Wheel chair abstract
A wheel chair has a rear swing axle pivotally connected to the
seat frame and a spring shock absorber controls the relative movement
therebetween. A front suspension is connected to the seat frame
separately from the rear suspension and includes a floating beam
carrying the front castor wheels and pivotally connected to the
seat frame by four link control arms. Three shock absorbers acting
between the front of the seat frame and the floating beam allow
controlled vertical movement of the floating beam. A second embodiment
has the rear wheels each connected by a separate swing arm pivotallty
connected to the seat frame at their front end and each swing also
connected to the rear of the seat frame by a pair of control arms
and a shock absorber.
Wheel chair claims
What is claimed is:
1. A wheel chair comprising
a) a seat and back carrying frame having
1) a pair of spaced longitudinally extending side rails,
2) a front and a back cross member extending laterally between
and connecting said side rails,
b) a separate front and rear wheel carrying suspension for said
frame, with said frame having laterally spaced frame connecting
means thereon for seperately connecting said suspensions to said
frame,
c) said front suspension including
1) a pair of laterally spaced front wheels including mounting means
thereon,
2) a laterally extending floating beam member including laterally
spaced mounting means thereon mounting said front wheels thereto,
3) a first pair of link control arms connecting said mounting means
on one of the ends of said floating beam member to one of said frame
connecting means and a second pair of link control arms connecting
said mounting means on the end of said beam member opposite to said
one end thereof to said other frame connecting means,
4) the connection between said control arms and said mounting means
and said connecting means including pivoting connecting means,
5) front spring shock means connected to said front cross member
and to said floating beam member to allow for relative movement
between said floating beam member and said frame,
d) said rear suspension including
1) a pair of laterally spaced and longitudinally extending swing
arms each having a forward and a rearward end and including means
separately and pivotally mounting the forward end thereof for pivoting
in a vertical direction relative to said frame connecting means,
2) a pair of rear wheel chair wheels,
3) wheel connecting means separately connecting each of said wheels
to one of said swing arms in a laterally spaced relationship, and
4) a rear shock absorbing means connected between said back cross
member and the rearward end of each of said swing arms.
2. A wheel chair according to claim 1 wherein said rear shock absorbing
means is a pair of shock absorbers and each of said shock absorbers
is a combined spring shock absorber having variable dampening and
spring rate adjustments.
3. A wheel chair according to claim 1 including brake means connected
to at least one of said swing arms for selectively braking said
wheel thereon, whereby said brake means moves unitarily with said
wheels and is always in a position to apply a braking force to said
wheels.
4. A wheel chair according to claim 1 including a pair of links
of a link control arm structure connect the rearward end of each
of said swing arms to said frame and being pivotally mounted relative
to said frame.
Wheel chair description
1. FIELD OF THE INVENTION
This invention relates to wheel chairs generally and more particularly
to wheel chairs having an independent suspension configuration.
2. DESCRIPTION OF PRIOR ART
The general widely used wheel chair found today has an integrated
structure so that both of the larger rear wheel along with both
of the smaller front castor wheels are connected to the seat platform
of the wheel chair in not only a rigid manner, but also such that
all members are suspended in a dependent manner, that is, they are
not capable of moving relative to the seat platform in an independent
manner.
While a Powered Wheel Chair With--Independent Suspension is shown
in U.S. Pat. No. 5,575,348, the structure disclosed therein does
not have the shock absorbing characteristics or true independent
features of the present invention. Without a true independent suspension
wherein the front castor wheels are suspended independently of each
other and also independent of the rear wheels a comfortable ride
cannot be obtained. In a second embodiment, both the front and rear
wheels are independently suspended. With the structure of the present
invention, large steps such as encountered when going off a curb,
can be accomplished by the rider without assistance and without
bone jarring impact or damage to the wheel chair.
SUMMARY OF THE INVENTION
It is an object of this invention to provide a sturdy wheel chair
which is comfortable to operate and which can accommodate large
steps and bumps in its operation without damaging the wheel chair
or causing discomfort or injury to the user.
To this end, in a first embodiment the main occupant supporting
chassis is suspended from a rear swing arm which carries the larger
rear wheels and four link arms which extend forwardly with two of
them operatively connected on each side of a floating beam. The
floating beam carries at each of its opposed ends a castor wheel
and a foot support on its medial portion, and is connected to the
chassis by a plurality of vertically extending gas charged spring
shock absorbers which allow vertical movement with control to prevent
diving. The rear swing arm which carries the rear wheels, is connected
to the chassis at its back end by a vertically extending shock-absorber
spring device which has variable damping and spring rate adjustments.
