoustics, fuel efficiency and safety of passenger type vehicles.
Aerodynamic design also enhances vehicles control and improves
speed of passenger vehicles. Front splitters are a common
aerodynamic used to controls airflow around the vehicle and limit
front end lift and creates downforce.
[0003] A front splitter is typically found on the front-end of a
vehicle and appears as a flat extension to the bottom of the front
bumper. Typically, the splitter is rigid and extends straight out,
parallel to the ground and is attached to the bumper with support
rods to ensure the front splitter remains forward of the bumper and
parallel to the ground.
[0004] Depending on its positioning, a front splitter can limit how
much air is directed under the vehicle by slicing through the
incoming air stream and directing a portion of the airflow over the
vehicle body. A front splitter can helpful in preventing front end
lift as well as providing downward force on the vehicle. The
overall reduced lift and increased down force is created by the
flat extension slicing through oncoming air and restricting airflow
along the underbody of the vehicle.
[0005] To understand how a typical splitter prevents lift and
creates downward force it is helpful to understand the fluid
dynamics as oncoming air approaches the front of a vehicle. When
oncoming air reaches the front of the vehicle it must come to a
stop before it turns to move either up and over, down and under, or
around the vehicle. Thus the front of the moving vehicle is an area
of relatively high pressure.
[0006] The relatively high pressure at the front of a moving
vehicle pushes back on the vehicle creating drag. By extending a
front splitter out from the front of the vehicle, the high pressure
will also push down on the top of the splitter.
[0007] Also, the typical front splitter extends below the bumper
close to the road and air flowing underneath the front splitter and
vehicle creates somewhat of a Venturi effect, based on Bernoulli's
equation, where pressure is decreased as air is forced through a
constriction and speeds up in velocity. Thus the region between the
splitter and the pavement is an area of low pressure. This adds up
to a downward force on the splitter.
[0008] The resultant dynamic downward force generally helps the
driver to retain control of the vehicle at higher road speeds. A
front splitter is typically associated with racing vehicles.
However, the aerodynamic principles also apply to passenger
vehicles. But there are several factors which limit a typical front
splitter's aerodynamic effectiveness on a passenger vehicle.
Additionally, front splitters for passenger vehicles must be to
have adequate ground clearance to accommodate suspension and body
movement over dips and potholes, which makes typical splitters
aerodynamically effective. Design considerations for front
splitters are for passenger vehicle are also restricted by
government regulations which typically limit how far a front
splitter may protrude beyond the bumper of a vehicle.
[0009] Utility vehicles, such as sport utility vehicles and pickup
trucks, have also been popular in recent years. As utility vehicles
have become popular for utilization as passenger vehicles,
manufacturers of utility vehicles have incorporated many features
into utility vehicles to enhance fuel efficiency, safety and
control at high speeds.
[0010] Utility vehicles are often designed for travel through rough
terrain. Additionally, utility vehicles are generally designed to
haul cargo, whether in a cargo compartment, a bed of the vehicle,
or by towing cargo with a trailer. In order to meet these extreme
design requirements, utility vehicles are often provided with a
vehicle body that is elevated greater than conventional passenger
vehicles. In order to meet the fuel efficiency and safety standards
while maintaining the elevated cargo compartments in utility
vehicles, front end airflow management of utility vehicles is
required.
SUMMARY
[0011] At least one embodiment of the present invention provides an
aerodynamic splitter for the front of a vehicle. The splitter
includes a splitter panel which has a top surface adapted to be
mounted to a front fascia of a vehicle. The top surface is
contoured and offset from the front fascia in order to define an
airflow opening between the front fascia and the splitter panel.
The airflow opening directs air under the vehicle therethrough in
order to create a down force on the vehicle.
[0012] Another embodiment provides that the front fascia has a
bumper and a grille. A leading edge of the splitter panel does not
extend forward of the front fascia.
[0013] A further embodiment provides that the splitter panel has a
bottom surface contoured to define an elongated recess along a
central portion of the splitter panel.
[0014] An even further embodiment provides that the contoured
central recess is defined by a pair of wall portions along the
bottom surface. The wall portions are angled outboard and downward
from the central recess.
[0015] Another embodiment provides that the bottom surface includes
a second wall portion connected to the first wall portion. The
second wall portion is angled outboard and upward from the first
wall portion to define a pair of convex protrusions along the
bottom surface.
[0016] Yet another embodiment provides that the airflow opening is
defined at least along the top surface corresponding to the
elongate recess.
[0017] Still another embodiment provides that the splitter includes
at least two attachment arms extending from the top surface. The
attachment arms are adapted to attach the splitter to the
bumper.
[0018] A further embodiment provides that the airflow opening is
defined between the attachment arms.
