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Page 1 Short Notes on Machine Design Static Load ? A static load is a mechanical force applied slowly to an assembly or object.Load does not change in magnitude and direction and normally increases gradually to a steady value ? This force is often applied to engineering structures on which peoples' safety depends on because engineers need to know the maximum force a structure can support before it will collapse. Dynamic load ? A dynamic load, results when loading conditions change with time. Load may change in magnitude for example, traffic of varying weight passing a bridge. ? Load may change in direction, for example, load on piston rod of a double acting cylinder. Vibration and shock are types of dynamic loading. Factor of safety (F.O.S): ? The ratio of ultimate to allowable load or stress is known as factor of safety i.e. The factor of safety can be defined as the ratio of the material strength or failure stress to the allowable or working stress. ? The factor of safety must be always greater than unity. It is easier to refer to the ratio of stresses since this applies to material properties. F.O.S = failure stress / working or allowable stress Static Failure Theories Maximum Principal Stress Theory (Rankine Theory): ? The principal stresses s1 (maximum principal stress), s2 (minimum principal stress) or s3 exceeds the yield stress, yielding would occur. ? For two dimensional loading situation for a ductile material where tensile and compressive yield stress are nearly of same magnitude: Page 2 Short Notes on Machine Design Static Load ? A static load is a mechanical force applied slowly to an assembly or object.Load does not change in magnitude and direction and normally increases gradually to a steady value ? This force is often applied to engineering structures on which peoples' safety depends on because engineers need to know the maximum force a structure can support before it will collapse. Dynamic load ? A dynamic load, results when loading conditions change with time. Load may change in magnitude for example, traffic of varying weight passing a bridge. ? Load may change in direction, for example, load on piston rod of a double acting cylinder. Vibration and shock are types of dynamic loading. Factor of safety (F.O.S): ? The ratio of ultimate to allowable load or stress is known as factor of safety i.e. The factor of safety can be defined as the ratio of the material strength or failure stress to the allowable or working stress. ? The factor of safety must be always greater than unity. It is easier to refer to the ratio of stresses since this applies to material properties. F.O.S = failure stress / working or allowable stress Static Failure Theories Maximum Principal Stress Theory (Rankine Theory): ? The principal stresses s1 (maximum principal stress), s2 (minimum principal stress) or s3 exceeds the yield stress, yielding would occur. ? For two dimensional loading situation for a ductile material where tensile and compressive yield stress are nearly of same magnitude: ? Yielding occurs when the state of stress is at the boundary of the rectangle. Maximum Principal Strain Theory (St. Venant’s theory): ? If e1 and e2 are maximum and minimum principal strains corresponding to s1 and s2, in the limiting case: ? Boundary of a yield surface in Maximum Strain Energy Theory is given below Page 3 Short Notes on Machine Design Static Load ? A static load is a mechanical force applied slowly to an assembly or object.Load does not change in magnitude and direction and normally increases gradually to a steady value ? This force is often applied to engineering structures on which peoples' safety depends on because engineers need to know the maximum force a structure can support before it will collapse. Dynamic load ? A dynamic load, results when loading conditions change with time. Load may change in magnitude for example, traffic of varying weight passing a bridge. ? Load may change in direction, for example, load on piston rod of a double acting cylinder. Vibration and shock are types of dynamic loading. Factor of safety (F.O.S): ? The ratio of ultimate to allowable load or stress is known as factor of safety i.e. The factor of safety can be defined as the ratio of the material strength or failure stress to the allowable or working stress. ? The factor of safety must be always greater than unity. It is easier to refer to the ratio of stresses since this applies to material properties. F.O.S = failure stress / working or allowable stress Static Failure Theories Maximum Principal Stress Theory (Rankine Theory): ? The principal stresses s1 (maximum principal stress), s2 (minimum principal stress) or s3 exceeds the yield stress, yielding would occur. ? For two dimensional loading situation for a ductile material where tensile and compressive yield stress are nearly of same magnitude: ? Yielding occurs when the state of stress is at the boundary of the rectangle. Maximum Principal Strain Theory (St. Venant’s theory): ? If e1 and e2 are maximum and minimum principal strains corresponding to s1 and s2, in the limiting case: ? Boundary of a yield surface in Maximum Strain Energy Theory is given below Maximum Shear Stress Theory (Tresca Theory): ? At the tensile yield point s2= s3 = 0 and thus maximum shear stress is sy/2. ? Yield surface corresponding to maximum shear stress theory in biaxial stress situation is given below : Maximum strain energy theory ( Beltrami’s theory): ? Failure would occur when the total strain energy absorbed at a point per unit volume exceeds the strain energy absorbed per unit volume at the tensile yield point. Page 4 Short Notes on Machine Design Static Load ? A static load is a mechanical force applied slowly to an assembly or object.Load does not change in magnitude and direction and normally increases gradually to a steady value ? This force is often applied to engineering structures on which peoples' safety depends on because engineers need to know the maximum force a structure can support before it will collapse. Dynamic load ? A dynamic load, results when loading conditions change with time. Load may change in magnitude for example, traffic of varying weight passing a bridge. ? Load may change in direction, for example, load on piston rod of a double acting cylinder. Vibration and shock are types of