Deployable vehicle access ramp

An access ramp for a van or a similar vehicle having a housing below the vehicle floor and adjacent door which houses the ramp structure. A carrier is extendable and retractable and is mechanically linked to a ramp platform. A boom arm on the carrier extends when the carrier extends and guides a cable which is motor driven to lower and lift the platform. Lift cams elevate the inner end of the platform when the platform is extended to bring it into close proximity with the vehicle floor.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to vehicle access ramps and more particularly 
relates to ramps which are deployable from a position in which the ramp is 
stored below the vehicle floor to an extended, inclined position to assist 
disabled persons entering and exiting the vehicle. 
There is a recognized need for access ramps or platforms which will assist 
persons, particularly disabled persons, in entering and exiting motor 
vehicles, either as a passenger or as a driver. The Americans With 
Disabilities Act has as a stated objective the removal of physical 
obstacles to those with handicaps or disabilities. Because of the stated 
objectives of this legislation and an increased public awareness and 
concern of the requirements of the disabled, there has been more emphasis 
in providing systems which assist a wheelchair occupant or other disabled 
person a convenient and safe way of entering or leaving a motor vehicle. 
In many cases, once access to the vehicle is obtained, the person can 
operate the vehicle which may be provided with special operator controls. 
2. Description of Related Art 
Some of the earlier design efforts in this area include power-operated 
ramps to facilitate wheelchair passengers in entering and leaving public 
vehicles such as buses. U.S. Pat. No. 4,131,209 discloses a ramp for a 
motor bus which, when the door is opened, accommodates lateral outward 
extension of a ramp from a normally stowed position below the floor of the 
bus. A portion of the ramp adjacent its outer end serves as a step for 
entering the bus when the ramp is in the stowed position. The device is 
powered by a motorized lead screw. When extended, the ramp moves outwardly 
through the entranceway and automatically tilts upwardly towards its inner 
end to provide an inclined platform from the sidewalk or roadway to the 
vehicle. A further improvement to this ramp is shown in U.S. Pat. No. 
4,685,858. 
U. S. Pat. No. 4,479,753 discloses another approach to the problem of 
providing accessibility to vehicles. A lift is shown which may be retrofit 
to a van which lift is hinged on a vertical axis to a door post adjacent 
the door hinge. A horizontal carrier allows the unit to slide to clear the 
vehicle structure and then a vertical carrier descends from the horizontal 
carrier powered by a hydraulic actuator. A folding platform then swings 
down on its horizontal hinge along the lower edge of the vertical carrier. 
In the deployed position, the platform is vertically moved on the vertical 
carrier and is subsequently stowed by swinging the platform vertically 
against the horizontal and vertical carriers so that the entire lift 
package when not deployed is conveniently stowable. 
Another type of vehicle-mounted access ramp for a wheelchair user is shown 
in U.S. Pat. No. 3,874,527. In this patent, the vehicle door is modified 
to hinge about a horizontal axis along or below the lower edge of the 
door. The inner surface of the door is modified to provide a ramp surface. 
The door is raised and lowered by a power assembly. Approach ramp pivots 
along the normal upper door edge provides a smooth ramp surface from the 
ground to the inner door surface when the door is lowered. 
U.S. Pat. No. 4,827,548 discloses an extendable and retractable ramp 
assembly for facilitating wheelchair passengers to and from a bus or van. 
The invention has an extendable and retractable ramp which includes a 
power actuating mechanism disposed in the vehicle which includes a track 
mechanism and roller elements mounted on the ramp which elevate the inner 
end of the ramp to the approximate level of the floor of the bus or van. 
Further improvements in ramps of this type are found in U.S. Pat. No. 
5,160,236 which ramp has been commercialized by the assignee of this 
application, Care Concepts, Inc., of Phoenix, Ariz. This patent shows a 
retractable van side door ramp which has a short base end section and a 
longer outer end section which are pivotally connected. The ramp assembly 
is mounted from the floor structure of the van and is extendable and 
retractable at the side of the van below the door opening. The ramp 
assembly is supported during a portion of the extension and the retraction 
and as the ramp approaches the fully extended position, the outer ramp 
platform pivots to a position on the ground or curb so as to not shovel. 
The reverse operation takes place during retraction. The ramp may be 
powered by various manual or mechanical drive arrangements including 
electric motors or cable and gear systems. 
