Wheelchair Design
Original Editor - Naomi O'Reilly as part of the Wheelchair Service Provision Content Development Project
Top Contributors - Naomi O'Reilly, Kim Jackson, Simisola Ajeyalemi, Shaimaa Eldib, Amrita Patro, Lucinda hampton and Olajumoke Ogunleye
Introduction[edit | edit source]
The World Health Organisation define a wheelchair as ‘a device providing wheeled mobility and seating support for a person with difficulty in walking or moving about’. Thus, the purpose of a wheelchair is to improve personal mobility. The aim of wheelchair design is to produce wheelchairs that perform well and can provide appropriate seating and postural support without compromising strength, durability and safety. This can be achieved when government authorities, manufacturers, engineers, designers, service providers and users fulfil their respective roles with respect to design. [1]
Wheelchair designs vary greatly to take account of the diverse needs of users with design features, such as the overall length, weight, frame type and width, seat configuration, wheel and castor type, arm and footrests, axle position and propulsion mechanism, all having an influence function. To ensure wheelchairs are appropriate, designers and providers must thoroughly understand the needs of the intended users and their environments. According to Visagie et al (2015) design features must be matched to the user`s functional ability and posture support needs, and also to the environmental and durability requirements. Achieving an ideal match between user, wheelchair design and environment might be as difficult as it is important. [2]
Users’ needs are best met when there is a variety of models from which to choose. Wheelchairs should be designed to enable their users to participate in as many activities as possible. As a minimum, a wheelchair should enable the user to lead a more active life without having a negative effect on their health or safety. Comfort and safety are two important factors affecting the quality of life of long-term users. [1]
According to the World Health Organisation the design of a wheelchair depends on a number of factors:"Design features must be matched to the user`s functional ability and posture support needs, and also to the environmental and durability requirements. Achieving an ideal match between user, wheelchair design and environment might be as difficult as it is important." [3]
- The physical needs of users
- The environment in which the wheelchair will be used; and
- The materials and technology available where the wheelchair is made and used.
General Considerations[edit | edit source]
Wheelchairs should be designed to enable their users to participate in as many activities as possible. As a minimum, a wheelchair should enable the user to lead a more active life without having a negative effect on their health or safety. Comfort and safety are two important factors affecting the quality of life of long-term users. Common wheelchair parts are shown in Fig. 1. A cushion is to be considered an integral part of a wheelchair, and is therefore to be included with all wheelchairs, in particular for wheelchair users with sensory issues to prevent the development of life-threatening pressure sores. [1]
User's Health and Safety[edit | edit source]
Although it may seem that any wheelchair is better than no wheelchair, this is not true when the wheelchair causes or contributes to injury or other health risks. The health and safety of users should never be compromised in order to reduce costs. A wheelchair should be designed to ensure the user's safety and health. There are many ways in which users can be injured by their own wheelchairs, as illustrated by the following examples: [1]
- A wheelchair with an inadequate cushion or no cushion can cause pressure sores;
- Unstable wheelchairs can tip either forward or backwards, leading to users falling out and potentially injuring themselves;
- Shoulder injuries, either through overuse or increased loading can result from a wheelchair that is too wide, too heavy or set up incorrectly for the wheelchair user;
- Sharp edges on surfaces can cause a break in the skin, which in turn can lead to infection.
- Poor design can result in places on the wheelchair where the user can get their fingers or skin pinched.
- Wheelchairs that cannot endure daily use in the user's environment may fail prematurely and can injure the user.
Strength and Durability[edit | edit source]
Wheelchairs used outdoors are subjected to greater wear and tear than those designed for indoor use or use on smooth roads and paths. A wheelchair must be strong enough not to suffer a sudden failure while being used. The wheelchair should be built to have the longest possible useful life and require the fewest repairs, or where repairs are required should be able to to repaired in the users locality with replacement parts be easily available.[1]
Suitability for Use[edit | edit source]
Wheelchairs should be appropriate for the environment in which they will be used and for the specific people who will use them. One wheelchair design will not suit everyone. When designing or selecting wheelchairs, it is necessary to think about the environment and the way in which the wheelchair may be used. Consider the following;[1]
- Pushing for long distances over rough roads.