The rear swing arm and the four forwardly extending link arms are
centrally connected to a pair of spaced supports fixedly carried
by the seat supporting portion of the chassis. The location of the
rear wheels relative to the rear swing arm are adjustably positioned
for fore and aft adjustment to provide for front and back weight
transfers. The rear wheel locks are carried by a support bracket
connected directly to the rear wheel supports so movement thereof
is in conjunction with the rear wheels.
In a second embodiment, instead of both of the rear wheels being
connected to the same swing arm, and only a single shock absorber
at the rear, each of the rear wheels has its swing arm which is
connected to the chassis by a pair of link arms and a separate spring
shock absorber to each of two separate swing arms. This embodiment
for certain operators and certain applications provides even more
comfort in its operation than the first embodiment.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a side elevational view of a wheel chair made according
to this invention;
FIG. 2 is a front elevational view;
FIG. 3 is a rear elevational view;
FIG. 4 is a sectional view taken along the line 4--4 in FIG. 3.
FIG. 5 is a sectional view taken in the manner of FIG. 4, of a
second embodiment of this invention; and
FIG. 6 is a rear elevational view of the embodiment of FIG. 5.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now to FIGS. 1-4 of the drawings, a seat frame shown
generally at 10 includes a pair of laterally spaced side rails 12
and 14 interconnected at their front ends by a front cross member
16 and at their rearward end by a rear cross member 18. The front
cross member 16 is displaced arcuately downwardly and the rear cross
member 18 is displaced arcuately rearwardly so that when the seat
19, made of a durable material such as a high denier balistic nylon
and suitably secured at its lateral edges to the rails 12 and 14,
is sat upon, the sitters legs will not strike the front cross member
16 and the sitter's back will not hit the member 18. A back cover
20, which is also made of such durable material, is secured at its
lateral edges to a pair of spaced back rails 21 and 22 suitably
secured or formed integrally with the side rails 12 and 14 respectively,
and joined at their top end by a top rail 23. The top rail 23 is
bent arcuately rearwardly so as to avoid a sitters back and the
intermediate portion thereof has a comfortable hand grip 24 which
a party pushing the chair 10 can conventionally grasp. Side plates
15 and 17 are conventionally secured to the sides of the seat frame
10 to form the sides of the seating area.
The side rails 12 and 14 have attachments brackets 25 and 26, respectively
which brackets are rigidly secured to the associated side rails
at a location forward of the longitudinal midpoint thereof and extend
downwardly from the side rail. The lower end of the brackets 25
and 26 provide the mounting location for the under carriage of the
chair, that is, the front floating beam assembly shown generally
at 27 and the rear single swing axle assembly shown generally at
28.
More particularly the axle assembly 28 is secured to the brackets
25 and 26 for pivotal movement in a vertical direction about the
horizontal axis of a pair of mounting bolts 29 and 29A which pass
through aligned openings in the front ends of the axle assembly
28 and in the brackets 25 and 26. The axle assembly 28 includes
a swing arm comprised of a pair of generally longitudinally extending
side members 30 and 31 (these members slope slightly downwardly
from the front and end thereof toward the rear) interconnected at
their rear ends by an arcuately shaped rear bar 32, and a cross
brace 32A slightly forward of the rear bar 32 rigidly interconnects
the side members at the location just below the axle spindles 33
and 34 which rotatably mount the usual and conventional wheel chair
wheels 35 and 36.
The mounting of the axle spindles to the assembly 28 will now be
described in detail with respect to the wheel 36, as seen in FIG.
4, such details being also applicable to the mounting of wheel 35.
Rectangular braces 37 and 38 are fixedly secured, respectively,
to the top of side members 30 and 31, which braces each has longitudinal
opening formed medially in the top thereof so that the brace is
somewhat "U" shaped. An axle mounting bracket 39 and 40
is respectively bolted to the brace 37 and 38 and overly the longitudinal
opening formed therein. A longitudinal slot 41 and 42 is formed
in the bracket 39 and 40, respectively, and the inner end of the
axle spindles 33 and 34 are received in the slots 41 and 42 and
a nut threaded on the inner end of each of the spindles secures
the spindle in the respective bracket. The axle spindles may be
shifted for and aft in the slots 41 and 42 as needed fore weight
transfer. A spring-shock 43 having variable dampening and spring
rate adjustments such as a shock available from Koni under Part
No. 7610-1277 has its lower adjustable end pivotally secured by
a bolt in a bracket 44 secured medially to the top of the rear bar
32 and the top of the shock is pivotally secured by a bolt in a
bracket 45 secured medially to the forward face of the rear cross
member 18 so that the rear axle floats on a single swing arm design.