[0019] An even further embodiment provides that the top surface is
contoured to be generally parallel to the bottom surface.
[0020] Another embodiment provides that the convex protrusions are
angled forward.
[0021] At least one embodiment of the present invention provides a
vehicle having an aerodynamic front splitter. The vehicle includes
a front fascia have a front grille and a front bumper. A front
splitter panel is adapted to be mounted adjacent a lower surface of
the front fascia along a top surface of the splitter panel. The
splitter panel is mounted an offset distance from the front bumper
to define an airflow opening between the front fascia and the top
surface of the splitter panel. Air is thereby directed under the
vehicle through the airflow opening.
[0022] Another embodiment provides that the splitter has a bottom
surface contoured. The bottom surface is contoured to define an
elongated recess along a central portion.
[0023] A further embodiment provides that that the vehicle includes
rear fins disposed below the rear bumper.
[0024] An even further embodiment provides that the vehicle
includes a rear spoiler mounted adjacent a roof of the vehicle.
[0025] Another embodiment provides that the rear spoiler is
integrally formed in a rear body panel to define a rear airflow
opening.
[0026] Yet another embodiment provides that the rear spoiler is
formed with a high-mount stoplight, the airflow opening formed
between the stoplight and the rear body panel.
[0027] At least one embodiment of the present invention provides a
splitter panel adapted to be mounted to a front fascia of a vehicle
along a top surface of the splitter panel. The splitter panel
includes a bottom surface contoured to define an elongated recess
along a central portion, the panel mounted an offset distance from
the front bumper to define an airflow opening between the front
bumper and the splitter panel in order to direct air under the
vehicle through the airflow opening.
[0028] Still another embodiment provides that the splitter panel
does not extend forward of the front fascia.
[0029] Yet another embodiment provides that the bottom surface is
contoured to define an elongate recess along a central portion of
the splitter panel. The elongate recess is defined by a pair of
convex protrusions extending from the bottom surface. The convex
protrusions are located along a pair of distal ends of the splitter
panel.
[0030] A further embodiment provides that the top surface is
contoured to create a downward force on the vehicle.
BRIEF DESCRIPTION OF THE DRAWINGS
[0031] FIG. 1 is a perspective view of a passenger vehicle in
accordance with an embodiment of the present invention;
[0032] FIG. 2 is a front perspective view of the passenger vehicle
of FIG. 1;
[0033] FIG. 3 is a rear perspective view of the passenger vehicle
of FIG. 1; and
[0034] FIG. 4 is a rear side perspective view of the passenger
vehicle of FIG. 1; and
[0035] FIG. 5 is a exemplary side section view along section 5-5 of
FIG. 2 according to an embodiment of the present invention.
DETAILED DESCRIPTION
[0036] As required, detailed embodiments of the present invention
are disclosed herein; however, it is to be understood that the
disclosed embodiments are merely exemplary of the invention that
may be embodied in various and alternative forms. The figures are
not necessarily to scale; some features may be exaggerated or
minimized to show details of particular components. Therefore,
specific structural and functional details disclosed herein are not
to be interpreted as limiting, but merely as a representative basis
for teaching one skilled in the art to variously employ the present
invention.
[0037] FIG. 1 illustrates a perspective view of a passenger vehicle
10 including a front splitter panel 12 according to an embodiment
of the present invention.
[0038] The vehicle 10 includes a front end 14 and a rear end 16
with a passenger compartment 18 provided therebetween. The
passenger compartment 18 of the depicted embodiment may include two
rows for passenger seating, for example, a front row and a back row
(not shown). The front row and the back row may each include a pair
of doors on opposed lateral sides of the vehicle 10, such as a
front side door 20 and a back side door 22 illustrated in FIGS. 1
and 2. The side doors 20, 22 are illustrated on a right side of the
vehicle 10. Although the doors for the left side of the vehicle are
not illustrated, the left side doors may generally be a mirror
image of the right side doors 20, 22 because the vehicle 10 may be
generally symmetrical. The passenger compartment 18 is generally
elevated relative to an underlying support surface 24 upon which
the vehicle 10 travels.
[0039] The front end 14 of the vehicle 10 includes the area forward
of the passenger compartment 18 in the longitudinal direction. As
illustrated in FIG. 1, the front end 14 includes a hood 26 defining
an engine compartment 28 therebeneath. The front end also includes
front quarter panels 30 on opposed lateral sides of the vehicle 10.
Each quarter panel 30 defines a front wheel well is illustrated on
a right side of the vehicle 10. The left quarter panel is generally
a mirror image. The engine compartment 28 is located laterally
between the quarter panels 28.