While the above patents as well as various patents disclosed therein 
disclose various systems for assisting disabled persons and persons 
confined to a wheelchair in entering and exiting a motor vehicle, there 
nevertheless exists a need for a simplified and efficient ramp which 
provides vehicle accessibility and which ramp complies with the 
requirements and spirit of the Americans With Disabilities Act. 
SUMMARY OF THE INVENTION 
Accordingly, it is a broad object of the present invention to provide a 
loading and unloading ramp for use in conjunction with a vehicle which has 
a ramp that is particularly suitable for use by disabled persons. 
It is another object of the present invention to provide a retractable and 
deployable ramp structure which may be conveniently retrofit to existing 
vehicles, particularly side door minivans. 
It is another object of the present invention to provide a ramp structure 
which is simple and efficient and which may be originally incorporated or 
retrofit into the body structure of the vehicle. 
It is still another object of the present invention to provide a ramp which 
when deployed extends horizontally and having a mechanism which allows the 
ramp outer end to pivot downwardly at or near the end of the deployment 
cycle to provide a gradually inclined surface from the curb or roadway to 
the floor of the vehicle. 
It is another object of the present invention to provide a ramp assembly 
design which simplifies the installation operations necessary. 
It is another object of the present invention to provide an access ramp 
which is mounted beneath the floor structure of a side door van and is 
extendable and retractable at the side of the van immediately adjacent the 
floor of the van at the door opening. 
Briefly, in accordance with the foregoing objects, a vehicle access ramp 
assembly is provided which assembly has a planar floor or platform for 
longitudinal extension and retraction from a stowed position in the van. 
The ramp assembly includes a housing positioned adjacent the vehicle door 
opening as, for example, below the floor of the van adjacent the side 
door. A carrier is extendable and retractable on rollers at opposite 
longitudinal sides of the housing structure. The carrier is mechanically 
connected to the ramp platform. The carrier has a boom arm which projects 
horizontally outwardly from the side of the vehicle when the ramp is 
extended. A reversible electric carrier drive motor is mounted to the 
housing in a fixed position and through a chain, cable, belt or rack/gear 
with mating pinion gear reversibly drives the carrier which, in turn, 
moves the ramp platform from a retracted to a deployed position and 
return. A second reversible electric lift motor is positioned on the 
carrier to move with the carrier. The lift motor operates a cable and at a 
predetermined location along the deployment and retraction cycle will 
either the pay-out cable or take-up the cable to selectively control the 
position the outer end of the ramp platform to permit it to swing 
downwardly to provide a gradually inclined surface to return the ramp to a 
substantially horizontal position for retraction and storage. Lift cams on 
the sides of the ramp platform elevate the inner end of the ramp platform 
to bring it into close proximity to a transition plate attached to the 
vehicle floor when the ramp is fully deployed. Braces on the carrier move 
into a supporting position beneath the inner end of the ramp platform when 
the ramp platform is deployed to reinforce the ramp. 
The assembly includes an operational control system which includes 
electrical switches positioned to control the operation of the carrier 
drive motor and the lift motor during the extension and retraction 
operations. Provision is also made to permit manual operation of the ramp.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Turning now to the drawings, the ramp assembly is generally designated by 
the numeral 10 and in FIG. 1 is shown in a deployed position in 
conjunction with a vehicle 12 which vehicle is representative of the type 
of vehicle generally designated as a minivan such as those manufactured by 
Chrysler Corporation under the model designation Caravan, and Town and 
Country Voyager. It is to be understood that the ramp assembly 10 may be 
employed or adapted to various types and models of vehicles of various 
manufacturers including vans and buses to permit persons, particularly 
disabled persons convenient entry and egress from the vehicle. The vehicle 
12 is shown as having side door 14 which is shown in the open position so 
a person can conveniently enter and leave the van through side opening 16. 
In the deployed position, the ramp assembly of the present invention 
provides a ramp platform 40 which serves as a bridge from the roadway 15 
on which a person may either walk or on which a wheelchair or motorized 
cart may be driven to access the vehicle. The ramp is designed in 
accordance with the provisions of the American Disabilities Act (ADA) 
which specifies a maximum one-to-four rise or incline of the ramp 
platform, a minimum width of 30", minimum 2" high side rails and a load 
capacity, of 600# with a safety factor of at least 3 based on the ultimate 
strength of the material. 