The wheel locking assemblies 46 are of conventional configuration
and, when activated, abut the front end of the wheels 35 and 36.
These assemblies are carried on the front ends of a pair of brake
support brackets 47 and 48, the rear ends thereof being secured
to the axle mounting brackets 39 and 40, respectively, so that the
locks move unilaterally with the brackets and the wheels mounted
therein.
The floating beam assembly 27 is mounted at the front end of the
frame 10 by three gas charged spring shocks and includes a floating
beam 49 medially carrying a foot rest and mounting on its lateral
ends caster wheel mounting brackets 50 and 51 and being connected
to the brackets 25 and 26 by four link control arms.
More particularly the floating beam assembly 27 includes a floating
beam 49 having a foot rest 49A thereon which beam while extending
laterally, is curved arcuately downwardly intermediate its ends
and at its lateral ends terminates in mounting brackets 50 and 51
which brackets extend fore and aft of the beam 49. On the front
ends of each of the brackets 50 and 51 is secured a castor wheel
assembly 52 of conventional construction. Two links of the four
link control arm structure are connected to the rear end of each
bracket 50 and 51. A vertically elongated spacer bracket 53 is secured,
as by bolting, to the inner-lower side of each of the brackets 25
and 26. To the lower end of each of the brackets 53 is bolted the
rear end of a lower link 54 by a bolt 54A. with said rear end of
the link being of a yoke configuration with one ear of the yoke
being on the inside and the other being on the outside of the bracket
and the yoke being pivotal relative to the associated bracket in
a vertical direction only.
The front end of each lower link 54 has an opening therein receiving
a shouldered bolt 54B, with the shoulder being of semi-spherical
configuration so that the front end of each of the links 54 can
pivot in a vertical plane relative to its associate bolt and also
an move angularly relative thereto; each of the bolts being secured
to the lower rear end of its associated mounting bracket 50. Each
of the links 54 is made of two pieces which are screwed together
such that the length of the link can be adjusted.
To the middle of each spacer bracket 53 is secured a shoulder bolt
55 which is received in an opening in the rear end of an upper link
56, with the shoulder portion being of semi-spherical configuration
and received in the opening in the link 56 whereby the link 56 can
pivot in a vertical plane relative to the bolt and also can move
angularly relative thereto. It should be noted that the bolt 55
also secures the spacer bracket 55 to the attachment bracket 26
as does a bolt 57 which secures the top of the spacer bracket to
the attachment bracket. Thus the rear ends of both the upper and
lower links are attached to the attachment bracket.
The front end of each of the upper links 56 is secured to the top
rear of the associated mounting bracket 50 by a shoulder bolt 58,
the shoulder of which is received in an opening in the front end
of the link 56 and said shoulder being of semi-cylindrical configuration,
whereby the link 56 can pivot vertically relative to its associated
mounting bracket 50, and also can move angularly relative thereto.
Each of the upper links 56 is formed in three pieces, with the two
end pieces threaded into the middle piece so that the length of
the upper links 56, as well as the length of the lower links 54
can be adjusted to "tune" the suspension.
Spring shock means 60 are disposed between the front of the frame
10 and the floating beam assembly 27 for controlling the relative
movement thereof. More particularly a shock mounting bracket is
secured to the middle of the front cross member 16 and the upper
end of three gas charged spring shocks is bolted thereto with the
bolt heads being in a spherical socket relationship to the shocks
for free pivotal movement. The middle shock 60A extends straight
down to and is secured to the middle of the floating beam 49 and,
as seen in FIG. 2, the right shock 60B is angled to the right and
is secured to the floating beam 49 adjacent its right end while
the left shock 60C is angled to the left and is secured to the floating
beam 49 adjacent the left end thereof, while all three shocks are
angled slightly forwardly as seen in FIG. 1. The securement of the
shocks to the beam 49 is by bolts with the bolt heads being in a
spherical relationship to the shock for free pivotal movement.
