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Chapter 10: Problem 37

Supporting a broken leg. A therapist tells a 74 kg patient with a broken leg that he must have his leg in a cast suspended horizontally. For minimum discomfort, the leg should be supported by a vertical strap attached at the center of mass of the leg-cast system. (See Figure \(10.57 . )\) In order to comply with these instructions, the patient consults a table of typical mass distributions and finds that both upper legs (thighs) together typically account for 21.5\(\%\) of body weight and the center of mass of each thigh is 18.0 \(\mathrm{cm}\) from the hip joint. The patient also reads that two lower legs (including the feet) are 14.0\(\%\) of body weight, with a center of mass 69.0 \(\mathrm{cm}\) from the hip joint. The cast has a mass of \(5.50 \mathrm{kg},\) and its center of mass is 78.0 \(\mathrm{cm}\) from the hip joint. How far from the hip joint should the supporting strap be attached to the cast?

Short Answer

Expert verified
The strap should be attached 45.03 cm from the hip joint.

Step by step solution

01

Understand the Problem and Gather Information

We need to determine the point at which to attach a support strap to a patient's leg in a cast to minimize discomfort by aligning it with the center of mass (COM) of the leg-cast system. We have the patient's body weight, the mass distribution of the legs, and the mass and COM of the cast.
02

Calculate Leg Weights

The patient's total body weight is 74 kg.- Combined weight of upper legs (thighs): \(0.215 \times 74 \text{ kg} = 15.91 \text{ kg}\)- Combined weight of lower legs and feet: \(0.14 \times 74 \text{ kg} = 10.36 \text{ kg}\)
03

Determine the Moment Arms

Moments are calculated based on the weight and distance from the hip joint for each component:- Thighs' moment: \(15.91 \text{ kg} \times 18 \text{ cm} = 286.38 \text{ kg} \cdot \text{cm}\)- Lower legs' moment: \(10.36 \text{ kg} \times 69 \text{ cm} = 715.44 \text{ kg} \cdot \text{cm}\)- Cast's moment: \(5.5 \text{ kg} \times 78 \text{ cm} = 429 \text{ kg} \cdot \text{cm}\)
04

Calculate Total Moment

Sum the moments to find the total moment of the whole system:\[ \text{Total Moment} = 286.38 + 715.44 + 429 = 1430.82 \text{ kg} \cdot \text{cm} \]
05

Calculate Total Mass of the System

Combine the mass of the thighs, lower legs, and cast:\[ \text{Total Mass} = 15.91 \text{ kg} + 10.36 \text{ kg} + 5.5 \text{ kg} = 31.77 \text{ kg} \]
06

Determine Center of Mass Position

The center of mass (COM) position from the hip joint is calculated as the total moment divided by the total mass:\[ \text{COM Position} = \frac{1430.82 \text{ kg} \cdot \text{cm}}{31.77 \text{ kg}} \approx 45.03 \text{ cm} \]
07

Conclusion

Attach the supporting strap at approximately 45.03 cm from the hip joint to minimize discomfort by aligning with the center of mass.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Center of Mass Calculation
The center of mass, often termed as COM, is the point where the entire mass of a system can be considered to be concentrated. It plays a crucial role, especially in biomechanics, when analyzing systems like a leg in a cast. To calculate the COM, you need to account for all parts of the system and their individual moments. These are essentially the product of each part's mass and its distance from a reference point, generally the hip joint in this context.

In our problem, the task is to find the suitable position to attach a support strap that horizontally suspends a patient's leg in a cast. We need to find where the sum of the moments is balanced by the combined weight of all components, which gives the position of the COM.

Using the equation: \[ \text{COM Position} = \frac{\text{Total Moment}}{\text{Total Mass}} \]An accurate COM finds the most comfortable position. Aligning the support strap with this point reduces discomfort for the patient. The equation ensures that the overall moments (or rotations caused by the distributed mass) are balanced.
Moment of Inertia
Moment of inertia is a key concept in understanding how bodies will rotate based on mass distribution. Although not directly used here, it is closely related to the concept of moments. In biomechanics, the moment of inertia describes how distribution of mass about an axis influences rotational motion.

