BSR112 Building Structure I UITM Asignment Sample Malaysia

BSR112 Building Structure I is a course that introduces students to the fundamental principles of building structures. The course typically covers topics such as statics, the strength of materials, and the analysis and design of structural elements. Students will learn about the different types of loads that can act on a building structure, including dead loads, live loads, wind loads, and seismic loads. They will also study the behavior of materials under different types of loading and learn how to calculate stresses and strains in structural members.

Other topics covered in the course may include the design of beams, columns, and foundations, as well as the use of computer software for structural analysis and design. Throughout the course, students will work on design projects and assignments to apply their knowledge to real-world scenarios.

Get assignment samples for BSR112 Building Structure I course

Malaysiaassignmenthelp.com provides online assignment samples for BSR112 Building Structure I course. Get help from experienced professionals to understand various topics such as statics, the strength of materials and analysis and design of structural elements. Our writers will also provide guidance on other aspects of the course such as the design of beams, columns, foundations etc.

Here, we will provide some assignment outlines. These are:

Assignment Outline 1: Comprehend the principles in Standard International Unit (S.I Unit) and Centre of Gravity.

The Standard International Unit (SI Unit) is the modern metric system of measurement that is used universally. It was established in 1960 and is based on the International System of Units. The SI unit consists of seven base units, which are the meter (m) for length, kilogram (kg) for mass, second (s) for time, ampere (A) for electric current, kelvin (K) for temperature, mole (mol) for the amount of substance, and candela (cd) for luminous intensity.

The SI system is based on decimal multiples or submultiples of these base units. This system makes it easy to convert from one unit to another, and it allows for accurate and consistent measurements across different fields of science, engineering, and technology.

The center of gravity is a concept in physics and engineering that refers to the point where the weight of an object is evenly distributed in all directions. The center of gravity is also known as the center of mass.

The position of the center of gravity is important in the design and stability of objects, especially in engineering and architecture. The location of the center of gravity affects how an object will behave under different conditions, such as when it is tilted, rotated, or subjected to external forces.

In general, the center of gravity of an object depends on its mass distribution. For a symmetrical object with uniform mass distribution, the center of gravity is at the geometric center. However, for an irregularly shaped object, the center of gravity may be located outside the object itself.

The principles of SI units and the center of gravity are fundamental to many fields of science and engineering. Understanding these concepts is essential for accurate and consistent measurement, and for designing stable and safe structures and objects.

Asignment Outline 2: Solve problems in structural analysis involving load transfers and load combinations.

Structural analysis is the study of the behavior of structures when subjected to external loads. The primary goal of structural analysis is to determine the internal forces, stresses, and deformations within a structure that will result from the application of external loads. In this process, load transfers and load combinations are important factors to consider. Here are some common problems in structural analysis involving load transfers and load combinations:

1. Truss analysis: Trusses are structures composed of interconnected bars or beams that are designed to carry loads primarily in tension and compression. To analyze a truss, one must determine the forces in each member due to applied loads. The load transfer in a truss occurs through the axial forces in each member. The load combinations for a truss are typically governed by the design codes and standards.
2. Beam analysis: Beams are structures that are designed to support transverse loads. In beam analysis, one must determine the bending moments, shear forces, and deflections due to applied loads. Load transfer in a beam occurs through bending moments and shear forces. The load combinations for a beam are also governed by the design codes and standards.
3. Frame analysis: Frames are structures composed of interconnected beams and columns that are designed to carry loads in all directions. To analyze a frame, one must determine the forces and deformations in each member due to applied loads. Load transfer in a frame occurs through bending moments, shear forces, and axial forces in each member. The load combinations for a frame are again governed by the design codes and standards.
4. Load combinations: In structural analysis, loads are often applied simultaneously or sequentially. Therefore, it is important to consider load combinations that may result in the worst-case scenario for a structure. The design codes and standards typically provide guidance on the load combinations to consider for different types of structures.
5. Load transfers: In some cases, loads may be transferred from one element of a structure to another. For example, a column may transfer loads to a beam, which then transfers loads to a foundation. To analyze load transfers, one must consider the equilibrium and compatibility conditions at the interface between the two elements. The design codes and standards typically provide guidance on how to analyze load transfers for different types of structures.

Assignment Outline 3: Interpret an appropriate behavior and size determination of timber structures.

Interpreting an appropriate behavior and size determination for timber structures involves understanding the mechanical properties of wood and how they are affected by various factors such as moisture content, temperature, and loading.

The behavior of timber structures can be predicted using engineering principles and techniques such as structural analysis, which involves calculating stresses and strains within the structure under various loading conditions. Timber structures can also be designed to meet specific codes and standards set by regulatory bodies.

In terms of size determination, the size of the timber members used in a structure will depend on the loads that the structure is expected to bear, as well as other factors such as the span of the structure, the spacing of the members, and the type of joint used.

It is important to note that the size of timber members used in a structure can also affect the behavior of the structure. For example, increasing the size of a timber member can increase its stiffness and strength, but may also lead to increased weight and cost.

Therefore, it is important to strike a balance between the desired behavior of the structure and the practical considerations of size and cost when designing and constructing timber structures. This can be achieved through careful analysis and design by a qualified structural engineer or architect.