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Enroll in this Master"s in Structural Analysis and Calculation and obtain a Master"s Degree in Structural Analysis and Calculation with 60 ECTS credits issued by the Universidad Católica de Murcia (UCAM), in collaboration with Structuralia.

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1500 horas - 60 ECTS
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Nuestros alumnos opinan sobre: Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

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Thaicia Stona

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

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Emma S.

BRIGHTON

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

I understand that the campus might feel a bit outdated due to its slow speed, but overall, it is still quite good.

Mason P.

NOTTINGHAM

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

I had a pleasant experience studying with Euroinnova. I gained a lot of knowledge about the subject, and it has been beneficial for my job.

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DENVER

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

I really enjoyed the practical exercises in the online course as they provided real-life examples of the subject matter. Moreover, the testing system was very convenient.

Noah R.

DALLAS

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

I am glad to hear that the course has met your expectations, and now you feel like an expert in structural calculation. Thank you, Euroinnova, for the high-quality content in your study materials.

Liam R.

LONDON

Opinión sobre Master’s Degree in Structural Analysis and Calculation + 60 ECTS Credits

Online mode has allowed me to work while studying, without having to leave my full-time job.The tutors have been the best part of the entire course.
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Plan de estudios de Master structure calculation

MASTER STRUCTURE CALCULATION. What are you waiting for? Enroll today in this comprehensive training and enjoy the benefits of e-learning. Obtain a Master´s Degree in Structural Analysis and Calculation with 60 ECTS credits issued by the University Isabel I in collaboration with Structuralia as accreditation.

 

Resumen salidas profesionales
de Master structure calculation
The Master’s degree in Structural Analysis and Calculation seeks to reinforce, increase, and strengthen the knowledge and skills of construction professionals in the areas of structural design, calculation, and dimensioning in civil works projects. This program consists of modules focused on the structural calculation of foundations, vaults, frames, screens, walls, among others, via conventional methods.
Objetivos
de Master structure calculation
- Reinforce and increase the students' knowledge of structural engineering. - Provide the essential theoretical / practical foundations to perform duties in the area of structural calculation. - Provide criteria and solid knowledge for the design and calculation of structures made of reinforced concrete, structural steel and wood structures, among other materials. - Provide students with the essential tools for the development of their professional and / or academic career in the field of structural calculation. - Learn the main structural typologies; learning to perform the implicit calculation model in each typology, its calculation and dimensioning.
Salidas profesionales
de Master structure calculation
The students will be able to acquire the necessary knowledge and skill required to perform duties, and develop their professional careers, related to structural engineering in civil works and construction firms, and in the areas of architectural studies in construction firms.
Para qué te prepara
el Master structure calculation
In addition to providing the necessary theoretical framework, this master’s program will enable students to carry out a diversity of practical cases and exercises. Finally, a master’s final Project must be prepared for the students to apply all of the knowledge they have acquired throughout the course.
A quién va dirigido
el Master structure calculation
- Consulting project engineers - Consulting engineering project managers - Project engineers and technical study specialists at construction firms - Project and technical study manager at construction firms - Numerical modernization professionals
Metodología
de Master structure calculation
Metodología Curso Euroinnova
Carácter oficial
de la formación
La presente formación no está incluida dentro del ámbito de la formación oficial reglada (Educación Infantil, Educación Primaria, Educación Secundaria, Formación Profesional Oficial FP, Bachillerato, Grado Universitario, Master Oficial Universitario y Doctorado). Se trata por tanto de una formación complementaria y/o de especialización, dirigida a la adquisición de determinadas competencias, habilidades o aptitudes de índole profesional, pudiendo ser baremable como mérito en bolsas de trabajo y/o concursos oposición, siempre dentro del apartado de Formación Complementaria y/o Formación Continua siendo siempre imprescindible la revisión de los requisitos específicos de baremación de las bolsa de trabajo público en concreto a la que deseemos presentarnos.

Temario de Master structure calculation

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MODULE 1. STRUCTURAL CALCULATION

UNIT 1. STRUCTURE TYPES AND CONNECTIONS
  1. Structure types
  2. Structure types according to their behavior
  3. Structure types according to their deformation
  4. Types of structural support elements. joints, embeddings and rollers
  5. Types of connections in metal and concrete structures
UNIT 2. STRESS ANALYSIS. ACTIONS AND EFFORTS
  1. Actions on structures
  2. Ultimate Limit State (ULS) and Serviceability Limit State (SLS)
  3. Calculation combinations
  4. Efforts/stresses on structures
  5. Structural design methods
UNIT 3. BENDING, SHEARING AND BUCKLING
  1. Bending, shearing and flexo-compression calculation
  2. Inestability types and solutions
  3. Compressive buckling
  4. Lateral torsional buckling
  5. Denting and reinforceable profiles. Criteria and solutions
UNIT 4. FUNDAMENTAL CONCEPTS AND APPLICATION
  1. Applying structural concepts
  2. Deformation calculation
  3. Beam calculation
  4. Pillar calculation
  5. Frame calculation

