Wheel chair abstract
A motorized wheel chair is provided comprising a chassis having
two rear wheels and one front wheel mounted thereon. The front wheel
is steerable by a handlebar. The rear wheels are driven by an electric
motor, coupled to a gearbox, for reducing the speed of the wheel
chair. The gearbox drives a friction drive assembly which is engageable
with the rear wheels and also is coupled to the handlebar such that
one of the rear wheels will be disengaged depending upon which direction
the handlebar is turned. The device is provided with a switch which
cuts power to the device when a change in surface elevation of a
desired amount is detected either in front of or behind the device.
A second switch may be provided to stop the vehicle upon contact
with a foreign object. A third switch may be activated remotely
to stop the device. Also, the chassis is adjustable in length, such
that as a child grows the device may be adjusted accordingly.
Wheel chair claims
I claim:
1. A motorized wheel chair for small children, comprising:
(a) a chassis;
(b) a front wheel, rotatably mounted on said chassis;
(c) a right rear wheel, rotatably mounted on said chassis;
(d) a left rear wheel, rotatably mounted on said chassis;
(e) a steering means, mounted on said chassis and connected to
said front wheel, for turning said front wheel;
(f) a gear reduction means, for limiting the speed of said wheel
chair, mounted on said chassis;
(g) a drive shaft, rotatably connected to said gear reduction means,
said drive shaft having a left friction drive roller and a right
friction drive roller fixedly attached thereto such that said left
and right friction drive rollers are engageable with said left and
right rear wheels, respectively;
(h) an electric motor, driveably connected to said gear reduction
means such that for every revolution of said drive shaft, said motor
will turn a greater number of revolutions;
(i) a throttle means, for controlling the speed of said motor,
connected to said motor;
(j) a shift means, for controlling the direction of said motor,
connected to said motor;
(k) a power source, mounted on said chassis and connected to said
motor;
(l) a seat, mounted on said chassis; and
(m) a clutch means, for selectively operating only said left rear
wheel during a right turn and only said right rear wheel during
a left turn, said clutch means being connectable between said steering
means and said drive shaft said clutch means further comprising:
i. a right steering cable, connected at one end to said steering
means, and at the other end to a right clutch lever;
ii. a right clutch lever pivotably attached to said chassis, attached
to said right steering cable and attached to said drive shaft such
that, during a right turn, said right friction drive roller is urged
away from said right rear wheel;
iii. a left steering cable, connected at one end to said steering
means, and at the other end to a left clutch lever; and
iv. a left clutch lever pivotally attached to said chassis, attached
to said left steering cable and attached to said drive shaft such
that, during a left turn, said left friction drive roller is urged
away from said left rear wheel; and wherein said gear reduction
means is flexibly mounted to said chassis such that, upon an application
of force, said gear reduction means may twist slightly on an axis
generally perpendicular to said chassis and then return to its original
position upon the release of said force. .Iadd.
2. A motorized wheel chair for a small child comprising:
a chassis;
seat means supported by the chassis for supporting the child;
wheel means for supporting the chassis;
drive and steering means for selectively driving and steering the
wheel means so that the wheel chair is caused to be moved along
a selected path by the wheel means in response to actuation by the
child;
detection means for sensing the presence of an object and for preventing
the drive means from driving the wheel means in the direction of
the sensed object; and
elevation sensing means for detecting a change in surface elevation
greater than a selected elevation difference and for stopping the
wheel chair upon detecting the selected elevation difference. .Iaddend.
.Iadd.3. The motorized wheel chair of claim 2 wherein the detection
means comprises:
front detection means attached to the wheel chair for sensing the
presence of an object and for preventing the drive means from driving
the wheel
means in a forward direction. .Iaddend. .Iadd.4. The motorized
wheel chair of claim 3 wherein the detection means further comprises:
rear detection means attached to the wheel chair for sensing the
presence of an object and for preventing the drive means from driving
the wheel means in a reverse direction. .Iaddend. .Iadd.5. The motorized
wheel chair of claim 4 wherein the elevation sensing means comprises:
front elevation sensing means supported by a forward portion of
the chassis for stopping the wheel chair upon detecting the selected
elevation
difference. .Iaddend. .Iadd.6. The motorized wheel chair of claim
5 wherein the elevation sensing means further comprises:
rear elevation sensing means supported by a rearward portion of
the chassis for stopping the wheel chair upon detecting the selected
elevation difference. .Iaddend. .Iadd.7. The motorized wheel chair
of claim 2 wherein the drive and steering means comprises:
power means for selectively powering the wheel means. .Iaddend.