dynamic loading. Factor of safety (F.O.S): ? The ratio of ultimate to allowable load or stress is known as factor of safety i.e. The factor of safety can be defined as the ratio of the material strength or failure stress to the allowable or working stress. ? The factor of safety must be always greater than unity. It is easier to refer to the ratio of stresses since this applies to material properties. F.O.S = failure stress / working or allowable stress Static Failure Theories Maximum Principal Stress Theory (Rankine Theory): ? The principal stresses s1 (maximum principal stress), s2 (minimum principal stress) or s3 exceeds the yield stress, yielding would occur. ? For two dimensional loading situation for a ductile material where tensile and compressive yield stress are nearly of same magnitude: ? Yielding occurs when the state of stress is at the boundary of the rectangle. Maximum Principal Strain Theory (St. Venant’s theory): ? If e1 and e2 are maximum and minimum principal strains corresponding to s1 and s2, in the limiting case: ? Boundary of a yield surface in Maximum Strain Energy Theory is given below Maximum Shear Stress Theory (Tresca Theory): ? At the tensile yield point s2= s3 = 0 and thus maximum shear stress is sy/2. ? Yield surface corresponding to maximum shear stress theory in biaxial stress situation is given below : Maximum strain energy theory ( Beltrami’s theory): ? Failure would occur when the total strain energy absorbed at a point per unit volume exceeds the strain energy absorbed per unit volume at the tensile yield point. ? Above equation results in Elliptical yield surface which can be viewed as: Distortion energy theory (Von Mises yield criterion): ? Yielding would occur when total distortion energy absorbed per unit volume due to applied loads exceeds the distortion energy absorbed per unit volume at the tensile yield point. Total strain energy E T and strain energy for volume change E V can be given as: At the tensile yield point, s1 = sy , s2 = s3 = 0 which gives, The failure criterion is thus obtained by equating Ed and Edy , which gives In a 2-D situation if s3 = 0, so the equation reduces to, Page 5 Short Notes on Machine Design Static Load ? A static load is a mechanical force applied slowly to an assembly or object.Load does not change in magnitude and direction and normally increases gradually to a steady value ? This force is often applied to engineering structures on which peoples' safety depends on because engineers need to know the maximum force a structure can support before it will collapse. Dynamic load ? A dynamic load, results when loading conditions change with time. Load may change in magnitude for example, traffic of varying weight passing a bridge. ? Load may change in direction, for example, load on piston rod of a double acting cylinder. Vibration and shock are types of dynamic loading. Factor of safety (F.O.S): ? The ratio of ultimate to allowable load or stress is known as factor of safety i.e. The factor of safety can be defined as the ratio of the material strength or failure stress to the allowable or working stress. ? The factor of safety must be always greater than unity. It is easier to refer to the ratio of stresses since this applies to material properties. F.O.S = failure stress / working or allowable stress Static Failure Theories Maximum Principal Stress Theory (Rankine Theory): ? The principal stresses s1 (maximum principal stress), s2 (minimum principal stress) or s3 exceeds the yield stress, yielding would occur. ? For two dimensional loading situation for a ductile material where tensile and compressive yield stress are nearly of same magnitude: ? Yielding occurs when the state of stress is at the boundary of the rectangle. Maximum Principal Strain Theory (St. Venant’s theory): ? If e1 and e2 are maximum and minimum principal strains corresponding to s1 and s2, in the limiting case: ? Boundary of a yield surface in Maximum Strain Energy Theory is given below Maximum Shear Stress Theory (Tresca Theory): ? At the tensile yield point s2= s3 = 0 and thus maximum shear stress is sy/2. ? Yield surface corresponding to maximum shear stress theory in biaxial stress situation is given below : Maximum strain energy theory ( Beltrami’s theory): ? Failure would occur when the total strain energy absorbed at a point per unit volume exceeds the strain energy absorbed per unit volume at the tensile yield point. ? Above equation results in Elliptical yield surface which can be viewed as: Distortion energy theory (Von Mises yield criterion): ? Yielding would occur when total distortion energy absorbed per unit volume due to applied loads exceeds the distortion energy absorbed per unit volume at the tensile yield point. Total strain energy E T and strain energy for volume change E V can be given as: At the tensile yield point, s1 = sy , s2 = s3 = 0 which gives, The failure criterion is thus obtained by equating Ed and Edy , which gives In a 2-D situation if s3 = 0, so the equation reduces to, ? This is an equation of ellipse and yield equation is an ellipse. ? This theory is widely accepted for ductile materials Cotter and Knuckle Joints A cotter joint is a temporary fastening and is used to connect rigidly two co-axial road or bars which are subjected to axial tensile or compressive forces. Socket and Spigot Cotter Joints In a socket and spigot cotter joint, one end of the rods is provided with a socket type of end as shown in figure and the other end of the rod is inserted into a socket. The end of the rod which goes into a socket is also called spigot. Failures in Socket and Spigot Cotter JointsRead More
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FAQs on Machine Design Formulas for GATE ME Exam - Design of Machine Elements - Mechanical Engineering
| 1. What are some important machine design formulas that are commonly asked in the GATE ME exam in Mechanical Engineering? |  |
Ans. Some important machine design formulas that are commonly asked in the GATE ME exam include formulas for stress and strain, such as:
- Stress formula: Stress = Force / Area
- Strain formula: Strain = Change in length / Original length
- Shear stress formula: Shear stress = Force / Area
- Bending stress formula: Bending stress = (M * y) / I, where M is the bending moment, y is the distance from the neutral axis, and I is the moment of inertia.
