Biomechanics
A requirement in traction is that the traction force is equal in magnitude but in the opposite direction to the counter-traction force. This requirement is really a statement of:
Ohm’s law
Pascal’s principle
Newton’s first law
Newton’s third law
Newton’s third law
Newton’s third law, F1 = -F2. When an object (the hanging mass) exerts a force on another object (the patient in traction), the second object exerts an equal but opposite force on the first object.
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When two forces of magnitude 6 N and 10 N are added vectorially, what value could the resulting vector NOT have?A. 4 N
B. 6 N
C. 10 N
D. 18 N
Which of the following is not an example of a force?
A. Tension
B. Friction
C. Inertia
D. Weight
What is the purpose of using a slide sheet in patient manual handling?
A. To extend the patient’s base of support
B. To facilitate raising the patient’s centre of gravity
C. To minimise friction between the patient and the bed
D. To minimise the patient’s inertia
Traction forces may be represented by vectors. In Hamilton-Russell traction, which of the following vectors is equal in magnitude to the traction force?
A. The component of the patient’s weight that is perpendicular to the bed
B. The component of the patient’s weight that is parallel to the bed
C. The vector in A subtracted from the patient’s weight
D. The resulting vector when the vectors in A and B are added
What does the term “friction” refer to?
A. The tension force generated when a muscle contracts
B. A force that acts in the opposite direction to a motion
C. The resistance force that is overcome by an effort force
D. The force of gravity that causes an object to fall
When the biceps brachii muscle flexes the forearm, what is the forearm an example of?
A. A first-class lever
B. A second-class lever
C. A third-class lever
D. An efficient lever
Third-class lever systems are always inefficient for which one of the following reasons?
A. The effort arm is longer than the load arm.
B. The effort force required is less than the load force.
C. The fulcrum lies between the effort and the load. The load arm is longer than the effort arm.
D.
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