Mechanical Effect Analysis of Braking in Sports
Liguo ZHENG
Taishan Medical University, Taian, Shandong, 271000, China
Keywords: Sports, Braking, Mechanical Effect, Analysis.
Abstract: In games, high-speed movements are required to stop or slow down. It is necessary to focus on applying
body force to braking. In the work, braking to change sports state was conducted with mechanical analysis
to derive the key force of braking—friction force based on Newton laws of motion. After that, mechanical
factors of braking were analyzed according to theorems of momentum and kinetic energy. We obtain the
relation between braking effect and factors including braking force, distance and time. After impact analysis
of braking action and power source, mechanical principles were applied to achieve a better braking effect by
examples.
1 INTRODUCTION
In sports, human body was usually at a high-speed
state. Human body was required to slow down or
stop in games including dash, gymnastics, skiing,
skating, football, basketball, etc. An unsuccessful
braking resulted in failure and accident of sports.
Therefore, mechanical effect analysis played an
important role in completing sports and obtaining
better competition results. Games were conducted
with mechanical effect analysis based on physical
principle of nature.
2 MECHANICAL PRINCIPLE
ANALYSIS OF BRAKING IN
SPORTS
2.1 Relation between Body Motion
State and Applied Force
There are two motion states of body including
stationary and uniform motion according to
Newton's first law of motion law of inertia. Body
motion can be described as the result of exogenic
action.
Newton's first law of motion can be expressed as
follows.
0 0
i
i
dv
F
dt
= ⇒ =
∑
where
i
i
F
∑
is the resultant force; v the speed; t
the time.
If there is no external force (Fi = 0), then the
body will be static (v = 0). The Equation Fi = 0 can
be divided into two conditions including bodies with
a friction force of 0 and with no friction force. The
forces are applied to the body to derive phenomenon
of stationary-to-motion and motion-to-stationary.
There are kinds of forces applied to the body, such
as traction, resistance, gravity and support force.
Motion state of the body is affected by resultant. If
certain force is dominant, it will cause the motion
result of the body. E.g., if a car is started and given
enough oil, the traction will be larger than
resistance. The resultant is more than 0, and the car
is in a steady state. If the oil is not enough, the
traction will be equal to resistance. The resultant is
0, and the car keeps moving in a steady state. If the
brake is hit, the traction will be smaller than
resistance. The resultant is less than 0, and the car is
in a decelerated motion. In sports, we focus on
mechanical effects of braking including the body
with a larger traction, zero resultant and decelerated
motion.
2.2 Relation between Applied Force
and Accelerated Speed in a Motion
State
The accelerated speed increases with the increase of
the applied force based on Newton's second law of
240
240
Zheng L.
Mechanical Effect Analysis of Braking in Sports.
DOI: 10.5220/0006023202400243
In Proceedings of the Information Science and Management Engineering III (ISME 2015), pages 240-243
ISBN: 978-989-758-163-2
Copyright
c
2015 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
motion. For equivalent force, the body with smaller
mass has a larger accelerated speed. The body with a
mass to certain extent has no accelerated speed. The
directions of the force and
F
a
m
∝
where
F
is the applied force (N); mass (kg);
a
accelerated speed (
2
/
m s
).
Human is the body with kinds of motion states in
sports. Newton's second motion law illustrates
change of motion state and relation between applied
forces. Therefore, for braking deceleration, the
baking force is the key factor while the mass of body
is determined. If the braking force is larger, the
accelerated speed will be larger. The braking in
high-speed motion will be efficiently achieved.
2.3 Friction Force
—
A Key of
Achieving Braking in Sports
In the process of human body motion, traction is
produced by friction of body muscle. The resistance
of body motion, including wind and friction force,
comes from body muscle motoricity. As the source
of main braking force in sports, the motoricity can
apply friction and resistance to human motion. For
human body at a high speed, larger resistance and
shorter time will cause a larger accelerated speed
and better braking effect.
Mechanical effect of body from motion to static
state is analyzed to derive braking effect in sports.
Accelerated traction and braking resistance are
realized by friction between body and ground. The
friction is in proportion to pressure and friction
coefficient. Therefore, braking force of body motion
is determined by pressure, friction coefficient and
reacting force.
For every action, there is an equal and opposite
reaction based on Newton's third law of motion. An
example shows a person sits in a chair. The pressure
of body and the support force of the chair are a
couple of actions. In sports, the pressure that body
applies to the ground and the support force that
ground applies to the body are a couple of actions.
Then, the friction is produced to achieve traction and
braking force of body motion.
The pressure that body applies to the ground is
constant in high-speed motion. The friction is in
proportion to friction coefficient. The friction
coefficient has a close relation with sports shoes.
Good sports shoes are designed considering
mechanical performance, beauty, bearing and
friction coefficient. Different characteristics of
sports make friction coefficients of designed shoes
different. In general, kinds of patterns and hobnails
on the soles are designed to increase traction and
braking force.
For braking effect of human body in sports, we
focus on analyzing change laws of momentum and
kinetic energy.
3 RELATION BETWEEN
MECHANICAL BRAKING
FACTORS IN SPORTS
3.1 Kinetic Analysis of Braking in
Sports
Energy produced by object motion is called kinetic
energy. Energy production is a process of dong
work. E.g., people get hot and sweat because
thermal energy is produced. In braking process, the
braking force does work to change the object from
motion to static state. The work is half of the product
of mass and the square of speed. While the speed is
the same, the cars with different masses have
different kinetic energies. A truck has a larger
braking distance than a car with the same speed. For
the same car, the kinetic energy at high speed is
larger than that at low speed. Therefore, people are
required to drive slowly for safety. The result of
synthetic action to an object is expressed as follows.
