Prototype myoelectric hand

Prototype myoelectric hand, made to the design primarily developed by Colin Light as part of the Southampton Hand project at the School of Electronics and Computer Science, University of Southampton, England, 1996-2000

Also known as the Remedi-Hand, this protoype was part of a project to devleop a lightweight prosthetic hand that could mimic the movements and control of a human hand. Each digit has senors to monitor and control grip. Four motors move the fingers and two others power the thumb. This work built on that of Paul Chappell, also part of the Southampton Hand project.

Begun by Professor Jim Nightingale, Professor of Control Engineering at the University of Southampton in the 1960s, the Southampton Hand project ran for over 50 years. Many engineers interested in developing new types of prosthetic arms worked on the project, each adding their own advances to the project. Inspired by how our brains and hands communicate they aimed to make a prosthetic arm that was easy for users to control. The user initiates movement by thinking, which activates the muscles in their arm. This is detected and it opens and closes the hand. Sensors on the hand detect what shape object is within the hand and the microcontroller selects the grasp that is needed. This work led to the first microprocessor controlled prosthetic hands to be used in the outside of clinical trials.

Details

Category:
Orthopaedics
Object Number:
2021-1259
Materials:
metal, plastic and electronic components
Measurements:
overall: 345 mm x 110 mm x 80 mm,
overall (circuit boards): 40 mm x 140 mm x 226 mm,
type:
hand

Parts

Prototype myoelectric hand

Prototype myoelectric hand

Prototype myoelectric hand, made to the design primarily developed by Colin Light as part of the Southampton Hand project at the School of Electronics and Computer Science, University of Southampton, England, 1996-2000

More

Also known as the Remedi-Hand, this protoype was part of a project to devleop a lightweight prosthetic hand that could mimic the movements and control of a human hand. Each digit has senors to monitor and control grip. Four motors move the fingers and two others power the thumb. This work built on that of Paul Chappell, also part of the Southampton Hand project.

Begun by Professor Jim Nightingale, Professor of Control Engineering at the University of Southampton in the 1960s, the Southampton Hand project ran for over 50 years. Many engineers interested in developing new types of prosthetic arms worked on the project, each adding their own advances to the project. Inspired by how our brains and hands communicate they aimed to make a prosthetic arm that was easy for users to control. The user initiates movement by thinking, which activates the muscles in their arm. This is detected and it opens and closes the hand. Sensors on the hand detect what shape object is within the hand and the microcontroller selects the grasp that is needed. This work led to the first microprocessor controlled prosthetic hands to be used in the outside of clinical trials.

Measurements:
overall: 345 mm x 110 mm x 80 mm,
Materials:
metal , plastic and electronic components
Object Number:
2021-1259/1
type:
hand
Circuit boards for prototype myoelectric hand

Circuit boards for prototype myoelectric hand

Three circuit boards, electrical components for prototype myoelectric hand, made to the design primarily developed by Colin Light as part of the Southampton Hand project at the School of Electronics and Computer Science, University of Southampton, England, 1996-2000

More

Also known as the Remedi-Hand, this protoype was part of a project to devleop a lightweight prosthetic hand that could mimic the movements and control of a human hand. Each digit has senors to monitor and control grip. Four motors move the fingers and two others power the thumb. This work built on that of Paul Chappell, also part of the Southampton Hand project.

Begun by Professor Jim Nightingale, Professor of Control Engineering at the University of Southampton in the 1960s, the Southampton Hand project ran for over 50 years. Many engineers interested in developing new types of prosthetic arms worked on the project, each adding their own advances to the project. Inspired by how our brains and hands communicate they aimed to make a prosthetic arm that was easy for users to control. The user initiates movement by thinking, which activates the muscles in their arm. This is detected and it opens and closes the hand. Sensors on the hand detect what shape object is within the hand and the microcontroller selects the grasp that is needed. This work led to the first microprocessor controlled prosthetic hands to be used in the outside of clinical trials.

Measurements:
overall: 345 mm x 110 mm x 80 mm,
Materials:
metal , plastic and electronic components
Object Number:
2021-1259/2
type:
circuit boards