- Going up and down many kerbs every day.
- Accessing built environments: narrow doorways, small turning areas, steep ramps, desks and tables, bathroom facilities (e.g. sitting and squatting toilets).
- Exposure to moisture such as rain, high humidity, snow, ice, hail and body fluids such as urine and sweat.
- User showering while sitting in the wheelchair.
- Exposure to extreme temperatures.
- User transporting goods on the push handles, upholstery, footrests or other parts of the wheelchair.
- Passengers riding on footrests and armrests.
- People lifting the wheelchair by one armrest, footrest or push handle when the wheelchair is occupied.
- Transporting the wheelchair in confined spaces or other cramped or crowded conditions.
Wheelchair Production[edit | edit source]
When designing a new wheelchair, or selecting a pre-existing wheelchair design, it is important to know where the wheelchair will be produced. In different locations, the technical skills, available technology, materials and components available for production will vary. For this reason, a wheelchair designed for one region may not be suitable in another region. However, the fundamental design might be quite similar. [1]
Wheelchair Design[edit | edit source]
Functional Performance[edit | edit source]
Functional performance is how a wheelchair performs for different users in different environments. The functional performance of a wheelchair is determined by its unique design and features. There are many compromises to consider when designing or selecting for different uses but overall the manual wheelchair should be configured to optimise stability and manoeuvrability for everyday function. Stability is necessary to ensure client safety and security in chair use. Manoeuvrability affects access to tight spaces and the ease of propulsion. Manoeuvrability and stability in the wheelchair can be altered by adjustment of the rear axle and the front castor positions in relation to the centre of mass of the wheelchair and client. In practice an appropriate wheelchair configuration for a given client should balance their need for stability and manoeuvrability. As there is a fine balance between stability and manoeuvrability, wheelchair configuration should be assessed for indoor activities and outdoor use in various environments, and should also be reviewed over time according the changes in the client’s wheelchair skills, experience and health status (e.g. adjusting axle position to compensate for weight gain or loss).
This section provides information on the key features of a wheelchair that affects the main categories of performance and how to evaluate them. It also outlines compromises that need to be considered when choosing different design features. To meet the functional performance needs of individual users, a range of wheelchair designs and sizes are needed. [1]
Wheelchair Stability[edit | edit source]
Stability in relation to manual wheelchair seating can relate to a number of characteristics including:
- The resistance the chair has to being tipped rearwards into a wheelstand
- The resistance the chair has to tipping forwards or sideways, and
- The capacity for the seating to support the client’s seating posture throughout typical daily use.
Wheelchair stability affects how safe the wheelchair is, and how well the user can carry out activities in the wheelchair. Wheelchair tipping causes many injuries for users. Here we look in more detail at stability and consider how to change the set up of the wheelchair for stability.
Static Stability; Relates to the stability of the wheelchair when it is not moving. This determines whether the wheelchair will tip over (where some wheels lose contact with the ground) when the user, for example, leans over to pick something up off of the ground or transfers into or out of their wheelchair.
Dynamic Stability; Relates to the stability of the wheelchair when moving. This determines whether the user can ride over bumps or sloped surfaces without tipping. The design features used to increase wheelchair stability have secondary effects on other functional performance characteristics. For example, moving the front castor wheel forward increases stability but reduces the manoeuvrability of the wheelchair in confined spaces. These relationships are described below.
General Stability; Affected by the position of the combined centre of gravity of the user and the wheelchair relative to its wheelbase. Lowering the seat height is a way of increasing general stability and its associated advantages and disadvantages are shown below;.
Advantages
- It may be easier for the user to reach objects on the floor.
