The invention relates to a rigid frame wheelchair which is designed according to the box frame design.
The following specifications relating to the front, rear, right, left, top, bottom and sagittal plane are to be understood from the background of a person seated on the wheelchair and the specifications relating to the vertical, horizontal and perpendicular are also to be understood when arranging the wheelchair on a horizontal substrate.
Rigid frame wheelchairs are sufficiently well known from the prior art. They are used where the main priority is placed on low weight, stiffness and maximum maneuverability.
Said wheelchairs are so-called active wheelchairs with specific options for adjustment and/or individual options for adaptation for active users (in contrast to passive users—pushed by an accompanying person) and differ substantially by two designs: the open frame design and the box frame design.
In the open frame design, the frame (without a rear frame) consists of an L-shaped seat-foot support frame—with a seat frame segment and foot support frame segment—and a rear axle construction welded to the seat frame segment (individual construction) or adjustably fastened (adaptable). The advantages of this design are in the low weight and the space-saving accommodation (with the rear wheels/drive wheels removed) for transport, since the L-shaped frame requires little space and may be inserted easily between other items of luggage in the trunk.
Examples of an open frame design are wheelchairs disclosed hereinafter:
In the box frame design, an additional frame connection from the rear axle to the foot support frame segment is provided in the region of the steering wheels. All of the frame parts are rigidly connected together.
The advantage of the box frame design is in the greater level of stiffness in comparison with the open frame design.
Examples of a box frame design are the wheelchairs disclosed hereinafter:
In the case of the adaptable variant, the steering forks are fastened to the frame so as to be adjustable in terms of angle, so that the rotational axis thereof may always be oriented relative to the perpendicular and/or vertical irrespective of the adjusted seat angle. This is essential for avoiding “wobbling” of the steering wheels. For adjusting the seat angle (or even the rear seat height) the spacing of the rear axle to the seat tube is adjusted. The closer the rear axle is positioned to the seat tube, the greater the seat angle with a given seat height. For installing rear wheels with camber, the camber adapter is rotatably installed in the rear axle tube or in the rear wheel receiver. This permits the adjustment of the camber of the rear wheels when altering the seat angle. The adjustment of the camber is also essential for running the rear wheels with low friction.
The following embodiments refer to the box frame design, in particular with an adaptable frame, such as for example TRA from Permobil or SPEEDY 4TEEN from PROACTIV. Apart from the seat width and seat depth, the essential adapting and/or adjusting parameters of an active wheelchair are:
The relative position—from the lateral view—of the rear axle (drive wheels) to the back is understood here.
The further the rear axle is positioned away from the back to the front—in the direction of travel—the more active the adjustment and/or the closer it is located below the center of gravity of the wheelchair/user system. The wheelchair is thus very maneuverable but at the same time the risk of rollover is increased. A very active adjustment is reserved only for experienced wheelchair users.
The closer the rear axle is positioned relative to, or even behind, the backrest, the more stable the wheel chair is in terms of rollover but it is all the more cumbersome to move.
The adaptation of the seat height and the seat angle in the aforementioned box frame design in an adaptable variant is to be considered more closely.
For the approximate adaptation to different body sizes, most manufacturers provide 3-4 frame sizes. The adjustment of the exact seat height (with a given frame size) is implemented by the choice of steering forks of variable heights and by the positioning of the steering wheels in the steering forks at variable heights, and the adjustment of the seat angle (or rear seat height) by the adjustment of the spacing of the rear axle from the seat frame.
The following drawbacks have to be taken into account in this design:
It is the object of the present invention to provide a rigid frame wheelchair in an adaptable box frame design in which the adjustment of the seat height and the seat angle is able to be carried out with low material use and reduced operating effort.
The object is achieved by a rigid frame wheelchair which is configured according to the present invention, as described and shown herein.
In a rigid frame wheelchair according to the invention, the rigid shape of a box frame is achieved by fixedly welded frame parts and by separate frame parts which are adjustable to one another. A rigid frame wheelchair which is designed according to the box frame design is proposed with the following features:
For achieving greater stability it is regarded as advantageous to install an additional movable transverse strut on the seat-foot support frame in the rear region of the seat tube segments, the left-hand and right-hand frame connectors preferably being able to be fastened to the lateral left-hand and right-hand end thereof.
Since in the construction thus described the base frame always has the same position relative to the road (spacing and angle), neither adjustment operations nor replacement measures which are susceptible to error should be required on the steering forks or on the rear wheels. The seat angle and the seat height are adjusted solely by rotating the seat-foot support frame with the coupling units (seat angle) and/or by displacing into the coupling units (seat height) and by fixing the seat tube segments to the left-hand and right-hand frame connectors.