2 2
0
1 1
2 2
t
W mv mv
= −
Kinetic principle reflects cumulative effect of
force in space. It can be expressed as follows.
2 2
0
1 1
2 2
t
Fs mv mv
= −
The mass of human body is constant in the
movement. Therefore, the change of kinetic energy
is determined by the speed of movement. While
speed and kinetic energy are the same, braking force
is inversely proportional to braking distance, and
proportional to the square of speed. Consequently,
the influence of speed to braking force is larger than
braking distance.
3.2 Momentum Analysis of Braking in
Sports
Motion effect can be reflected by momentum
product of object mass and speed. Momentum effect,
Mechanical Effect Analysis of Braking in Sports
241
Mechanical Effect Analysis of Braking in Sports
241
determined by object mass and speed, can be
expressed as Ft=m
∆
v. In time axis, momentum law
is used to express accumulation of force results. So
we obtain that momentum is in proportion to mass
and speed.
Law of conservation of momentum is expressed
as follows.
2 1
Ft mv mv
= −
In sports, human body follows law of
conservation of momentum. As the mass of human
body is definite, the momentum of human body is
determined by the speed. The human motion braking
process is a sharp change of speed. The braking
momentum is in proportional to braking force and
time. While braking force is constant, the change of
braking momentum is proportional to braking time.
When the change of momentum is constant, the
braking force is reversely proportional to braking
time. Therefore, braking effect can be improved by
increasing braking force and time.
4 MECHANICAL ANALYSIS OF
BRAKING ACTION IN SPORTS
In sports, braking action has great influence on
braking force. The addition of pressure contributes
to the form of larger braking force in short time.
E.g., athletes raise commencing height and jump
distance by high-speed approach in long jump. The
athletes realize safe landing by forward stroke of
legs and feet, thus avoiding falling to the ground.
Mechanical analysis of this braking action is
conducted. The forces applied to athletes in a
jumping state are gravity and wind resistance. In
long jump, the athletes form a parabolic curve of
high-speed. The athlete has an inertial force forward
to form momentum and kinetic energy of human
body. Meanwhile, there exists downward gravity
acceleration and kinetic energy. At the moment of
landing, legs and feet produce ground support by
forward stroke. The inertia of athletes makes a huge
friction between legs and ground. The friction force
is proportional to pressure while friction coefficients
and areas are the same. The huge friction force will
result in sudden stop of athletes' legs. If the athlete
does not stop, he will fall down by effect of inertia.
The athlete can increase braking time by forward
stroke and bending of legs to avoid falling. The
control of braking force and time can decrease the
reacting force of ground to achieve effective braking
of forward and downward action.
5 POWER SOURCE AND
INFLUENCE OF BRAKING TO
HUMAN BODY
Braking force comes from internal force of human
body produced by muscle. Tensile force originates
from muscle contraction, and support force from
bone and soft tissue. In sports, braking force should
be supported by bone and soft tissue. Overlarge
braking shock will cause body hurt. E.g., in high
jump, the body should fall to the buffer cushion to
raise braking time. Otherwise, the huge braking
counterforce will hurt human body.
6 CASE ANALYSIS USING
MECHANICAL PRINCIPLES IN
SPORTS
In sports, braking force is added to achieve prompt
braking in a short distance. E.g., some students go
climbing. A girl trips down the hill. Suddenly, a boy
calls her to stop because there is a cliff ahead. The
smart girl slows down with her hip on the ground. At
last, she is lucky to stop. Now we analyze braking
mechanical effect of the girl. The forces applied to
the girl are gravity, ground supporting force, forward
traction and braking friction. The angle between
gravity and ground supporting force is less than 180
degree in the slope. The combined action of the two
forces produces a propulsive force downward along
the slope. The traction derived from gravity is added
with the propulsive force to produce accelerated
speed. The accelerated speed makes it difficult to
stop in a finite distance. The girl applies resistance
by feet while stopping traction. The friction
resistance applied by her muscle is partially offset
by propulsive force downward. The small friction
resistance cannot achieve complete braking within
finite distance. Then she sits on her hip to increase
the friction force between body and ground. The
friction force is proportional to the area while
friction coefficients and pressures are the same.
Therefore, the friction force is larger than propulsive
force downward, thus achieving braking in finite
distance. Finally, she stops before falling down the
cliff.
7 CONCLUSIONS
Consequently, the braking effect in sports can be
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ISME 2015 - International Conference on Information System and Management Engineering
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improved by addition of braking force, time and
distance based on scientific theories. In daily
exercises, braking effect can be improved by raising
physical quality, muscular contractility and shock
resistance. Besides, we can apply other methods
including increasing friction coefficient of sports
shoes and buffered devices. Multiple braking
methods should be trained to avoid impact damage
of promote braking to human body.
REFERENCES
Cui Li, 1989(3): 47-49. Mechanical effect of braking in
sports, Journal of Teaching and Management (Middle
School Edition).
Meng Xianjuan, 2008(3): 107-109. Pre-squatting brake—
key movement of jerking technique, Journal of Harbin
Institute of Physical Education.
Zhang Zhonghai, 2009(32): 276-281. Basic braking
technique in rollerblade club teaching, Information
Technology.
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Mechanical Effect Analysis of Braking in Sports
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