The ramp assembly is disposed within a box-like housing structure 18 which 
is normally positioned beneath the floor or deck 20 of the van at a 
location aligned with the door opening 16 so that in the deployed 
position, the ramp platform 40 extends from an opening 30 at the lower 
portion of the door opening as shown in FIG. 1. A transition plate 21 may 
be provided at the edge of the floor 20. Once the person enters the 
interior of the vehicle by means of the ramp, the person may either assume 
a position as a passenger at the rear of the van or may be seated at the 
steering wheel in a position to operate the van. Many persons confined to 
a wheelchair operate motor vehicles and often vans are modified and 
equipped so that the wheelchair may be positioned and locked behind the 
steering wheel in the normal vehicle operator's position. Special operator 
controls may also be provided. 
Turning now to the drawings, particularly FIGS. 2 to 6, the ramp assembly 
10 is shown in greater detail. FIG. 2 shows the ramp assembly mounted in 
the vehicle with a portion of the vehicle floor 20 removed to better 
reveal the ramp structure. In the normal installed position, the floor 20 
of the vehicle extends as a cover for the ramp assembly so that it is in a 
concealed and out-of-the-way position. 
The ramp assembly is mounted within a box-like housing structure 18 which 
is preferably attached to the vehicle and vehicle frame below the floor 
20. The ramp assembly may be provided as an OEM component of the 
manufactured vehicle or retrofit by appropriate modifications in a manner 
which will not detrimentally effect the structural integrity of the 
vehicle body and chassis. The housing has opposite side walls 22 and 24 
which are preferably structural Z-members having an upper leg attached to 
the underside of the floor 20. A vertical wall 25 extends between the end 
of the Z-sections 22 and 24 at the inner end of the housing. For purposes 
of orientation, the term "outer" refers to the area of the ramp assembly 
disposed adjacent the door opening 16 and the terms "inner" or "rear" 
refer to the area at the opposite end of the ramp assembly. A panel of 
sheet steel extends between the lower legs of the Z-section and defines 
the bottom 28 of the housing. Opening 30 is defined at the front of the 
ramp assembly which opening is disposed immediately subjacent the edge of 
the floor 20 at the door opening 16 of the vehicle. When the vehicle door 
is closed, the opening 30 is concealed by the vehicle door. Transition 
plate 21 angles downwardly from the edge of the vehicle floor 20 to extend 
in close relationship with the ramp platform 40. 
As indicated above, the ramp assembly includes a ramp or platform 40 which 
is slidable with respect to the housing 18 and in the retracted position 
is fully contained within the housing beneath the floor of the vehicle in 
an out-of-the way position. In the extended or deployed position, the ramp 
platform extends outwardly providing an inclined bridge surface extending 
from the road surface or curb 15 to the floor of the van. 
The ramp platform 40 has a generally horizontal floor 42 with integrally 
formed upstanding flanges 44 and 46 positioned at the opposite sides of 
the ramp. The flanges 44 and 46 are spaced inwardly from the opposite 
sides of the vertical sides of the housing 22 and 24. Platform 40 has 
inner edge 47 and outer edge 48 which extend transversely between the 
flanges. 
Retraction and extension or deployment movement is imparted to the ramp by 
means of a carrier 50 which is powered by drive motor 60 secured to the 
housing floor 28. The carrier 50 has a transversely extending bottom plate 
55 having a front edge 56 and a rear edge 58. A recess 59 is provided in 
the rear edge 58 of the carrier plate. A lift motor 62 is mounted on the 
carrier plate 55 adjacent the forwardly extending boom arm 66. Another 
boom arm 68 extends forwardly from the opposite side of the carrier. Boom 
arms 66 and 68 are similar in construction, although boom arm 66 is longer 
so that when the ramp platform is in the fully deployed position, the boom 
arm 68 extends outwardly from the side of the vehicle at least part way 
above the ramp platform as seen in FIG. 1. For example, ramp platform 40 
may be typically 4' in length so that in the forward, fully deployed 
position, boom arm 66 extends approximately 2' to 3' from the side of the 
van. Boom arm 68 in the deployed position extends only to the approximate 
edge of the vehicle chassis. 
The carrier 50 is guided along its path of movement by the boom arms 66 and 
68. Each of the boom arms 66, 68 has a channel configuration as shown in 
FIG. 3. The boom arms each define longitudinally extending slots which are 
disposed toward the adjacent side walls of the housing which slots each 
define a track 75. A plurality of roller assemblies 70A, 70B and 70C are 
disposed at spaced-apart locations along the opposite side wall 22 of the 
housing. Each of the roller assemblies has a cylindrical wheel 79 
rotatable about an axle 78 which is fixed to the housing side walls 22. 