- The seat, including the user’s knees, will be more likely to fit under desks and tables.
- Is easier for those who use their feet for propulsion of the wheelchair
Disadvantages
- Being lower may make it harder to reach objects above.
- The posture may be less comfortable and may increase the pressure on the user’s seat (a cause of pressure sores).
- The user’s pushing position may be worse and access to the hand rims more difficult.
Rearward Stability; Resistance to tipping backwards, is affected by the rear axle position in relation to the user’s centre of gravity. Ways of increasing rear stability and their associated advantages and disadvantages are shown below in Table 1;
Advantages | Disadvantages | |
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Moving the rear wheel further behind the User’s Centre of Gravity | ||
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Using Anti-tip Devices to Prevent Wheelchair Tipping Backwards | ||
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Forward Stability; Affected by the size and position of the front castor wheel in relation to the user’s centre of gravity. Ways of increasing forward stability and their associated advantages and disadvantages are shown in Table 2.
Advantages | Disadvantages |
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Move Front Castor Wheel Forward of User’s Centre of Gravity | |
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Larger Front Castor Wheels | |
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Sideways Stability; Affected by wheelchair width. The further out to the side of the wheelchair the front and rear wheels touch the ground, the more the chair will resist tipping over sideways. Ways of increasing sideways stability and their associated advantages and disadvantages are shown in Table 3.
Advantages | Disadvantages |
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Increasing Width of Wheelchair | |
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Add Camber to Wheels | |
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Users with advanced mobility skills and with good trunk control can partially compensate for some of the wheelchair’s instability if they can balance on the rear wheels and if they can shift their weight forwards, backwards or to the side to prevent tipping.
Manoeuvrability[edit | edit source]
Manoeuvrability in the wheelchair typically refers to a combination of characteristics including:
- The overall ability of the chair to navigate around tight spaces
- The ease with which the speed of the chair can be changed, and
- The ease with which the direction of the chair can be changed.
A very manoeuvrable wheelchair would fit into tight spaces and be very responsive to the user in rolling, turning and performing a wheelstand. However such a wheelchair configuration may be insufficiently stable for safe use by some users, so it is importance to assess the safety of the wheelchair user:
Manoeuvrability Around Obstacles; Determines the user’s ability to manoeuvre in an environment with confined spaces, such as a toilet with a narrow door and very limited space. (Table 4)
- Moving through narrow passageways. The narrowest space through which a wheelchair can pass is determined by its width, measured from the outermost point on each side. The ability to move through narrow passageways can be improved by making the wheelchair narrower.
- Pulling up close to surfaces and objects. How close users can get to surfaces and objects they cannot roll under, such as toilets, low tables, counter tops, centre-post tables and bathtubs, is determined by how far the wheelchair extends both forwards and to the side of the seat. A user can get closer to surfaces and objects if the wheelchair is shorter in height.
- Rolling under surfaces. The user’s ability to pull up to a table is determined by the height of the user’s knees (the length of the user’s lower leg plus the minimum safe height of the footrest above the ground). Some types of fixed armrest also prevent users from pulling up to tables and counters.
- Turning around in confined spaces. The smallest area in which a wheelchair can turn around is determined by its maximum diagonal measurement.
Advantages | Disadvantages |
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Making Wheelchair Shorter and Narrower | |
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Moving Rear Wheel Forward in Relation to User | |
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If Wheelchair has Easily Removable Footrests | |
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Manoeuvrability Over Obstacles; Determines the user’s ability to negotiate obstacles such as soft ground or raised obstacles. When negotiating obstacles, the user is at risk of tipping backwards or forwards and falling out of the chair, a common cause of injury; thus it is also important to consider stability when evaluating a wheelchair’s ability to manoeuvre over obstacles.
