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< Back Indic Institute of Design and Research ​ Indic Institute of Design and Research Introduction: Welcome to the Indic Institute of Design and Research, a premier institution dedicated to providing quality education in the field of design and research. Our institute aims to nurture creative minds and equip them with the skills and knowledge required to excel in the dynamic world of design. Approval & Affiliation: Indic Institute of Design and Research is proud to be affiliated with the prestigious Biju Patnaik University of Technology (BPUT). This affiliation ensures that our programs are in line with the latest industry standards and that our students receive a comprehensive education that prepares them for successful careers in the field of design. About the College: At Indic Institute of Design and Research, we offer a wide range of programs in various design disciplines such as graphic design, product design, fashion design, interior design, and more. Our experienced faculty members are industry professionals and experts in their respective fields, providing students with valuable insights and guidance throughout their academic journey. We believe in a holistic approach to education, combining theoretical knowledge with practical skills. Our state-of-the-art facilities and well-equipped design studios provide students with the necessary resources to bring their creative ideas to life. With a focus on hands-on learning and industry exposure, we strive to develop well-rounded professionals who are ready to make a meaningful impact in the design industry. Contact Information: If you have any inquiries or would like to learn more about the Indic Institute of Design and Research, please feel free to reach out to us at the following contact details: Address: Indic Heights, Muktapur, Khordha, Orissa 752055, India Phone: 9238333226, 9238423515 Affiliated with: Biju Patnaik University of Technology - BPUT Approved By: All India Council for Technical Education (AICTE) We look forward to welcoming you to the Indic Institute of Design and Research and helping you embark on an exciting journey towards a successful career in the field of design. Previous Next

Colleges Filter by Category Select Category arrow&v ​ ​ Read More A One College of Education Education Read More A.K. College of Education Education Read More A.M. College Education Read More A.M. Teachers Training Institute - AMTTI Education Read More A.R. Memorial Teachers' Training College Education Read More AAR Mahaveer Engineering College Engineering Read More AASEE College of Education Education Read More ABMSP's Anantrao Pawar College of Engineering and Research Engineering Read More ABR College of Education Education Read More ABR College of Engineering and Technology Engineering, Management, Agriculture Science Read More ABS Institute of Education and Management Arts, Management, Science, Commerce Read More Load More

< Back Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering ​ Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering Introduction: Welcome to Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering. We are a reputed educational institution located in Amravati, Maharashtra, India. Our college is committed to providing quality education and fostering a holistic learning environment for our students. Approval & Affiliation: Our college is affiliated with Sant Gadge Baba Amravati University, a renowned university in Maharashtra. This affiliation ensures that our students receive a recognized and valuable degree upon completion of their studies. Additionally, our college is approved by the All India Council for Technical Education (AICTE) and the Directorate of Technical Education (DTE), further validating the quality of our educational programs. About the College: At Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering, we offer a wide range of engineering courses to cater to the diverse interests and aspirations of our students. Our faculty members are highly qualified and experienced, dedicated to imparting knowledge and nurturing the talents of our students. We provide state-of-the-art facilities and resources to support experiential learning and practical application of theoretical concepts. Our college focuses not only on academic excellence but also on the overall development of our students. We encourage participation in extracurricular activities, sports, and various clubs and societies to enable students to explore their passions and develop their personality. Contact Information: If you have any queries or would like to know more about our college, here is our contact information: Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering University' Mardi Road, Ghatkhed Amravati, Maharashtra 444602 India Phone: (0721) 2711625, 2711617 / 9403024575 We are happy to assist you and provide any further information you may need. In conclusion, Indira Bahuuddeshiya Shikshan Santa, Buldhana's College of Engineering is a prestigious institution dedicated to providing quality engineering education. With our affiliation with Sant Gadge Baba Amravati University and approval from AICTE and DTE, we ensure that our students receive an excellent education that prepares them for a successful career in the field of engineering. Previous Next