[0040] The front end 14 also includes a front fascia 34. The front
fascia 34 is generally located forward of the hood 26 and quarter
panels 28. The front fascia 34 includes the front grille 36 and the
bumper 38. The front grille 36 defines an opening to the engine
compartment 28 in order to allow airflow into the air induction
system and for cooling of the engine compartment 28. The grille 36
may be designed for vehicle styling and aesthetic appeal and may
also include the vehicle manufacturer logo or may have ornamental
design characteristics.
[0041] The bumper 38 provides energy absorption in the event of a
front impact crash. As such, the bumper 38 may extend forward of
the grille 36, or as illustrated, the bumper 38 may be generally
flush with the grille 36.
[0042] FIG. 2 illustrates the front perspective view of the
passenger vehicle 10 including the front splitter 12. The front
splitter 14 may be mounted adjacent a lower surface 40 of the
bumper 38 or the front fascia 14. The front splitter 12 is mounted
to the bumper 38 along a top surface 42 of the splitter panel 12.
The splitter panel 12 may be mounted an offset distance from the
front bumper 38 so that the splitter 12 is not flush with the
bumper 38 in the vertical direction. An airflow opening 44 is
defined between the front fascia 34 and the top surface 42 of the
splitter panel in order to direct air under and along the underbody
46 of the vehicle 10 through the airflow opening 44.
[0043] Unlike typical splitters which extend from the bumper and
are located close to the ground to prevent air from flowing
underneath the vehicle, utility passenger vehicles must maintain a
minimum ground clearance in order to prevent colliding with
obstacles. Therefore, the front splitter panel 12 extends a minimal
distance from the bumper 38 and instead prevents lift and generates
a downward force by directing airflow under the vehicle 10 through
the airflow opening 44.
[0044] FIG. 5 illustrates a side section view along section 5-5 of
FIG. 2 according to an embodiment of the present invention. The
airflow opening 44 constricts oncoming air along the front end 14
of the vehicle 10. The airflow opening 14 creates somewhat of a
Venturi effect where pressure is decreased as it flows through the
constriction of the airflow opening 44. Therefore, the airflow
opening 44 creates a region of low pressure which adds to a
downward force on the splitter panel 12.
[0045] The airflow opening 44 may be defined by the offset distance
between the front fascia 34 and the top surface 42 of the splitter
12. The airflow opening 44 may be defined along the entire length
of the splitter panel 12 between the front quarter panels 30.
Alternatively, the airflow opening 44 may be defined along only a
portion of the top surface 42 in order to create a further
constriction by having a smaller opening. For example, the splitter
12 may be mounted to the front fascia 34 with attachment arms 48
which are spaced apart. The airflow opening 44 is defined only
between the attachment arms 48 along a central portion 50 of the
splitter panel 12.
[0046] Referring again to FIG. 2, the splitter panel 12 may also
include a contoured bottom surface 50. Whereas typical splitters
are parallel to the ground 24, the splitter panel 12 may be
contoured to provide additional clearance for utility vehicles 10.
The contoured bottom surface 52 may define an elongated recess
along the central portion 50 of the splitter panel 12. The
elongated recess 54 may define a second constriction for oncoming
air along the front end 14 of the vehicle 10. Similar to the
airflow opening 14, the elongated recess 54 may create somewhat of
a Venturi effect where pressure is decreased as it flows through
the constriction of the elongated recess 54. Therefore the
elongated recess 54 also creates a region of low pressure.
[0047] By defining the airflow opening 44 and the elongated recess
54 along the central portion 50 of the front end 14, the high
velocity, low pressure oncoming air is directed under the underbody
28 along a midline of the vehicle 10 and away from the tires where
the drag is less. Consequently, the central portion 50 is inboard
of the tires and wheel wells 32.
[0048] In one embodiment, the airflow opening 44 is defined at
least along the top surface 42 corresponding to the elongate recess
54. The airflow opening 44 may be the same lateral width as the
elongated recess 54 and extend along the central portion 50
adjacent each other. It is also contemplated that the top surface
may be contoured in the lateral direction to be generally parallel
to the bottom surface 52.
[0049] The elongated recess 54 is defined by a pair of wall
portions 56 along the bottom surface 52. The wall portions 56 may
be angled outboard in the lateral direction and downward from the
central portion 50. The bottom surface 52 may also include a pair
of second wall portions 58 connected to the first wall portions 56
to define a pair of convex protrusions 60 along the bottom surface
at the distal ends of the splitter panel 12. The second wall
portion 58 may be angled outboard and upward from the first wall
portion 56.
[0050] In one embodiment, the front splitter 12 may not extend
forward in the longitudinal direction of the bumper 38. In another
embodiment, while the central portion 50 of the splitter panel 12
may not extend beyond the front fascia 34 in the forward direction,
the convex protrusions 60 are angled forward of the front fascia
34.