The wheels 79 are received within the tracks 75 in the boom arm 66. 
A plurality of similarly constructed roller assemblies 72A, 72B, and 72C 
are provided at spaced-apart locations along side wall 24 and are received 
within the longitudinal track extending along boom arm 68. Thus, as the 
carrier moves in and out, the travel of the carrier is smoothly guided by 
one or more pairs of the wheels 70, 72, etc. When the ramp platform is 
fully retracted, all wheels are positioned within the track 75 in the boom 
arms and as the ramp is deployed, the carrier passes along the roller 
assemblies and in the fully extended position, the boom arms clear the 
roller assemblies, 
The carrier 50 drives the ramp platform and is mechanically connected to 
the ramp platform 40 at opposite sides of the carrier by means of a pair 
of links 80 and 82. Link 80 interconnects the carrier 50 and ramp platform 
40 at the aft side of the ramp platform and link 82 connects the carrier 
and platform at the forward side of the assembly. The terms "forward" and 
"aft" are used with respect to the normal vehicle orientation and travel. 
Link 80 is pivotally connected to flange 44 at pivot point 84. The 
opposite end of link 80 is pivotally connected to the rear of the ramp 
assembly at pivot point 86 which is located adjacent the upper edge of the 
ramp wall 46 near the rear of the ramp. Link 82 is similarly positioned 
extending between pivot point 84A on the inner side of boom arm 68 and 
pivot point 86A disposed on side wall 44 of ramp platform 40. 
In the retracted position and during a substantial portion along the 
deployment path of the ramp, a portion of the ramp floor along edge 47 of 
the ramp platform overlaps the forward edge 58 of the carrier assembly as 
seen in FIGS. 6 and 7. A predetermined gap (.DELTA.) is maintained between 
the inner edge 47 of the ramp assembly and braces 90 and 90A. Braces 90 
and 90A are welded or otherwise secured to the upper surface of the 
carrier plate and each has a vertical front wall 92 and a rearwardly 
extending angular brace member 94. The overall height of front wall 92 is 
approximately half the height of the side walls of the ramp platform. The 
brace members 90 and 90A serve to reinforce the inner end of the ramp 
platform when the ramp is deployed as seen in FIG. 7 and will be more 
fully explained hereafter. 
A roller 98 is rotatable about a horizontally extending axis which extends 
inwardly from ramp side wall 44 vertically aligned and below pivot 86. A 
roller 98A is similarly positioned on the inner side of the opposite ramp 
side wall 46. 
The ramp assembly drive system imparts linear motion to the carrier which 
through the links 80 and 82 transmit motion to the ramp platform 40 to 
cause the ramp to deploy and retract. The drive assembly consists of an 
electric drive motor which may be a conventional reversible window lift 
motor of the type commercially available from various manufacturers. The 
motor is secured to the floor 28 of the housing 18 at a rear location so 
that when the carrier is fully retracted, the motor is positioned within 
the recess 59 at the rear of the carrier. As seen in FIG. 2, the carrier 
drive motor has a vertically extending output shaft 102 on which is fixed 
gear sprocket 104. An idler gear 110 is rotatively disposed on a shaft 112 
which depends from stringer member 114 located toward the outer end of the 
ramp assembly extending transversely between the opposite side walls 22 
and 24 of the housing 18. 
A continuous drive chain 125, shown as a bicycle or pintle-type chain, 
extends around the driven gear sprocket 104 and the idler sprocket 110. A 
chain tensioning device 130 maintains the proper tension on chain 125 by 
applying a tensioning force to a section of the chain extending between 
the sprockets. The chain tensioning device 130 consists of an idler 
sprocket 126 rotatably mounted on the outer end of arm 128. Arm 128 is 
pivotally mounted at an intermediate location to cross member 134 
extending transversely between the side walls of the ramp assembly pan. 
The opposite end of arm 128 is attached to one end of a tensioning spring 
135 which has its opposite end secured to axially extending cross member 
134. Thus, it will be seen that as the carrier 50 traverses inwardly and 
outwardly, the tensioning device 130 will maintain the proper tension of 
the chain. Although a chain is shown as a preferred power transmitting 
means, other equivalent means such as cables or belts may be used. 