- Torsional stress formula: Torsional stress = (T * r) / J, where T is the torque, r is the radial distance from the center, and J is the polar moment of inertia.
| 2. How can I apply machine design formulas in problem-solving during the GATE ME exam? | |
Ans. To apply machine design formulas in problem-solving during the GATE ME exam, you need to understand the given problem and identify the relevant formula(s) needed to solve it. Follow these steps:
1. Read the problem carefully and identify the variables given and the variables you need to find.
2. Identify the applicable machine design formula(s) for the given problem.
3. Substitute the known values into the formula(s) and solve for the unknown variable(s).
4. Check your solution and ensure it is reasonable and matches the units required.
5. Present your answer clearly, showing the steps you followed and the final result.
Practice solving various problems using machine design formulas to improve your problem-solving skills for the GATE ME exam.
| 3. Can you provide an example of how to use machine design formulas to solve a problem in the GATE ME exam? | |
Ans. Sure! Here's an example:
Problem: A beam is subjected to a bending moment of 500 Nm. The beam has a rectangular cross-section with a width of 50 mm and a height of 100 mm. Calculate the bending stress on the beam.
Solution:
Given:
Bending moment (M) = 500 Nm
Width (b) = 50 mm
Height (h) = 100 mm
First, we need to calculate the moment of inertia (I) of the beam using the formula:
I = (b * h^3) / 12
Substituting the given values:
I = (50 * (100^3)) / 12 = 41,666,667 mm^4
Next, we can calculate the bending stress (σ) using the formula:
Bending stress = (M * y) / I
Since the beam is symmetric, the distance from the neutral axis (y) is half of the height, i.e., y = h/2.
Substituting the values:
Bending stress = (500 * (100/2)) / 41,666,667 = 0.6 MPa
Therefore, the bending stress on the beam is 0.6 MPa.
| 4. What are some common mistakes to avoid when applying machine design formulas in the GATE ME exam? | |
Ans. Some common mistakes to avoid when applying machine design formulas in the GATE ME exam include:
1. Failing to understand the given problem: It is crucial to carefully read and understand the problem statement before attempting to apply any formula. Misinterpreting the problem can lead to incorrect solutions.
2. Using the wrong formula: Make sure to select the correct machine design formula(s) that apply to the given problem. Using the wrong formula will lead to inaccurate results.
3. Incorrect unit conversions: Pay attention to the units given in the problem and ensure that all units are consistent throughout your calculations. Incorrect unit conversions can result in incorrect answers.
4. Calculation errors: Be cautious when performing calculations and double-check your work. Small calculation errors can significantly affect the final result.
5. Neglecting to include units in the final answer: Always include the appropriate units in your final answer. Neglecting to include units can result in point deductions in the exam.
By being aware of these common mistakes, you can minimize errors and improve your chances of obtaining correct solutions in the GATE ME exam.
| 5. Are there any recommended resources or textbooks for studying machine design formulas for the GATE ME exam? | |
Ans. Yes, there are several recommended resources and textbooks for studying machine design formulas for the GATE ME exam. Some popular ones include:
1. "Machine Design" by R.S. Khurmi and J.K. Gupta
2. "Design of Machine Elements" by V.B. Bhandari
3. "A Textbook of Machine Design" by R.K. Bansal
4. "Machine Design Data Book" by V. B. Bhandari
5. "Mechanical Engineering Design" by Joseph Edward Shigley and Charles R. Mischke
These textbooks cover various topics related to machine design and provide a comprehensive understanding of the subject. Additionally, solving previous year GATE ME exam papers and practicing with online mock tests can also help in mastering machine design formulas.
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