Basic assumptions of stress and strain Stress and strain are fundamental concepts in the field of mechanics and materials science. These concepts help us understand the behavior of objects under external forces. To simplify the analysis, certain assumptions are made when studying stress and strain. These assumptions provide a basis for theoretical calculations and practical applications. In this document, we will discuss the basic assumptions of stress and strain. 1. Linear Elasticity: The first assumption is that the material being analyzed exhibits linear elasticity. This means that the relationship between stress and strain is linear within the elastic limit. In other words, the material will deform proportionally to the applied stress and will return to its original shape once the stress is removed. This assumption is valid for many engineering materials under normal operating conditions. 2. Homogeneity: The second assumption is that the material is homogeneous. Homogeneity refers to the uniform distribution of material properties throughout the object. In other words, the material's properties, such as density, elasticity, and strength, are the same at every point within the object. This assumption allows for simplification of calculations and analysis. 3. Isotropy: The third assumption is that the material is isotropic. Isotropy means that the material's properties are the same in all directions. In practical terms, this assumption implies that the material's response to stress and strain is independent of the direction in which the forces are applied. This simplifies the analysis by reducing the number of variables that need to be considered. 4. Small Deformations: The fourth assumption is that the deformations experienced by the material are small. This assumption is valid as long as the applied stress is within the elastic limit of the material. Small deformations allow for linear relationships between stress and strain, making the analysis more straightforward. However, for larger deformations, nonlinear elasticity and other models must be used. 5. No Temperature Effects: The fifth assumption is that temperature does not significantly affect the material's behavior. This assumption is valid for many engineering materials under normal operating conditions. However, in extreme temperature conditions or when dealing with materials with temperature-dependent properties, this assumption may not hold true. 6. No Time Dependency: The final assumption is that the material's behavior is instantaneous and does not depend on time. This assumption simplifies the analysis by neglecting any time-dependent effects, such as creep or relaxation. In most engineering applications, the time scales involved are relatively short, making this assumption reasonable. It is important to note that these assumptions are simplifications made to facilitate the analysis of stress and strain. While they may not always hold true in real-world scenarios, they provide a useful framework for understanding and predicting the behavior of materials under external forces.

Concept of Load Load is a fundamental concept in engineering and physics that refers to the force applied to a structure or system. It is a measure of the external forces that act upon an object, causing it to deform, move, or experience stress. Understanding the concept of load is crucial in various fields, including civil engineering, mechanical engineering, and structural analysis. Definition of Load In engineering, load can be defined as the external forces acting on a structure or system. These forces can be static or dynamic and may result in deformation, displacement, or stress on the object or structure. Loads can be applied in different ways, such as through direct contact, gravitational force, or external forces like wind, water, or seismic activity. Types of Load 1. Dead and Live Load: Dead Load refers to the weight of the structure itself and any permanent attachments or components. It includes the weight of materials like concrete, steel, and wood, as well as the fixed equipment or furnishings. Dead load remains constant over time and is essential for determining the overall structural stability. Live Load, on the other hand, refers to the variable or moving loads that a structure experiences during its lifetime. This includes the weight of people, furniture, vehicles, or any other temporary or transient loads. Live loads are significant in determining the structural design and capacity, as they can change in magnitude and location. 2. Axial and Transverse Load: Axial Load refers to the force that acts along the longitudinal axis of a structural member, causing compression or tension. It is applied in a straight line and passes through the center of the cross-section. Axial loads are commonly seen in columns, pillars, or vertical members that support the weight of a structure. Transverse Load refers to the force that acts perpendicular to the longitudinal axis of a structural member. It can cause bending or shear stress in the material. Transverse loads are applied horizontally or at an angle and can be seen in beams, slabs, or any other structural element that experiences bending or twisting. 3. Tensile, Compressive, and Shear Load: Tensile Load refers to the force that tends to pull apart or stretch a material. It induces tension stress, causing the material to elongate. Tensile loads are common in structures like cables, ropes, or supports that need to withstand pulling forces. Compressive Load refers to the force that tends to compress or squeeze a material. It induces compressive stress, causing the material to shorten or compact. Compressive loads are seen in columns, pillars, or any other element that needs to resist crushing or squeezing forces. Shear Load refers to the force that causes one part of a material to slide or deform parallel to another part. It induces shear stress, causing the material to experience shear deformation. Shear loads are significant in beams, joints, or connections where forces are applied parallel to the surface. 4. Impact Load: Impact Load refers to the sudden or impulsive forces acting on a structure due to a collision or abrupt change in motion. It can cause high-stress concentrations and result in dynamic loading, leading to structural failure. Impact loads are crucial in designing structures to withstand events like earthquakes, explosions, or vehicular collisions. Understanding the concept of load and its various types is essential for engineers and designers to ensure the safety, stability, and functionality of structures and systems. By analyzing and considering different load conditions, appropriate materials, dimensions, and structural elements can be selected to meet the required design standards and specifications.