The floating beam assembly which includes the castor wheel and
the foot rest moves unitary relative to the frame and relative to
the back wheels, while the back wheels move unitarily relative to
the frame and the front wheels. The front wheels do not have to
stay in the same plane as the back wheels and can independently
move vertically relative to the plane of the back wheels.
The gas charged spring shocks do not have to be of the same spring
rates. In a preferred embodiment, the outside shocks were labelled
as 30 pounds while the center shock was 40 pounds. This provides
vertical movement outside with minimal control to prevent front
end diving. These shocks can be obtained from Spring Lift Corporation.
The middle shock is identified as being SL-30, 40#; while the outside
shocks were identified as SL32, 30#.
Referring now to the second embodiment having independent rear
suspension, as seen in FIGS. 5 and 6, the front suspension is the
same as for the first embodiment shown in FIGS. 1-4, while the differences
in the seat construction and the rear suspension as seen in FIGS.
5 and 6 will be explained hereinafter.
The side rails 12 and 11 of the seat frame shown generally at 10A
includes, in addition to the rear cross member 18, a lower cross
member 18A interconnecting the lower ends of the spaced back side
rails 21 and 22. While in the first embodiment of FIGS. 1-4, the
swing arm 32 was made of a one piece structure, in this second embodiment,
as clearly shown in FIGS. 5 and 6, there are a pair of swing arms,
one for each rear wheel, namely a right swing arm 30A, and a left
swing arm 31A. The rectangular braces 37 and 38 arm fixedly secured
to the top of the swing arms 30A and 31A, respectively, thereby
mounting the rear wheels to the swing arms 30A and 31A, respectively
in a manner like the rear wheels are mounted to the braces 37 and
38 carried by swing arm 32 of the embodiment of FIGS. 1-4. The front
end (The right end as seen in FIG. 5) of the swing arm 31A is secured
to the bottom of the seat carrying bracket by the bolt 29A while
the front end of the swing arm 31A is secured to the bottom of the
seat carrying 25 by the bolt 29A, while the front end of the swing
arm 30A is secured to the bottom of the seat carrying bracket 25
by the bolt 29, with the securement allowing pivotal movement in
a vertical direction. The swing arms 30A and 31A extend rearwardly
and downwardly from the front ends thereof and the rear end of the
arm 30A is turned inwardly at 30B, and the rear end of the arm 31A
is turned inwardly at 31B. A bolt and nut assembly 62 secures the
lower end of a spring shock absorber 63 to the rear end 30B of the
swing arm 30A and a bolt and nut assembly 64 secures the lower end
of a like spring shock absorber 65 to the rear end 31B of the swing
arm 31A. The upper ends of the shock absorbers 63 and 65 are secured,
respectively, to spaced brackets 66 and 67, secured as by welding,
to the rear cross member 18 of the seat frame 10A, so that the shock
absorbers independently cushion between the seat frame 10A and the
control arms 30A and 31A. The spring shocks 63 and 65 have variable
damping and spring rate adjustment, such as a shock absorber available
from the Yamaha Motor Company under part number3YJ22210-50.
Two links of a four link-control structure operatively connect
the seat 10A to the swing arms 30A and 31A. More particularly, spaced
brackets 68 and 69 are secured, as by welding, to the bottom rear
of the lower cross, member 18A of of the seat 10A while upwardly
extending brackets 70 and 71 are respectively secured, as by welding,
to the top of the control arms 30A and 31A and also secured to the
back edge of the brackets 37 and 38. A pair of links 72 and 73 connect
the brackets 68 and 70, and a pair of links 74 and 75 connect the
brackets 69 and 71. The links 72, 73, 74, and 75 are made of two
pieces which are screwed together so the the length thereof can
be adjusted. The upper ends of the links 72 and 73 are secured to
the bracket 70. Each of such securements is by a shouldered bolt
76 secured in the bracket and with the shouldered portion of the
bolt being of semi-spherical configuration and being received an
opening in the adjacent portion of the link, whereby the links can
pivot in a vertical plane relative to the bolts and can also move
angularly relative thereto.
Thus the rear wheels can move independently relative to the seat
frame 10A as well as independently relative to the front wheel assemblies
52.
Although the above description relates to presently preferred embodiments,
numerous changes can be made therein without departing from the
scope of this invention as claimed in the following claims: |