When managing leg casts, it's vital to consider moments, and by extension inertia, to prevent unnecessary rotational torque which could cause discomfort or injury. The inertia, calculated via the integral of mass elements and their squared distances from the pivot, is pivotal in analyzing the rotational equivalent of mass in motion.

Understanding moment of inertia allows biomechanists and physicians to make more informed decisions about support placements such as straps or casts as it influences balance and stability.
Mass Distribution
Mass distribution refers to how mass is spread out in an object or system, affecting its balance and stability. In the context of supporting a broken leg suspended horizontally, understanding this distribution is critical.

For our patient's leg and cast system:
  • Upper legs account for 21.5% of the body weight.
  • Lower legs make up 14% of the body weight.
  • The cast itself adds additional weight and alters the normal COM.
These percentages are crucial as the mass distribution directly impacts where the supporting strap should be attached. Distributing the mass evenly, especially in medical contexts, aids in positioning support structures in a way that minimizes discomfort or strain.
Biomechanics
Biomechanics is the study of the mechanical laws relating to the movement or structure of living organisms, such as humans. In our scenario, it helps us understand how different parts of the leg affect the entire system's balance and stability when suspended.

By incorporating biomechanics, medical professionals can determine optimal support solutions that align with the natural movement and structural needs of the body. This includes calculating forces, like those exerted by or on tendons, muscles, and bones, ensuring the system's equilibrium is maintained.

An engagement with biomechanics not only aids recovery by promoting comfort mitigation of undue stress through correct weight and force distribution, but also provides a scientific basis for therapeutic practices.
Torque and Equilibrium
Torque is the force that causes an object to rotate about an axis. In a suspended leg scenario, minimizing rotational discomfort requires the system to be in equilibrium, meaning all forces and torques are balanced.

Equilibrium is achieved when the sum of all torques about any pivot point is zero. In our example, the supporting strap must be positioned at the point where the torques generated by the mass of the thigh, lower leg, and cast balance one another. This ensures that the leg remains stable and does not tilt to one side, which could lead to further injury or discomfort.

Understanding how torque functions simplifies configuring support systems correctly, emphasizing the need to find the center of mass accurately to achieve the desired balance. This balance between forces underscores the importance of accurate load distributions, essential in both physics and medical settings.

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Most popular questions from this chapter

\(\bullet\) Calculate the angular momentum and kinetic energy of a solid uniform sphere with a radius of 0.120 \(\mathrm{m}\) and a mass of 14.0 \(\mathrm{kg}\) if it is rotating at 6.00 \(\mathrm{rad} / \mathrm{s}\) about an axis through its center.

What would be the radial (centripetal) acceleration of an astronaut standing on the inner surface of the space station, which is at a distance of 240 \(\mathrm{m}\) from the axis of rotation, once the space station reaches its final angular velocity of 0.20 \(\mathrm{rad} / \mathrm{s}\) ? A. 0 \(\mathrm{m} / \mathrm{s}^{2}\) B. 4.8 \(\mathrm{m} / \mathrm{s}^{2}\) \(\mathrm{C}, 9.6 \mathrm{m} / \mathrm{s}^{2}\) D. 48 \(\mathrm{m} / \mathrm{s}^{2}\)

A \(\mathrm{A} 2.00 \mathrm{kg}\) stone is tied to a thin, light wire wrapped around the outer edge of the uniform 10.0 \(\mathrm{kg}\) cylindrical pulley shown in Figure \(10.47 .\) The inner diameter of the pulley is \(60.0 \mathrm{cm},\) while the outer diameter is 1.00 \(\mathrm{m}\) . The system is released from rest, and there is no friction at the axle of the pulley. Find (a) the acceleration of the stone, (b) the tension in the wire, and (c) the angular acceleration of the pulley.

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A a uniform drawbridge must be held at a \(37^{\circ}\) angle above the horizontal to allow ships to pass underneath. The drawbridge weighs \(45,000 \mathrm{N},\) is 14.0 \(\mathrm{m}\) long, and pivots about a hinge at its lower end. A cable is connected 3.5 \(\mathrm{m}\) from the hinge, as measured along the bridge, and pulls horizontally on the bridge to hold it in place. (a) What is the tension in the cable? (b) Find the magnitude and direction of the force the hinge exerts on the bridge. (c) If the cable suddenly breaks, what is the initial angular acceleration of the bridge?
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