The carrier 50 is attached to the straight section of chain 125 extending 
between the drive sprocket 104 and idler sprocket 110. As best seen in 
FIGS. 2, 9 and 10, the chain 125 is secured to the carrier by means of a 
pair of oppositely disposed pick-up brackets 140 and 142 which have 
upstanding legs 144, 144A, respectively, which define elongated slots 146 
and 146A, respectively. The slots 146 and 146A are aligned with an 
aperture 148 in a selected one of the chain links of chain 125. A pin 150 
extends through the aperture 148 and slots and 146, 146A. Thus, the motion 
of the chain in both axial directions will be transmitted to the carrier 
by means of the pick-up brackets. 
The ramp assembly also has provision for manual operation of the ramp in 
the event of electrical power failure. To this end, the pin 150 is 
provided with a washer 152 which bears against the upstanding leg of 
bracket 146. A spring 155 extends around the pin and has one end engaging 
the washer 152 and the opposite end engaging fixed stop plate 158 which is 
spaced from bracket 146. The distal end of the pin is secured to a cable 
assembly 160, the opposite end of which is positioned for convenient 
access, as for example at the side of the housing at the outer edge of the 
ramp assembly. It will be apparent that by exerting a manual traction or 
pulling force on the cable assembly 160, the pin 150 will be disengaged 
from the chain allowing the ramp to be manually moved bi-directionally 
along the guide track in the boom arms. 
The ramp assembly of the present invention also includes provision for 
elevating the rear end of the ramp platform when the ramp platform is in 
the fully deployed position. The elevation of the inner end of the ramp 
platform places it closer to the vehicle floor 20 and the floor transition 
plate 28 for added safety and convenience. To elevate the rear end of the 
ramp platform, lift cams 200 and 200A are interposed between the ramp 
platform sides 44 and 46 and the boom arms 66 and 68, respectively, at a 
location immediately adjacent the outer or open end of the ramp. Cam 200 
is representative and is best seen in FIGS. 4, 5 and 6 and has a gradual 
rise 206 which extends to peak 210 and thereafter continues downwardly 
into a detent recess 212. The outer surface of each of the cams is 
vertical and terminates at a stop 215 forward of the detent 212. The cam 
has opposite planar sides 216 and 218 and is cut or fabricated from 
suitable steel material and is interposed between the boom and ramp in a 
vertical position. 
During the major portion of the deployment and retraction of the ramp, the 
ramp assembly operates with the floor 42 of the ramp engaging or sliding 
along or adjacent the upper surface of the floor 28 of the housing and 
supported on transverse roller 275 at the outer edge of the housing. 
During the deployment, as the ramp nears the fully extended position with 
a substantial portion of the ramp extending outwardly from the opening in 
the housing, the rollers 98 and 98A will initially engage the rise portion 
206 of respective lift cams 200 and 200A. As this occurs, the rollers will 
ascend the rise of the cams causing the inner end of the ramp to elevate 
as best seen in FIG. 7. This motion is permitted by the links 80, 82 
interconnecting the carrier and the ramp assembly. As the ramp moves to a 
position where the associated rollers 98 and 98A pass the peaks 210 of the 
associated cams, the rollers will descend into the detent area 212 of the 
cam. Further movement of the ramp is prevented by stops 215. The carrier 
50 is permitted slight further forward movement which will cause the 
supports 90, 90A which are mounted to the carrier to continue to move 
outward as the ramp is pivoted to the position shown in FIG. 6. As this 
occurs, the carrier and supports 90, 90A move under the ramp floor 42 
adjacent the inner end of the ramp to provide support and reinforcement 
for the ramp at this location. The supports 90, 90A serve to resist 
transverse flexing of the ramp under load giving the ramp greater 
stability. 
When the carrier drive motor 60 is reversed, the chain will pull the 
carrier rearwardly moving the ramp platform 40 rearwardly by means of the 
associated links 80, 82 from the deployed position. The ramp platform 40 
will move from a position seated in cam detents and progress downwardly 
along the cam surfaces until the ramp floor is positioned in sliding 
engagement with the upper surface of the floor of the housing. Continued 
retraction will bring the ramp to the position shown in FIG. 1. 
Another important functional feature of the present invention is the 
provision of controlled lowering and raising of the outer end of the ramp 
platform. During the retraction operation, the ramp is first raised to a 
substantially horizontal position before or at the beginning of retraction 
of the ramp into the retaining housing by means of the drive motor. During 
deployment, the ramp is partially or fully extended and then the outer end 
of the ramp lowered until it assumes a position resting on the ground or 
curb which provides an inclined surface for traffic. 
