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Total, external and internal work for human movement
ABSTRACTS
OF THE EIGHTH ANNUAL CONFERENCE AMERICAN SOCIETY OF BIOMECHANICS Held in Tucson,
THE KISEMATICS
ASD
Kl;VETICS
Arizona,
3-5 October
OF SWINGING
The purpose
was to develop
Cam camera operating conditions: during
a spike mallet flexion during
spike condition, 200 m
hammer
the sledge condition
of trunk
a profile
s- ’ compared
with 280 m
swinging
the spike condition.
of the downswing
s- ’ developed
for the spike mallet
company
views of hammer
head. The movement
Although
with the spike mallet. Torques
than for the sledge. The output
two
was greater
showed similar speed
prior
acceleration
to impact
with the
of the sledge head was
at the lumbar
from
A Lo
under
of the trunk
its movement
The terminal
employee.
swinging
both performances
stopped
HARIhIERS
Urbana-Champaign)
male railroad
sagittal
the trunk
decreased its displacement.
OF RAILROAD
of Illinois.
for a skilled
was used to obtain
head and a sledge hammer
than during
the majority
whereas the trunk
to be 35”,, greater
of hammer
at 100 frames s-*
1984
TWO TI.PES
MARLENE ADRIAN and GERALD SMITH (University
OF THE
spine were estimated
this subject
can be a model
for
emulation.
TOTAL,
EXTERNAL
AND INTERNAL
SERGEI Y u. A LESHINSKY (Biomechanics
Different
methods currently
Among
these methods
However
used to calculate
mechanical
one of the most popular
the reason for this discrepancy
MOVEMENT
The Pennsylvania
energy during
movement
is to sum up ‘external’
analysis of the simplest example ofa one-link
To find out
WORK FOR HUMAN
Laboratory,
movement
a mathematical
State University)
give radically
and ‘internal’
work
shows the incorrectness
description
of a moving
different
results.
to get ‘total’
work.
of such an approach. multi-link
model
was
undertaken. It was shown that some components other
and required
W”,,, = %,Vn~l
no energy
of external
supply.
+ %rrmai. he unintentionally
INDIVIDUAL
MUSCLE
and internal
But if one follows includes
AND JOINT
energy always fluctuated
the traditional
the cncrgy
FORCES
total
work.
i.e.
cost of these lluctuations.
ACROSS
K. N. AFT, B. F. MORREY and E. Y. CHAO (Biomechanics
out of phase with each
way of calculating
THE ELBOW
Laboratory,
Mayo
Clinic,
IN SPORTS Rochester,
MN
55905.
U.S.A.) Knowing
the individual
information
muscle and joint
forces across the joints
can not only be used to assist in the design ofathletic
the mechanism
and management
ofsports
injuries.
forceanalysis
is presented. A new optimization
is introduced
to resolve the indeterminate
moments and joint
A BIODYNAMIC
MODEL
procedures,
In this study, the development
approach, problem
angles at the elbow during
in sports is significant training
running,
based on minimizing
for a unique
solution.
in several respects. This
but also for understanding
ofan
analytic
model for elbow
the upper bounds of muscle stress, By using the data of intersegmental
the results of major elbow muscle I’orces can be calcclated.
INDUSTRIAL
PUSH/PULL
R. 0. ANDRES. D. S. BLOSWICK and D. B. CHAFFIN (Center for Ergonomics.
FOR INVESTIGATING
The University
Ann Arbor, A sagittal pulling:
plane biodynamic
the risk of back injury
compressive
force,
Laboratory
validation
while
model
the slip hazard experiments
MI 48109, U.S.A.)
has been developed
and the risk of slipping. is surmised
were
designed
TASKS of Michigan,
to predict
two risks associated
The risk of back injury
with cart pushing
is assessed by predictions
from
predictions
of the required
and
performed
to
compare
coefficient
model
and
of Lj/SI of friction.
predictions
with
OF THE EIGHTH ANNUAL CONFERENCE AMERICAN SOCIETY OF BIOMECHANICS Held in Tucson,
THE KISEMATICS
ASD
Kl;VETICS
Arizona,
3-5 October
OF SWINGING
The purpose
was to develop
Cam camera operating conditions: during
a spike mallet flexion during
spike condition, 200 m
hammer
the sledge condition
of trunk
a profile
s- ’ compared
with 280 m
swinging
the spike condition.
of the downswing
s- ’ developed
for the spike mallet
company
views of hammer
head. The movement
Although
with the spike mallet. Torques
than for the sledge. The output
two
was greater
showed similar speed
prior
acceleration
to impact
with the
of the sledge head was
at the lumbar
from
A Lo
under
of the trunk
its movement
The terminal
employee.
swinging
both performances
stopped
HARIhIERS
Urbana-Champaign)
male railroad
sagittal
the trunk
decreased its displacement.
OF RAILROAD
of Illinois.
for a skilled
was used to obtain
head and a sledge hammer
than during
the majority
whereas the trunk
to be 35”,, greater
of hammer
at 100 frames s-*
1984
TWO TI.PES
MARLENE ADRIAN and GERALD SMITH (University
OF THE
spine were estimated
this subject
can be a model
for
emulation.
TOTAL,
EXTERNAL
AND INTERNAL
SERGEI Y u. A LESHINSKY (Biomechanics
Different
methods currently
Among
these methods
However
used to calculate
mechanical
one of the most popular
the reason for this discrepancy
MOVEMENT
The Pennsylvania
energy during
movement
is to sum up ‘external’
analysis of the simplest example ofa one-link
To find out
WORK FOR HUMAN
Laboratory,
movement
a mathematical
State University)
give radically
and ‘internal’
work
shows the incorrectness
description
of a moving
different
results.
to get ‘total’
work.
of such an approach. multi-link
model
was
undertaken. It was shown that some components other
and required
W”,,, = %,Vn~l
no energy
of external
supply.
+ %rrmai. he unintentionally
INDIVIDUAL
MUSCLE
and internal
But if one follows includes
AND JOINT
energy always fluctuated
the traditional
the cncrgy
FORCES
total
work.
i.e.
cost of these lluctuations.
ACROSS
K. N. AFT, B. F. MORREY and E. Y. CHAO (Biomechanics
out of phase with each
way of calculating
THE ELBOW
Laboratory,
Mayo
Clinic,
IN SPORTS Rochester,
MN
55905.
U.S.A.) Knowing
the individual
information
muscle and joint
forces across the joints
can not only be used to assist in the design ofathletic
the mechanism
and management
ofsports
injuries.
forceanalysis
is presented. A new optimization
is introduced
to resolve the indeterminate
moments and joint
A BIODYNAMIC
MODEL
procedures,
In this study, the development
approach, problem
angles at the elbow during
in sports is significant training
running,
based on minimizing
for a unique
solution.
in several respects. This
but also for understanding
ofan
analytic
model for elbow
the upper bounds of muscle stress, By using the data of intersegmental
the results of major elbow muscle I’orces can be calcclated.
INDUSTRIAL
PUSH/PULL
R. 0. ANDRES. D. S. BLOSWICK and D. B. CHAFFIN (Center for Ergonomics.
FOR INVESTIGATING
The University
Ann Arbor, A sagittal pulling:
plane biodynamic
the risk of back injury
compressive
force,
Laboratory
validation
while
model
the slip hazard experiments
MI 48109, U.S.A.)
has been developed
and the risk of slipping. is surmised
were
designed
TASKS of Michigan,
to predict
two risks associated
The risk of back injury
with cart pushing
is assessed by predictions
from
predictions
of the required
and
performed
to
compare
coefficient
model
and
of Lj/SI of friction.
predictions
with