Examples of cables | Additional Study Material for Mechanical Engineering PDF Download

Example 31.1  

Determine reaction components at A and B, tension in the cable and the sag yB, and yE  of the cable shown in Fig. 31.4a. Neglect the self weight of the cable in the analysis. 

Examples of cables | Additional Study Material for Mechanical Engineering

Examples of cables | Additional Study Material for Mechanical EngineeringExamples of cables | Additional Study Material for Mechanical Engineering

Examples of cables | Additional Study Material for Mechanical EngineeringExamples of cables | Additional Study Material for Mechanical Engineering

Since there are no horizontal loads, horizontal reactions at A and B should be the same. Taking moment about E, yields 

Ray *14 −17 * 20 −10 * 7 − 10 * 4 = 0

Rαy = 280/14 =20kN      Rey = 37 20 17kN.

Now horizontal reaction H may be evaluated taking moment about point  of all forces left of C . 

Ray *7 − H * 2−17*3 = 0

H = 44.5 kN

Taking moment about B of all the forces left of B and setting MB= 0 , we get 

Ray H * yB =0;   yB = 80/44.50 = 1.798 m

Similarly, yD = 68/44.50 =1.528m

To determine the tension in the cable in the segment AB , consider the equilibrium of joint A (vide Fig.31.4b). 

Examples of cables | Additional Study Material for Mechanical Engineering

The tension Tab may also be obtained as 

Examples of cables | Additional Study Material for Mechanical Engineering

Now considering equilibrium of joint B,C and D one could calculate tension in different segments of the cable.  

Segment bc 

Applying equations of equilibrium,

∑Fx = 0 ⇒ Tab cos θab = Tbc cosθbc   

Examples of cables | Additional Study Material for Mechanical Engineering

See Fig.31.4c 

Segment cd 

Examples of cables | Additional Study Material for Mechanical Engineering

See Fig.31.4d. 

See Fig.31.4e. 

Segment de

Examples of cables | Additional Study Material for Mechanical Engineering

The tension Tde may also be obtained as 

Examples of cables | Additional Study Material for Mechanical Engineering

Example 31.2 

A cable of uniform cross section is used to span a distance of 40m as shown in Fig 31.5. The cable is subjected to uniformly distributed load of 10 kN/m. run. The left support is below the right support by 2 m and the lowest point on the cable  is located below left support by 1 m. Evaluate the reactions and the maximum and minimum values of tension in the cable. 

Examples of cables | Additional Study Material for Mechanical Engineering

Examples of cables | Additional Study Material for Mechanical Engineering

Examples of cables | Additional Study Material for Mechanical Engineering

Fig. 31.6 Example 31.3

Assume the lowest point C to be at distance of x m from B . Let us place our origin of the co-ordinate system xy at C . Using equation 31.5, one could write, 

Examples of cables | Additional Study Material for Mechanical Engineering   (1)    (2) 

where ya and yb be the y co-ordinates of supports A and B respectively. From equations 1 and 2, one could evaluate the value of x . Thus,

10(4x - x2) = 10x2/3 ⇒ x =25.359 m

From equation 2, the horizontal reaction can be determined. 

Examples of cables | Additional Study Material for Mechanical Engineering

Now taking moment about A of all the forces acting on the cable, yields 

Examples of cables | Additional Study Material for Mechanical Engineering

Writing equation of moment equilibrium at point B , yields

Examples of cables | Additional Study Material for Mechanical Engineering

Tension in the cable at supports A and B are 

Examples of cables | Additional Study Material for Mechanical Engineering

The tension in the cable is maximum where the slope is maximum as T cosθ = H . The maximum cable tension occurs at B and the minimum cable tension occurs at C where dy/dx = θ = 0 and Tc = H = 1071.81 kN

Example 31.3 

A cable of uniform cross section is used to support the loading shown in Fig 31.6. Determine the reactions at two supports and the unknown sag yC.

Taking moment of all the forces about support B ,

Ray =1/10 [350 + 300 +100yc]             (1) 

Ray = 65 +10 yc

Taking moment about B of all the forces left of B and settingMB=0 , we get, 

Ray*3-Ha*2 =0

⇒ Ha= 1.5Ray            (2)

Taking moment about C of all the forces left of C and setting = 0 , we get 

∑Mc = 0   Ray * 7-Ha * yc -50*4 =0

Substituting the value of in terms of in the above equation, 

7Ray-1.5Ray yc -200 =0       (3)

Using equation (1), the above equation may be written as, 

yc2+1.833yc -17 =0       (4) 

Solving the above quadratic equation, can be evaluated. Hence,

yC = 3.307m.

Substituting the value of  in equation (1),  

Ray = 98.07 kN

From equation (2),  

Ha =1.5Ray = 147.05 kN

Now the vertical reaction atD,Rdy calculated by taking moment of all the forces about A,

Rdy * 10 − 100 * 7 + 100 * 3.307 − 50 * 3 = 0

Rdy =51.93  kN.

Taking moment of all the forces right of C about C , and noting that ∑Mc =0,

Rdy 3 = Hd* yc⇒Hd=47.109  kN.

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FAQs on Examples of cables - Additional Study Material for Mechanical Engineering

1. What are the different types of cables used in mechanical engineering?
Ans. Mechanical engineers use various types of cables in their designs, including wire rope cables, electrical cables, control cables, and fiber optic cables. Each type has its own specific applications and characteristics.
2. How do wire rope cables work and what are their advantages?
Ans. Wire rope cables are made up of multiple strands of metal wires twisted together to form a strong and flexible structure. They are commonly used for lifting heavy loads or for transmitting mechanical power. The advantage of wire rope cables is their high tensile strength and ability to withstand heavy loads without elongation or deformation.
3. What are the main considerations when selecting cables for mechanical systems?
Ans. When selecting cables for mechanical systems, engineers need to consider factors such as the required load capacity, flexibility, durability, and resistance to environmental conditions. They also need to ensure compatibility with the system's components and consider factors like cost and maintenance requirements.
4. How are control cables used in mechanical engineering applications?
Ans. Control cables are used in mechanical engineering applications to transmit mechanical forces or motion from one component to another. They are commonly used in systems such as brakes, clutches, and throttle controls. Control cables are designed to provide precise and reliable operation, allowing for the control of various mechanical functions.
5. What are the common failure modes of cables in mechanical systems?
Ans. Common failure modes of cables in mechanical systems include fatigue failure, corrosion, abrasion, and overloading. Fatigue failure occurs due to repeated stress cycles, while corrosion can weaken the cable material over time. Abrasion can occur due to friction or contact with sharp edges, while overloading can cause the cable to exceed its load capacity and fail. Regular inspection and maintenance are essential to prevent cable failures in mechanical systems.
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