Accordingly, referring to FIGS. 2, 7, 8 and 11, a ramp lift motor 62, as 
has been described, is mounted on the carrier 50 and traverses during 
deployment and retraction with the carrier. The lift motor is of the type 
described above which may be a reversible electric motor of the type 
conventionally used as window riser motors. Motor 62 is provided with a 
vertically extending output shaft 225 which carries a rotor 230 onto which 
a cable 250 is wound. The cable 250 extends from the rotor 230 around an 
idler 260 positioned adjacent the rotor. A generally C-shaped cable guard 
265 is associated with the idler 260. The cable 250 is directed along the 
boom arm 66 and extends around a pulley 268 mounted at the outer end of 
the boom arm 66. The cable extends downwardly from the pulley and is 
secured to the underside of the ramp platform 40 at clevis 270. Clevis 270 
is pinned to the underside of the ramp at pins 272. A section of the 
clevis projects outwardly beyond the end of the ramp as seen in FIG. 7. In 
the normal operation, when the cable is extended, the weight of the ramp 
platform will cause the ramp to pivot and drop to an inclined position. In 
the event it is necessary to operate the device manually in an emergency 
situation, such as in the event of a vehicle electrical failure, clevis 
270 may be removed by detaching clevis pins 272 and the ramp lowered 
manually. 
In the normal motorized operation, lowering of the ramp is controlled by 
the lift motor 62 which is a window lift motor of the type described 
above. When the lift motor is actuated and the ramp is fully extended, the 
cable will pay-out allowing the end of the ramp to drop to the curb or 
ground. A grounding post 290 is positioned adjacent the rotor as best seen 
in FIG. 11. When the end of the ramp engages the ground, the rotor 23(I 
will continue to rotate paying out cable causing the cable to become 
slack. The slack cable will engage the grounding post which operates upon 
a relay to switch the power off. 
The electrical system of the present invention is shown in FIGS. 12 and 13. 
Drive motor 60 is stationary and lift motor 62 moves with the carrier. The 
system operates from the electrical system of the vehicle represented by 
battery 310. 
The operation of the system is initiated by any one of three switches 
S.sub.1, S.sub.2 or S.sub.3 located on or in the vehicle. For example, 
switch S.sub.1 is located on the vehicle instrument panel, switch S.sub.2 
in the rear passenger compartment and switch S.sub.3 at an exterior 
location, as for example at or near the rear of the vehicle in an area 
rearward of door 14. A push button switch 330 is positioned to be closed 
only when door 14 is open. Refer 1o FIG. 1. Limit switch 300 is closed 
when the carrier and ramp are fully retracted and limited switch 302 is 
closed when the carrier and ramp are fully deployed. 
When one of the switches S.sub.1, S.sub.2 or S.sub.3 is depressed, the door 
14 is opened by a separate power mechanism. The opening of door 14 
releases push button switch 330 and allows relay 316 to be energized 
sending power to drive motor 60. The ramp and carrier deploy and at or 
near full deployment limit switch 302 is contacted and closed which 
terminates power to the drive motor. At full deployment, the contacts of 
switch 310 on the carrier engage the matching contacts of fixed switch 
312. This actuates the down relay 319 sending power to lift motor 62 
causing cable to pay out. The cable continues to pay out until the ramp 
engages the ground surface causing the cable to become slack engaging the 
grounding post terminating power to motor 62. 
The retraction cycle operates in a similar fashion. Any of the switches 
S.sub.1, S.sub.2 or S.sub.3 is actuated. Power is directed to the time 
delay relay 315 and to the "up" relay 318 causing motor 62 to operate in a 
direction to wind up cable to lift the ramp to a horizontal position. A 
clutch prevents overwinding of the cable. 
After a predetermined time delay, the "in" relay 317 is energized which 
directs power to motor 60 causing the carrier and ramp to move inwardly. 
This terminates the contact between switch elements 310 and 312 and 
de-energizes the lift motor 62. The carrier moves inwardly with the ramp 
until limit switch 300 is engaged which turns off power to the "in" relay 
317 and to the drive motor 60. 
Thus, it will be seen that the present invention provides a unique and 
efficient ramp assembly for vehicle access. It will be obvious to those 
skilled in the art to make various changes, alterations and modifications 
to the deployable vehicle access ramp described herein. To the extent such 
changes, alterations and modifications do not depart from the spirit and 
scope of the appended claims, they are intended to be encompassed therein.