.Iadd.8. The motorized wheel chair of claim 7 wherein the power
means has at least one gel cell battery. .Iaddend. .Iadd.9. The
motorized wheel chair of claim 8 wherein the wheel means comprises
at least one pair of wheels and wherein the motorized wheel chair
further comprises:
motor means connected to the wheel means for selectively rotating
the wheels when energized by the battery. .Iaddend. .Iadd.10. The
motorized wheel chair of claim 9 further comprising:
charge means supported by the chassis for charging the battery.
.Iaddend. .Iadd.11. The motorized wheel chair of claim 2 further
comprising:
remote switching means for actuating the drive and steering means
from a remote locate. .Iaddend.
Wheel chair description
BACKGROUND OF THE INVENTION
1. Field of Invention
This invention relates generally to motorized wheel chairs. More
particularly, this invention relates to motorized wheel chairs suitable
for use by small children.
2. Prior Art
Many devices have been designed and are now in use which aid the
physically or mentally challenged in moving from place to place.
Various motorized wheel chairs are now available for such use. However,
these devices are often unsuitable for use by small children.
In order to provide a motorized wheel chair for small children,
especially those under five years of age, additional factors must
be taken into consideration. In order to circumvent the requirement
of constant adult supervision, the vehicle must incorporate a number
of safety features. A child must not be able to operate the vehicle
across sharp changes in floor elevation (e.g. steps). The vehicle
should operate at a very low speed and must be easy to steer. Some
protection should be provided to prevent damage to furniture and
other household fixtures. The vehicle must resist overturning. It
is also desirable that a supervising adult be provided with some
remote means for immediately stopping the vehicle.
There are very few devices currently available which meet any of
the above criteria. This problem is compounded by the fact that
devices currently on the market are extremely expensive. Also, current
motorized wheel chairs for small children are useless when the children
outgrow them, thus requiring even greater costs for replacement
vehicles.
SUMMARY OF THE INVENTION
Considering the above, it is an object of this invention to provide
a motorized wheel chair which is suitable for operation by small
children.
It is another object of this invention to provide a motorized wheel
chair which cannot be operated across sharp changes in elevation.
It is still another object of this invention to provide a motorized
wheel chair which will operate at a low speed and which is easily
steerable.
It is a further object of this invention to provide a motorized
wheel chair which incorporates a feature to prevent damage to furniture
and other household fixtures.
It is still a further object of this invention to provide a motorized
wheel chair which is provided with a remote stopping means.
It is still another object of this invention to provide a motorized
wheel chair which is relatively inexpensive and is adaptable for
operation as a child grows.
Still other objects and advantages of this invention shall become
apparent from the ensuring descriptions of the invention.
A motorized wheel chair is provided comprising a chassis having
two rear wheels and one front wheel mounted thereon. The front wheel
is steerable by a handlebar. The rear wheels are driven by an electric
motor, coupled to a gearbox, for reducing the speed of the wheel
chair. The gearbox drives a friction drive assembly which is engageable
with the rear wheels and also is coupled to the handlebar such that
one of the rear wheels will be disengaged depending upon which direction
the handlebar is turned. The device is provided with a switch which
cuts power to the device when a change in surface elevation of a
desired amount is detected either in front of or behind the device.
A second switch may be provided to stop the vehicle upon contact
with another object. A third switch may be activated remotely to
stop the device. Also, the chassis is adjustable in length, such
that as a child grows the device may be adjusted accordingly.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side view of a preferred embodiment of the invention.
FIG. 2 is a top view of a preferred embodiment of the invention
with the outer coverings and right rear wheel removed.
FIG. 3 is a side view of a preferred embodiment of the invention
with the outer coverings removed.
FIG. 4 is a rear view of a preferred embodiment of the invention
with the outer coverings removed.
FIG. 5 is a front view of a preferred embodiment of the front steering
mechanism of the invention.
FIG. 6 is a side view of the front steering mechanism of the invention
as it is attached to the chassis of the invention.
FIG. 7 is a top view of the adjustable chassis of a preferred embodiment
of the invention.
DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION
As shown in FIGS. 1 and 2, the vehicle 1 generally comprises a
chassis 2, on which are mounted a front wheel 3, a right rear wheel
4 and a left rear wheel 5. As can be seen, the wheels 3, 4 and 5
are located within the outer perimeter of the vehicle. This arrangement
complements the sensory equipment on the vehicle, which will be
described in further detail herein, and reduces the likelihood of
wheel contact with foreign objects. The vehicle 1 can be steered
by a steering means 6, which is usually a handlebar, as shown in
the Figures. The handlebar 6 is provided with a handlebar post 23,
which passes through a front bearing assembly 24 in chassis 2 and
connects to front forks 25. In a preferred embodiment, handlebar
post 23 is removable and replaceable with an eating tray, learning
aids, a desk top or other such items. A throttle 7 is provided for
speed control. The throttle 7 may assume various forms known in
the art. In the Figures, the throttle 7 is shown in the form of
a twist grip. A shift lever 8 is provided to enable the operator
to shift between forward and reverse. Sterring means 6, throttle
7 and shift lever 8 could be combined electronically into a joy
stick control such that all vehicle movements could be controlled
by a single component, actuated by a single hand or head movement
by the operator. A front covering 9 and a rear covering 10 encase
the internal workings of the vehicle. It is preferable that coverings
9 and 10 be lockable to prevent tampering and promote safety. A
seat 11 is provided for the operator. In order to assure a tight
turning radius, it is preferred that rear wheels 4 and 5 be located
generally beneath the seat 11. Safety belts 12 may be provided to
hold the operator in place. A front bumper 13 and a rear bumper
14 are provided to encase the perimeter of front covering 9 and
rear covering 10, respectively. The bumpers 13 and 14 will also
serve complement the sensory equipment on the vehicle 1.
One separate requirement for the vehicle 1 is that it must travel
at a slow rate to permit proper supervision of the child and to
prevent accidents.
The vehicle is powered by an electric motor 15. Electrical wiring
has been omitted for clarity. It will be understood that shift lever
8, throttle 7, motor 15, front elevation sensing means 52, rear
elevation sensing means 53, remote switching means 55 front object
detection means 56, rear object detection means 57 and battery system
58 are connected to circuit box 54 by means known in the art so
as to perform their respective functions. In order to provide the
reduction in speed, various means may be employed. As shown in FIGS.
2-4, a small pulley 16, rotatably connected to motor 15, drives
a large pulley 17 which is connected to a gear reduction means 18,
usually a gearbox. The pulleys are driven by means of a belt 19.
The gearbox 18 drives drive shaft 20 at a greatly reduced rate of
rotation compared to that of small pulley 16.
Connected to either end of drive shaft 20 are a right friction
drive roller 21 and a left friction drive roller 22. When turning,
rollers 21 and 22 maintain contact with rear wheels 4 and 5, respectively,
and the vehicle 1 moves accordingly. One problem which arises concerning
three-wheeled vehicles is that of the vehicle's ability to turn.
When the front wheel 3 is turned and both rear wheels 4 and 5 are
driving, the vehicle tends to move forward rather than to run in
the direction urged by the front wheel 3. This situation is compounded
by the increased driving power resulting from the gear reduction
means 18 described above. Applicant has solved this problem by employing
a unique, but simple, steering arrangement. As shown in FIGS. 5
and 6, a collar 26 is attached to handlebar post 23. A right steering
cable 27 and a left steering cable 28 are fixedly connected to collar
26 at right and left cable clamps, 29 and 30, respectively. Right
and left cable clamping screws 43 and 44 hold cables 27 and 28 in
place in collar 26. Steering cables 27 and 28 are encased so as
to allow relative movement between cable casings 31 and cables 27
and 28. Front bracket 32 serves to hold cable casings 31 in a stationary
position to allow for relative movement. Thus, as the handlebar
post 23 is turned, steering cables 27 and 28 will move accordingly.
Right and left steering cables 27 and 28 are connected to right
and left clutch assemblies, 33 and 34, respectively. The right clutch
assembly 33 comprises a right clutch bracket 35, a right clutch
pin 36, a right clutch lever 37 and a right drive bearing 38. The
left clutch assembly 34 similarly comprises a left clutch bracket
39, a left clutch pin 40, a left clutch lever 41 and a left drive
bearing 41. The gearbox 18 is mounted on a pad 45 of resilient material,
which is in turn mounted to the chassis 2, such that the gearbox
18, drive shaft 20 and friction drive rollers 21 and 22 are allowed
to twist slightly as a unit upon the application of torque. When
torque is released, the unit will return to its normal position.
In normal position, right and left friction drive rollers 21 and
22 are held in contact with right and left rear wheels 4 and 5,
respectively, by right drive spring 46 and left drive spring 47.
Thus, should the operator desire to make a right turn, the handlebar
6 is turned clockwise, placing tension on the right steering cable
27, activating the right clutch lever 37, which urges the right
drive bearing 38 and thus the right friction drive roller 21 away
from the right rear wheel 4, causing the vehicle 1 to execute a
right turn as the left rear wheel 5 continues to turn. When the
handlebar 6 is straightened drive springs 46 and 47 urge both friction
drive rollers 21 and 22 back into contact with rear wheels 4 and
5. The clutch assemblies 33 and 34 also allow for single motor operation,
saving on costs, electrical circuitry and battery drain. Of course,
separate motors 15 (with necessary gear reduction means 18) could
be provided for each rear wheel 4 and 5. In this instance, turning
could be controlled electronically by a joy stick control as described
previously.