- Manoeuvring Over Soft Ground, such as mud, sand, grass, gravel and snow, depends on the area of contact that the wheels have with the ground and the amount of weight on the wheel. Ways of improving manoeuvrability over soft ground and their associated advantages and disadvantages are shown in Table 6.
- Manoeuvring Over Raised Obstacles, such as bumps, kerbs or rocks, depends on many factors. The size of the castor wheel, the distance of the castor wheel from the user’s centre of gravity and the springiness of the castor wheel all have a significant effect. Castor flutter is also a result of hitting bumps at speed. Ways of improving manoeuvrability over raised obstacles and their associated advantages and disadvantages are shown in Table 5.
Advantages | Disadvantages |
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Increasing Width, Diameter and Softness of Castor Wheel to Increase Contact Area
Helps Prevent Wheelchair from Sinking into Soft Ground | |
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Increasing Width, Diameter and Softness of Rear Wheel to Increase Contact Area
Help Prevent Wheelchair from Sinking into Soft Ground | |
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Move Front Castor Wheels Forward to Reduce Weight on Smaller Castor Wheels
Help Prevent Caster Wheels Sinking into Soft Ground | |
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Move Rear Wheels Forward in Relation to User to Reduce Weight on Front Castor Wheels
Help Prevent Caster Wheels Sinking into Soft Ground | |
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Use Rear Wheels with Knobs, such as those on Mountain Bike Tyres
Increase Traction on Soft Ground and Keep Wheels from Slipping | |
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Increasing the Amount of Deflection / Springiness of Castor Wheel | |
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Pushing Efficiency[edit | edit source]
Pushing efficiency is related to the amount of energy required for the user to push the wheelchair over a given distance. Lighter wheelchairs are normally easier to push, but there are many factors and wheelchair features that affect how difficult or easy it is to push one’s wheelchair. Ways of improving the pushing efficiency and their associated advantages and disadvantages are shown in Table 6.
Advantages | Disadvantages |
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Optimise Seat Width and Put Push Rims in Line with Shoulders | |
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Put Camber in Rear Wheels | |
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With an Aligned Wheelchair
Wheelchair is in Good Condition and Working Order | |
A wheelchair with a broken or misaligned component (e.g. untrue wheels, distorted frame, broken bearings causing friction, unparallel wheels or poorly inflated pneumatic tyres) resists the user’s forward motion, thereby wasting much of the user’s pushing energy. | |
On Smooth Ground use Harder Tyres | |
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On Imperfect / Uneven Surfaces (such as outdoors) Use Tyres that Return Energy and “Spring Back” i.e. Pneumatic Tyres | |
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Other Functional Performance Characteristics[edit | edit source]
Ability to Transfer; Depends on the type of transferral that is easiest for the user and whether the wheelchair’s structure impedes transferral. Ways of making transfer easier and their associated advantages and disadvantages are shown in Table 7.
Advantages | Disadvantages |
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Removable or Folding Armrests | |
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Fixed Armrests that do not extend to the Front of the Seat | |
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Detachable Armrests | |
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Removable Footrests | |
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For Standing Transfers, A Seat with Little to No Backward Tilt
(Reclined Seat Angle) | |
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Transporting the Wheelchair; For long-distance travel by, for example, bus, taxi or train, it is important to take account of the design and size of the wheelchair and the materials used in its construction. Weight is a crucial factor in transporting a wheelchair, and weight is determined by the types of component (wheels/frames) used and by the construction materials (e.g. steel, steel/ aluminium alloy or other metal). Reducing weight has a direct effect on durability and cost. Design and size are equally important, foldable and smaller wheelchairs being easier to carry. Ways of making it easier to transport a wheelchair and their associated advantages and disadvantages are shown in Table 8.