MODULE 2. CONSTRUCTION MATERIALS

UNIT 1. STEEL IN CONSTRUCTION
  1. Introduction. Manufacture and types
  2. Steel for concrete
  3. Types of structural steel
  4. Galvanized steel
  5. Aluminum
UNIT 2. CONCRETE IN CONSTRUCTION
  1. Types of concrete. Special types
  2. Mechanical properties of concrete
  3. Dimensioning shallow foundations
  4. Dimensioning short corbels
  5. Cracking in reinforced concrete
UNIT 3. LUMBER
  1. Lumber. Properties and construction products
  2. Calculation of plug joints in wood (I). Nails
  3. Calculation of plug joints in wood (II). Staples, bolts, pins and lag screws
  4. Calculation of woodworking joints. Splices and screwless
  5. Dimensioning lumber in fire scenarios
UNIT 4. OTHER MATERIALS AND SUSTAINABILITY
  1. Masonry works. Bricks and blocks. Types
  2. Basis for the calculation of a mansory wall
  3. Glass. Types and dimensioning
  4. Synthetic polymers. Types and applications
  5. Structural reinforcement with fiber-made materials

MODULE 3. CIVIL ENGINEERING STRUCTURAL CALCULATION

UNIT 1. PRESTRESSED CONCRETE
  1. Introduction
  2. Materials
  3. Prestressing force. Instantaneous losses
  4. Prestressing deferred losses
  5. Calculating prestressing force in hyperstatic structures
UNIT 2. UNDERPASS STRUCTURES OR BURIED WORKS
  1. Underpass works (I). Types
  2. Underpass works (II). Acting loads
  3. Cylindrical shells. Concepts and behavior
  4. Predimensioning of cylindrical shells (I). Concept and calculation
  5. Predimensioning of cylindrical shells (II). Spandrels and edge beams
UNIT 3. CONCRETE TANKS
  1. Concrete tank calculation elements
  2. Concrete tank design elements. Principles applied to calculating rectangular reinforced concrete tanks
  3. Calculating a rectangular reinforced concrete tank wall. Example
  4. Principles applied to calculating cylindrical reinforced concrete tanks
  5. Principles applied to analyzing a reinforced concrete tank floor slab. Example of how a rectangular reinforced concrete tank floor slab is calculated
UNIT 4. METAL TANKS
  1. Introduction. Design codes
  2. Types of storage tanks. Materials, joints and welds
  3. Design and calculation. Bottom and shell
  4. Calculation of fixed roofs
  5. Calculation by manometric pressure

MODULE 4. SHALLOW FOUNDATIONS

UNIT 1. DETERMINANTS AND STUDY FAILURE MODES
  1. Introduction and determinants
  2. Distribution of stresses below rigid foundations
  3. Verification of failure modes for ULS
  4. Verification of bearing capacity
  5. Correction factors
UNIT 2. ADDITIONAL NOTES ABOUT CARRYING CAPACITY
  1. Bearing capacity in non-homogenous soils
  2. Bearing capacity from in situ test
  3. Bearing capacity in particular soils
  4. Bearing capacity in rock (I)
  5. Bearing capacity in rock (II)
UNIT 3. LIMIT STATES OF SERVICE
  1. Definitions and concepts
  2. Stress distribution in the ground
  3. Settlements in granular soils
  4. Settlements in cohesive soils
  5. Other methods and other deformations
UNIT 4. RAFTS, WELLS, DYNAMIC ASPECTS AND OFFSHORE SCOPE
  1. Rafts
  2. Short rigid piers
  3. Machine foundations
  4. Foundation in earthquake-prone area and dynamic parameters
  5. Shallow foundations in maritime and offshore sectors

MODULE 5. DEEP FOUNDATIONS

UNIT 1. BASIC CONCEPTS AND COLUMN PILES IN SOILS
  1. Types of deep foundations. Terms. General rules of a deep foundation design
  2. Bearing capacity of a pile in soils. Basic formulation
  3. End bearing capacity in granular soils through analytical solutions
  4. End bearing capacity in cohesive soils through analytical solutions
  5. End bearing capacity in soils. In situ tests
UNIT 2. FLOATING PILES IN SOILS, PILES IN ROCK AND PILE GROUPS
  1. Skin friction capacity in granular soils through analytical solutions
  2. Skin friction capacity in cohesive soils through analytical solutions
  3. Skin friction capacity in granular and cohesive soils through in situ test
  4. Bearing capacity of a pile rocks
  5. Bearing capacity of a group of pile
UNIT 3. WORKLOADS AND PILES SETTLEMENT
  1. Safety coefficient. single pile and group of piles effect
  2. Structural strength
  3. Settlements in deep foundations
  4. Uplift load
  5. Dynamic formule for pile driving
UNIT 4. PILE SELECTION AND UNUSUAL SITUATIONS
  1. Verifying safety against ground failure owing to horizontal pull or pressure
  2. Negative Friction in Piles
  3. Load test in piles
  4. Choosing the type of pile
  5. Micro-piles

MODULE 6. EARTH PRESSURES AND RETAINING STRUCTURES.

