Question Set 2
The assumptions made in the theory of simple bending are:
> The material of the beam is homogeneous this implies that it is uniform in density, strength and have isotropic properties meaning possessing same elastic property in all directions.
> Even after bending the cross section of the beam remains constant.
> During the initial stages the beam is straight and unstressed.
> All the stresses in the beam are within the elastic limit of its material.
> The layers of the beam are free to contract and expand longitudinally and laterally
> On any cross section the perpendicular resultant force of the beam is zero.
> Compared to the cross-sectional dimension of the beam the radius of curvature is very large.
The following types of stresses are prevalent in shafts:
> At the outermost surface of the shaft the max shear stress occurs on the cross-section of the shaft.
> At the surface of the shaft on the longitudinal planes through the axis of the shaft the maximum longitudinal shear stress occurs.
> At 45 degrees to the maximum shearing stress planes at the surface of the shafts the major principal stress occurs. It equals the max shear stress on the cross section of the shaft.
> For certain materials where the tensile and compressive strengths are lower in measure as compared to the shear strength, then the shaft designing should be carried out for the lowest strengths.
> All these stresses are of significance as they play a role in governing the failure of the shaft. All theses stresses get generated simultaneously and hence should be considered for designing purposes
The Hooke`s coupling is used to connect two shafts whose axes intersect at a small angle. The two shafts are inclined at an angle and is constant. During motion it varies as the movement is transferred from one shaft to another. One of the major areas of application of this coupling is in gear boxes where the coupling is used to drive the rear wheels of trucks and other vehicles. In such usage scenarios two couplings are used each at the two ends of the coupling shaft. they are also used to transfer power for multiple drilling machines. The Hooke`s coupling is also known as the Universal coupling. The torque transmitted by the shafts is given by :
T= (pie/16) x t x (d) cube
Where T = torque, t = shear stress for the shaft material and d the diameter of the shaft.
Some of the qualities that should be present in materials for shafts are as follows:
> The material should have a high index of strength.
> Also it should have a high level of machinability.
> The material should possess a low notch sensitivity factor.
> The material must also have wear resistant properties.
> Good heat treatment properties should also be present
The common material used to creates shafts of high strengths an alloy of steel like nickel is used. The shafts are manufactured by hot rolling processes and then the shaft is finished using drawing or grinding processes.
The advantages of using a chain drives are:
> In a chain drive no slip occurrence takes place.
> The chains take less space as compared to rope or belts as they are made of metal and offer much strength.
> The chain drives can be used at both short and long ranges and they offer a high level of transmission efficiency.
> Chain drives can transmit more load and power as compared to belts.
> A very high speed ratio can be maintained in one step of chain drives.
Some of the cons of using a chain drive are:
> The cost of producing chain drives is higher as compared to that of belts.
> The chain drives must be serviced and maintained at regular intervals and henceforth their cost of ownership is high comparatively.
Springs can be broadly classified into the following types:
> Helical Springs: These springs as their name suggests are in coil form and are in the shape of helix. The primary purpose of such springs are to handle compressive and tensile loads. They can be further classified into two types: compression helical spring and tension helical spring each having their own unique areas of application./
> Conical and volute springs: Both these spring types have specialized areas of usage where springs with adaptable rate according to the load is required. In case of conical springs they are wound so as to have a uniform pitch while on the other hand volute springs are wound in a slight manner of a parabloid.
> Torsion Springs: The characteristics of such springs is that they tend to wind up by the load. They can be either helical or spiral in shape. These types of springs are used in circuit breaker mechanisms.
> Leaf springs: These types of springs are comprised of metal plates of different lengths held together with the help of bolts and clamps. Commonly seen being used as suspensions for vehicles.
> Disc Springs: As the name suggests such types of springs are comprised of conical discs held together by a bolt or tube.
> Special Purpose Springs: These springs are all together made of different materials such as air and water