Advantages | Disadvantages |
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Reducing the weight of the wheelchair | |
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Using folding mechanisms built into the frame (i.e. cross-folding frame, folding backrest)
to make the wheelchair more compact for transporting | |
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Other Factors | |
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Reliability[edit | edit source]
A wheelchair’s reliability is determined by its durability and the length of its useful life. In the case of failure, the frequency and difficulty of repair also determines the reliability of a particular model of wheelchair. Ways of improving the reliability of a wheelchair include:
- better materials and technologies at an affordable cost;
- fewer removable parts;
- non-folding design where folding is not a necessity;
- use of materials that can be repaired or replaced locally;
- regular servicing, repair and maintenance; and
- knowledge by the user of the product and its use, care and maintenance.
Needs of the User[edit | edit source]
An appropriate wheelchair should make it easier for wheelchair users to carry out the things they need to do. Wheelchair users need to be able to get in and out of their wheelchair, to push their wheelchair, to fold the wheelchair for transport and storage and carry out their daily activities. The right type of wheelchair can make it easier for the wheelchair user to do all these things. [1]
Environment[edit | edit source]
Different types of wheelchair are suited to different environments. Some of the major features that affect how a wheelchair works in a different environment include: [1]
Wheelbase; Distance between the front and rear wheels is important. When the wheels are further apart, this is called a “long-wheelbase”. When the wheels are closer together, this is a “short-wheelbase”. Long-wheelbase wheelchairs are more stable and less likely to tip forward. They can be a good choice for a person who will spend most of the time outdoors and moving over rough or uneven surfaces. There are three-wheel and four-wheel long-wheelbase wheelchairs.
- Three-wheel long-wheelbase wheelchairs are usually very stable and suitable for outdoors on rough terrain.
- Four-wheel long-wheelbase wheelchairs have the front castor wheels under the footrests instead of behind. This gives the wheelchairs a longer wheelbase.
Shorter-wheelbase wheelchairs are more suited to use in places where the ground is flat or the space is confined, indoors, for example. short-wheelbase wheelchairs are more likely to tip forward if going downhill, or if the front wheels hit a bump. Wheelchair users with good mobility skills may use a short-wheelbase wheelchair outdoors by balancing on the back wheels to go down hills and over rough ground.
Size and Width of the Wheels; The larger the wheel, the easier it is to push over uneven ground. Wide rear wheels and large and wide front castors help prevent the wheelchair from sinking into sandy or muddy ground.
Production and Supply[edit | edit source]
Wheelchairs may be produced nationally or imported. To provide a range of wheelchairs, some countries may choose to support both national production and importation. Each supply method has an appropriate application. With many different needs within a region, a variety of supply methods may be suitable, the long term goal being sustainable solution. It is recommended that all wheelchairs, irrespective of supply method, meet or exceed national wheelchair standards and be repairable locally. Fig. 3. [1]
When determining whether to acquire wheelchairs via import or local production, decision-makers are advised to balance a variety of factors including: [1]
- the needs of local wheelchair users;
- the quality and variety of wheelchair models;
- the long-term reliability of supply of wheelchairs and spare parts;
- the possibility of influencing the design, features, materials, etc.;
- the purchase price;
- the cost of repair and replacement;
- the effect on local employment and wheelchair production;
- coordination of supply with an overall plan for wheelchair provision;
- the amount and term of the funding available; and
- policies and strategies, including long-term sustainability.
References[edit | edit source]
- ↑ 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 William Armstrong, Johan Borg, Marc Krizack, Alida Lindsley, Kylie Mines, Jon Pearlman, Kim Reisinger, Sarah Sheldon. Guidelines on the Provision of Manual Wheelchairs in Less Resourced Settings. World Health Organization; Geneva: 2008.
- ↑ Visagie S, Duffield S, Unger M. Exploring the impact of wheelchair design on user function in a rural South African setting. African Journal of Disability. 2015;4(1).
- ↑ Di Marco A., Russel M. & Masters M., 2003, ‘Standards for wheelchair prescription’, Australian Occupational Therapy Journal 50 (1), 30–39. http://dx.doi.org/10.1046/j.1440-1630.2003.00316.x