Calculating the internal forces and drawing the free body diagram, concept of stress and strain; Mechanical properties of materials, stress-strain relationships and Hooke's law; Axial load; Shear force and bending moment diagrams; Normal stresses in symmetrical and non-symmetrical cross-sections due to normal forces and bending moments; Shear stresses in symmetrical solid and hollow profiles; Torsional shear stresses in circular and non-circular sections; Combined stresses and principal stresses; Transformation of stress and tension and Mohr's circle. Apply knowledge of math, science and engineering to calculate the physical properties of earth materials. Determine stresses and mechanical properties of rocks and their dimensions by applying the principles of rock mechanics.

Recognize the social, environmental issues associated with mechanical properties of rocks and geological maps. CLO2: Analyze the results of the experiments conducted to measure the mechanical properties of engineering materials under the influence of tensile testing and use engineering judgment to draw conclusions for these results. CLO3: Analyze the results of the experiments carried out to measure the mechanical properties of engineering materials under the influence of compression testing and bending testing.

CLO3: Analyze the results of experiments conducted to measure the physical properties of fresh and hardened concrete and use engineering judgment to draw conclusions from these results.

Formulate the fundamental principles of mathematics, and sciences related to fluid mechanics

Solve hydrostatic pressure problems by applying the fundamentals of fluid mechanics

The course will provide the student with the basics and knowledge needed to analyze different types of statically determined structural systems that are exposed to different types of loads. This includes analysis of specific beams, girders, flat frames and arches; reaction calculation; normal force, shear force, bending moment and strain diagrams. Analyze composite and complex beams using principles of engineering statics to calculate and thereby draw various types of internal force diagrams.

Solve various types of statically determinate structures using principles of engineering statics to determine and thus draw the internal force diagrams necessary to check the strength requirements for subsequent design courses. Assess different types of deformations for statically determinate structures, which are necessary to check serviceability requirements for subsequent design courses, applying principles of mathematics and materials.

Analyze experimental results (moisture content test, sieve analysis test, Atterberg limits test) in order to identify and classify soils

Analyze results of experiments (Proctor test, Sand Cone Test, Permeameter test) in order to examine factors affecting soil compaction and interpret

Determine stresses in a soil mass taking into account the characteristics of soil

This course includes basic concepts of fluid flow as types, classifications, conditions and characteristics in closed conduits and in open channels, Dimensional analysis and correspondences, Steady flow in closed conduits, Open channel hydraulics, Pumps and turbines, and Laboratory measurements and data analysis . Apply knowledge of mathematics and basic sciences as well as fundamentals of hydraulics to solve hydraulic problems related to different types, conditions of flow and computer dimensions of best hydraulic section in closed and open conduits. Apply knowledge of mathematics and basic sciences as well as fundamentals of hydraulics to solve hydraulic problems related to energy and momentum principles, crew shear stress, dimensional analysis, open channel networks and pumps.

Contact hours Introduction: course description, discussion of flow mechanics 1 5 Basic concepts in flow: Flow in closed pipes; open channel flow;. Calculate the trip distribution between different zones based on the collected data for transport planning by applying the principles of urban transport planning. Determine the appropriate travel path through the road network based on the collected data by applying the principles of traffic allocation.

Interpret effectively in oral presentations and in written form by preparing a report related to modern topics in transportation systems. Websites https://lms.ju.edu.sa/webapps/portal/execute/tabs/tabAction?tab_tab_group_id=_178_1. Introduction to properties of concrete and reinforcing steel; Limit state design of reinforced concrete structures, building codes and ethical and professional responsibilities in engineering solutions; Loads and load combinations acting on reinforced concrete structures; Analysis and design of beams against bending: rectangular beams, T-beams and double-reinforced beams; Design of beams against shear and torsional forces, joint and development length including joints and cut points; reinforcement details of beams; Analysis, design and reinforcement details of solid slabs in one direction and in two directions; Analysis and design of columns subjected.

CLO1: Evaluate the load behavior of reinforced concrete beams and its material properties using various design methods that meet the strength and serviceability limit state. CLO2: Analysis and design of single reinforced concrete beams (rectangular) subjected to transverse loads. CLO3: Analysis and design of reinforced concrete beam in bending state of T-beams as well as doubly reinforced and shear beams for rectangular beams.

CLO4: Evaluate appropriate code/standard for application to the practical analysis and design of short concrete columns and calculate tensile strength and compression bar development lengths. Building code requirements and ethical as well as professional responsibilities within technical solutions; Loads and load combinations acting on reinforced concrete structures.

Evaluate and Interpret data giving by laboratory tests (odometer test) in order to determine soil consolidation characteristics and settlement

Analyze results of experiments (direct shear test, shear tri-axial test) in order to study the shear strength of soil

Examine the stability of earth retaining structures, subject to the lateral earth pressure, and stability of slopes taking into account the characteristics of soil

Interpret effectively in oral presentations as well as in written form by preparing

Evaluate and interpret data provided by laboratory tests (mileage tests) to determine soil consolidation characteristics and settlement. This course includes an overview of the construction industry, earthmoving machinery and operation, digging and lifting, loading and hauling, compaction & finishing, concrete construction, concrete form design, construction economics and contract construction. Apply principles for plant engineering concepts for quantity start-up and different types of contracts.