Of course, steering means 6 and clutch assemblies 33 and 34 may
take various forms known in the art. For example, steering means
6 could comprise a joy stick type control for use by operators with
limited hand movement. Such a control could also incorporate throttle
7 if necessary.
In order to lower the center of gravity of the vehicle 1, the rear
axle 48 is elevated above the chassis 2 by means of right and left
axle support brackets 49 and 50. This arrangement allows for increased
stability of the vehicle 1. In order to provide increased assurance
of stability, at least one rear caster 51 may be provided to prevent
the possibility of the vehicle 1 rearing up upon rapid acceleration.
The vehicle 1 is provided with a front elevation sensing means
52 and a rear elevation sensing means 53, for sensing abrupt changes
in surface elevation, such as steep drop-offs or steps. Range finding
sonar circuits, of the type used in camera equipment, have proven
successful for this application. Both elevation sensing means 52
and 53 are connected to circuit box 54 such that when a desired
elevation difference is detected, power to the motor 15 is interrupted
and the vehicle is stopped, until the vehicle 1 is removed from
the danger area by a parent or other supervisory adult.
A remote switching means 55 is also provided to further enhance
the safety features of the vehicle 1. Upon receipt of a given signal,
the remote switching means 55 may be utilized to interrupt or reinstate
power to the vehicle 1. A whistle-activated switch, such as that
manufactured by Radio Shack, Catalog Number 277-1011 may be utilized
for this purpose. Thus, if the vehicle 1 is seen moving toward a
dangerous or undesired location, a parent need only blow a whistle
to stop the vehicle 1. A second blast from a whistle is necessary
to reinstate power to the vehicle 1. Of course, other types of remote
switching apparatus may also be used.
Because of the low speed and high gear ratio of the vehicle 1,
it tends to be unusually powerful. Therefore, in order to protect
furniture and other fixtures as well as to provide increased safety,
the vehicle 1 is provided with front and rear object detection means
56 and 57 which sense contact between the vehicle's front and rear
bumpers 13 and 14, respectively, and foreign objects. The object
detection means 56 and 57 are connected to the vehicle circuit box
54 such that upon contact with a foreign object, power will be interrupted
and the vehicle will be stopped. In a preferred embodiment, front
object detection means 56 is connected such that, when activated,
the motor 15 will not operate in a forward direction. Likewise,
the rear object detection means 57 is connected so as, when activated,
to prevent operation in a reverse direction. Thus, the operator
is able to extricate himself from difficulty without assistance
under certain conditions.
Front and rear object detection means 56 and 57 may comprise various
types of sensing devices. In one embodiment, shown in the Figures,
front and rear bumpers 13 and 14 comprise inflated rubber tubing.
Front and rear object detection means 56 and 57 comprise pressure
sensitive switches, connected to bumpers 13 and 14. The switches
56 and 57 are responsive to the pressure increase caused by bumper
contact with a foreign object. Of course, front and rear object
detection means 56 and 57 could take other forms. For example, bumpers
13 and 14 could each contain a pair of electrically conductive strips
which would normally be spaced apart, but would contact each other,
closing a circuit, when in contact with a foreign object.
The vehicle 1 is powered by battery system 58. It is preferred
that the battery system 58 includes a pair of six volts gel cell
batteries. The gel cell batteries eliminate the danger of acid spills.
This arrangement allows for one battery to be utilized for electronics
circuitry, eliminating the need for a voltage regulator or voltage
drop circuit. Both batteries would operate the twelve volt motor
15. Preferably, a one amp battery charger 59 is provided for overnight
charging.
The chassis 3 may be divided into a front section 60 and a rear
section 61, as shown in FIG. 7. The front chassis section 60 is
provided with a tongue 62, which has adjustment holes 63. Any two
adjustment holes 63 may thus be aligned with mounting holes 64 in
rear chassis section 61 and then bolted together to form a unitary
chassis 2 which is adjustable in length. The chassis 2 is thereby
made expandable such that, as a child grows, he does not outgrow
the vehicle 1.
As can be seen, a motorized wheel chair is provided which enables
physically or mentally challenged small children to safely and efficiently
move about with a minimum of adult supervision. There are, of course,
many alternate embodiments intended to be within the spirit and
scope of this invention, as defined by the following claims. |