[0051] Referring again to FIG. 5, the front splitter panel 12 may
have a top curvature shape 62 in the longitudinal direction along
the top surface 42. The top curvature shape 62 is formed along the
airflow opening 44 thereby directing airflow under the vehicle 10.
The splitter panel 12 may also have a bottom curvature shape 64 in
the longitudinal direction along the bottom surface 52. The bottom
curvature shape 64 is formed along the elongated recess thereby
directing airflow under the vehicle. The lower surface 40 of the
bumper 38 or fascia 34 may also have a lower curvature shape 66 in
the longitudinal direction along the airflow opening 44.
[0052] The top and bottom and lower curvature shapes 62, 64, 66 may
be designed in order to preserve laminar flow along the underbody
46 and diffuse airflow. The top, bottom and lower curvature shapes
62, 64, 66 may be developed according to an empirical data and
iterative airflow testing in a wind tunnel or computer model. As
such, the top and bottom and lower curvature shapes 62, 64, 66 may
be generally parallel to each other. Alternatively, the top and
bottom and lower curvature shapes 62, 64, 66 may have independent
curvature profiles. The curvature shapes may be defined so that the
splitter 12 effectiveness is maximized when airflow being directed
to the vehicle underbody 46 remains laminar and smooth. Providing
laminar underbody 46 airflow reduces drag and therefore allows the
vehicle aerodynamic efficiency to remain generally unaffected.
[0053] The top and bottom curvature shapes 62, 64 may extend a
distance rearward under the vehicle 10 to align with the underbody
profile 46. The longer the constriction regions formed by the
airflow opening 44 and the elongated recess 54, the more downward
force that may be generated. The underbody 46 may also be formed
with a tunnel portion (not illustrated) which may keep airflow
speed high along the length of the underbody 46. It is contemplated
that the tunnel portion may be formed by underbody structure, such
as a deployable rocker panel 68. The disclosure of a deployable
rocker panel 68 is disclosed in application Ser. No. 12/985,069
which is incorporated by reference herein in its entirety.
[0054] FIGS. 3 and 4 illustrate a rear perspective view of the
passenger vehicle 10. The rear end 16 of vehicle 10 may also
include aerodynamic features which may cooperate with the front
splitter 12 to improve the fuel efficiency, safety and handling of
the passenger vehicle 10.
[0055] The rear end 16 of the vehicle 10 may include a rear hatch
70 which may provide access to cargo space or the passenger
compartment 18. The rear hatch 70 is defined laterally between the
rear quarter panels 72 on opposed lateral sides of the vehicle 10
and may be attached to a rear body panel 74 or the roof 76. The
rear quarter panel 72 defines the rear wheel well 78 and is
illustrated on a right side of the vehicle 10. The left rear
quarter panel is generally a mirror image of the right.
[0056] The rear end 16 also includes a rear bumper 80. The rear
bumper 80 provides energy absorption in the event of a rear impact
crash. As such, the bumper 38 may protrude rearward from the
profile of the rear hatch 70 and quarter panels 72.
[0057] The rear end 16 may also include a rear fin 82 disposed
below the rear bumper 80. The rear fin 82 may have an upswept
contour surface 84 that extends from the underbody 46 to the rear
bumper 80 and may also include raised fin portions 86 which follow
the upswept contour 84. The rear fin 82 may act as a diffuser by
improving the transition area between the high-velocity airflow
underneath the vehicle 10 and the atmosphere behind the vehicle 10.
The rear fin 82 may include exhaust outlets 88 formed therein.
[0058] The rear end 16 may also include a rear spoiler 90 adjacent
the roof 76 of the vehicle 10. The rear spoiler 90 may be mounted
along an upper portion of the rear body panel 74 or the rear hatch
70 adjacent the roof 76. In another embodiment, the rear spoiler 90
may be integrally formed in the rear body panel 74 or the rear
hatch 70 to define a rear airflow opening 92. As illustrated in
FIGS. 3 and 4, the rear spoiler may also be integrally formed with
a high-mount stoplight 94. As such, the rear airflow opening 92 may
be formed between the stoplight 94 and the rear body panel
[0059] The rear spoiler 90 acts to modify the laminar airflow
passing over the vehicle 10 by increasing turbulence flowing over
the rear spoiler 90 or through the rear airflow opening 92.
[0060] While various embodiments are described above, it is not
intended that these embodiments describe all possible forms of the
invention. Rather, the words used in the specification are words of
description rather than limitation, and it is understood that
various changes may be made without departing from the spirit and
scope of the invention. Additionally, the features of various
implementing embodiments may be combined to form further
embodiments of the invention.
* * * * *