This course covers highway planning and capacity, design control and criteria, cross-sectional elements, sight distances, horizontal and vertical alignments, intersections, highway material characterization, design of bituminous mixtures, flexible pavement design, highway drainage, pavement evaluation and maintenance , traffic system components, traffic flow characteristics, traffic studies, parking, pedestrians, traffic safety, traffic lights, signs and markings, capacity of urban streets and intersections, and congestion management. Identify, formulate and solve complex problems for the horizontal and vertical alignments of highways by applying the principles of road planning and maintenance. Identify, formulate and solve complex traffic light cycle time calculation problems by applying traffic principles.

Determine asphalt mix volume and engineering properties of road materials (binder and aggregate) applying principles of engineering criteria. Characteristics of raw water, collection works in the water treatment plant, purification works in the water treatment plant (sedimentation, filtration and disinfection), characteristics of waste water, treatment of waste water, primary treatment of waste water and secondary cleaning during wastewater treatment.

Explain the characteristics and environmental issues associated with water and wastewater treatment

Describe fundamentals and basic concepts for design of water and wastewater treatment

Design water and wastewater treatment facilities

Demonstrate the concepts of performing experiments to evaluate the properties of water and waste water

Piling Works (Pit Function and Design, LLP) 1 2 Coagulation process, flash mixing, design i. Sedimentation process and design (Clarifiers) 2 4 Process involved in filtration and filter design (Cleaning . works at WTP) 1 2. Electronic materials (eg websites, social media, blackboard, etc.) Websites https://www.amazon .com/Foundation-Analysis-Design-.

This course covers foundation types, shallow foundation bearing capacity, shallow foundation design, deep foundation types, single pile and pile group bearing capacity, pile foundation design, types, stability and design of retaining walls, and analysis of sheet pile stability. Design different types of shallow foundations (insulated, wall, strip, belt and raft foundation) to complete design and typical drawings. Brief description of the content of the course (Catalogue description) The graduation project I (CE496) consists of choosing the subject of the project, setting up the project, reviewing the literature, preparing or conducting the preliminary experiments if the project includes an experimental part, collecting the field data and developing the mathematical/computer model, if necessary, and writing the first two chapters with the preliminary results.

CLO2: Outline the project and include the project objectives, an indicative summary of the methodology and possible outcomes. Websites https://lms.ju.edu.sa/webapps/portal/execute/tabs/tabAction?tab_tab_g roup_id=_178_1. Introduction to the knowledge, principles, tools and techniques of project management in engineering projects; management and decision-making processes; planning, scheduling and time management; PERT and the critical path method; cost and earned value analysis; risk management, quality management, resource management, ethics and leadership; procurement and contracting, computer applications and professional licensing in Project Management.

This course introduces the fundamentals of planning hydraulic structures and water channels, including classifications, functions, design. Design a system, component or project with intersecting hydraulic structures to meet desired needs within realistic constraints such as economics, environment, safety, manufacturability and sustainability. Present and perform effectively in oral presentations as well as in written form by preparing a report related to hydraulic engineering topics.

Design of spillway: types and use, design of tail escapes 2 8 Energy dissipation downstream hydraulic structures considering. Apply and acquire a new knowledge using engineering strategies to save the environment from different types of pollution with the ability to demonstrate it.

Apply and obtain a new knowledge by using engineering strategies to save the environment from different types of pollution with the ability to demonstrate that

• Design of tension steel members and compression steel members using LRFD method to meet the specified needs which are required to satisfy the American Institute of Steel
• Design of bolted and welded truss member shear-connections using LRFD method to satisfy the strength requirements according to AISC considering economy and safety
• Design of beams using LRFD method to satisfy the strength requirements and the serviceability requirements according to AISC considering economy and safety
• Design of beam-column and column base-plate according to the AISC requirements and specifications considering economy and safety

This course covers properties of steel, types of loads, design philosophies according to AISC using ASD method vs. LRFD method, analysis and design of tension and compression members, design of bolt and weld joints, design of beams for bending and shear strength requirements, serviceability requirements for beams, buckling of beams, beams with biaxial bending moments, design of beam column, design of column base plate . Design of tensile steel parts and compression steel parts using the LRFD method to meet the specified needs required to meet the American Institute of Steel. .

Design of bolted and welded cross-connections of lattice elements using the LRFD method to meet the strength requirements according to AISC, taking into account economy and safety. Design of beams using the LRFD method to meet AISC strength and serviceability requirements, taking into account economy and safety. Design of beam column and column base plate according to AISC requirements and specifications, taking into account economy and safety.

CLO2: Demonstrate the research/project work as conducting experiments that have passed the design and implementation phases. CLO3: Perform necessary tasks required in the conduct of research/project work as an individual or team member. CLO4: Present his research/project work in a logical and well-organized manner using appropriate communication and presentation skills.

CLO5: Integrate the social and environmental impacts of the project into the proposed technical solution. CLO6: Present in the form of a project report (draft, editing, layout, error checking) of research/project work. CLO7: Complete the project by practicing management principles, including punctuality, commitment and dedication, under the guidance of a supervisor.