In particular, the foot support tube segments in the adjusted displaced position thereof are fixedly connected to the coupling units. Additionally, it may be provided to block the joints after the angular adjustment of the foot support tube segments has been carried out.
Further features and advantages of the invention are described in the following detailed description and shown in the accompany drawing figures, which represent exemplary embodiments according to the invention.
The invention is described with reference to exemplary embodiments and shown in the accompanying drawing figures, without being limited thereto.
As essential components, the wheelchair 1 has a base frame 2, a seat-foot support frame 6, a transverse strut 10, a left-hand frame connector 11 and a right-hand frame connector 12, coupling units 13, a backrest frame 14, a foot support 15, rear wheels 16, front wheels 17, a left-hand rear wheel brake 18 and a right-hand rear wheel brake 19 as well as a left-hand fender 20 and a right-hand fender 21 (
Reference is made hereinafter to the view of
The base frame 2 (
The rear axle 5 in the embodiment shown here is displaceable on the struts 3 and 4 for the adjustability of the wheelbase and is fixed by clamping. However, for example, the rear axle could also be fixedly welded directly to the side struts 3 and 4. The rear axle 5 is arranged perpendicular to the sagittal plane.
In the embodiment described (
For the rotatable and positive bearing of the coupling units 13 the multifunction parts 23, at their side oriented toward the sagittal plane, in each case have a blind hole 42 (
The left-hand and right-hand struts 7 and 8 of the seat-foot support frame 6 are received in a linearly adjustable manner with their foot support tube segments 44 in the coupling piece 24 and by means of securing elements 29, 30 and 31 in the coupling piece 24 fixed in a bore 47 (
By means of the clamping element 25 and the connecting elements 26, 27 and 28, the coupling units 13 may be fastened non-positively to the foot support tube segments 44 of the left-hand and right-hand struts 7 and 8. This permits the accurate alignment of the coupling units 13 to the bores 47 and simplifies the positioning and mounting of the connecting elements 29, 30 and 31.
After the securing of the seat angle and seat height as described above, by means of frame connectors 11 and 12 a stable connection may be produced between the base frame 2 and the seat-foot support frame 6 in each case in the rear region thereof. This may be implemented in many different ways, for example by telescopic tubular connections or by struts which may be fastened with different spacings between, and relative to, the base frame 2 and the seat-foot support frame 6.
In a preferred embodiment, the frame connectors 11 and 12 are configured as plates which are fixedly screwed to the rear axle 5 by means of connecting elements 36. These frame connectors 11 and 12 may consist of a different material from the rear axle 5, for example of carbon. The frame connectors 11 and 12 extend with their upper contour preferably approximately concentrically to the rear wheels 16. The frame connectors may serve per se at the same time as clothes protection relative to the spoke wheels and receive a backrest frame construction. The frame connectors have in each case a slot 48 (in this case slightly curved) which extends from slightly above the rear axle 5 obliquely upwardly to the front. These slots 48 correspond to slots 46 in the seat tube segments 45 of the left-hand and right-hand struts 7 and 8 and form therewith, depending on the adjustment of the seat angle, seat height and wheelbase (position of the rear axle 5), a point of intersection at different positions relative to both slots. By means of clamping blocks 38 which are guided in the region and along the slots 46 in the seat tube segments 45 of the left-hand and right-hand struts 7 and 8, and the clamping disks 40 as well as the connecting elements 39 and 41, the left-hand strut 7 is clamped to the frame connector 11 and the right-hand strut 8 is clamped to the frame connector 12, and thus ultimately the entire frame structure is provided with stability.
In each case a camber adapter 35 (in the present case 6°) is connected to the rear axle 5 and the frame connector 11 and/or to the rear axle 5 and the frame connector 12 in the fixed position—without the requirement of re-adjusting the camber in the case of seat angle adjustment.
In a preferred embodiment, an additional transverse strut 10 consisting of the transverse strut tube 37 and the transverse strut couplings 49 is installed. The additional transverse strut is received by the left-hand and right-hand strut 7 and 8 in the transverse strut couplings 49 and the transverse bores 50 of the transverse strut couplings 49 are brought into congruence with the respective points of intersection of the slots 46 and 48. In this position, the transverse strut 10 together with the frame connectors 11 and 12 and the left-hand and right-hand struts 7 and 8 are additionally and at the same time clamped by means of clamping blocks 38, clamping disks 40 and the connecting elements 39 and 41.
The slots 48 may be configured in very different embodiments. A preferred object, however, is that when adjusting the seat angle and the seat height the clamping blocks 38 cover a path which is as wide as possible, both relative to the slots 46 and the slots 48 and thus produce the highest possible level of friction resistance.
In a particular embodiment the slots 48 have increments (
Number | Date | Country | Kind |
---|---|---|---|
18167665.1 | Apr 2018 | EP | regional |