UNIT 1. THEORY
  1. Classical earth pressures theory. Coulomb
  2. Classical earth pressures theory. Rankine, Terzaghi
  3. Classical earth pressure theory. Lateral earth pressures coefficient
  4. Classical earth pressures theory. Winkler spring model
  5. Other calculation methods. Numerical models and equivalent fluid theory
  6. Theory. Seismic considerations
UNIT 2. RIGID WALLS
  1. Rigid walls. Gravity walls
  2. Rigid walls. Reinforced concrete walls
  3. Rigid walls. Rock walls
  4. Rigid walls. Masonry walls and segmental retaining walls
UNIT 3. FLEXIBLE CANTILEVERED WALLS
  1. Flexible walls. Gabion walls and crib walls
  2. Flexible walls. mechanically stabilized earth wall
  3. Flexible walls. Diaphragm walls
  4. Flexible walls. Pile walls
  5. Anchors
  6. Flexible walls. sheet pile walls, king post walls, trenches
UNIT 4. DESING CONSIDERATIONS
  1. Other design considerations. construction procedures
  2. Other design considerations. ground movement and monitoring
  3. Other design considerations. problematic grounds
  4. Other design considerations. Design sections and groundwater flow diagram

MODULE 7. SEISMICITY AND SEISMIC-RESISTANT DESIGN

UNIT 1. INTRODUCTION AND CHARACTERISTICS OF SEISMIC ACTION
  1. What is an earthquake? Definition, causes, and effects. World highest seismicity regions
  2. Characteristics of seismic action. The concept of PGA. Seismic levels, return periods and seismic hazard curve
  3. Response spectrum, local geology, and amplification factors. Liquefaction
  4. Structure classification
  5. Seismic activity considerations in projects. Seismic vertical action, associated mass, and seismic action combinations
UNIT 2. ANALYSIS METHODS
  1. Introduction to modal analysis
  2. Seismic-resistant design methodology
  3. Static linear analysis (I). Equivalent lateral force method
  4. Dynamic linear analysis (II). Spectral and modal-spectral analyses
  5. Nonlinear analyses. The pushover analysis and the time-history method with accelerograms
UNIT 3. SEISMIC-RESISTANT DESIGN. METHODOLOGY AND REQUIREMENTS
  1. Basic design criteria in seismic areas
  2. Ductility. Behavioral factor
  3. Ductile design requirements for reinforced concrete
  4. Ductile design requirements for metal structures
  5. Displacement assessments. Seismic joints and spacing between surrounding structures
  6. Gravity and containment structures. Pseudo-static analysis. Seismic design and earth pressure equations
  7. Seismic-resistant design strategy. Dissipation Vs. Isolation
UNIT 4. PRACTICAL APPLICATION CASES
  1. Example 1. Structural design of land retaining walls
  2. Example 2. Design of reinforced concrete building. Application of Spectral-modal method
  3. Bibliography. Reference regulation and guides

MODULE 8. DESIGN OF INDUSTRIAL WAREHOUSES AND HIGH-RISE BUILDINGS

UNIT 1. DESIGN OF INDUSTRIAL WAREHOUSES (I)
  1. Industrial warehouses. Components and types
  2. Foundations
  3. Frames (I). Types
  4. Frames (II). Calculation
  5. Example of a gable frame
UNIT 2. DESIGN OF INDUSTRIAL WAREHOUSES (II)
  1. Bracing systems. Types
  2. Roof and facade purlins. Design and calculation
  3. Roof and facade bracing. Practical examples
  4. Overhead crane (I). Introduction
  5. Overhead crane (II). Actions and calculation
UNIT 3. CALCULATION AND DESIGN OF HIGH-RISE BUILDINGS (I)
  1. High-rise buildings. Introduction. General criteria
  2. Rigid frame systems
  3. Rigid core structures
  4. Tubular structures
  5. Stiffening systems for lateral stability
UNIT 4. CALCULATION AND DESIGN OF HIGH-RISE BUILDINGS (II)
  1. Building structural frames
  2. Building seismic calculation (I). The simplified method
  3. Building seismic calculation (II). Example
  4. Study on wind pressure
  5. Influence of axial deformations

MODULE 9. STRUCTURAL REHABILITATION

UNIT 1. FUNDAMENTAL CONCEPTS
  1. Fundamental concepts
  2. Seating cracks
  3. Crack control
  4. Pathologies in reinforced concrete structures
  5. Wood pathologies
UNIT 2. PATHOLOGIES IN BUILDING ELEMENTS
  1. Introduction
  2. Pathologies on roofs. General aspects
  3. Pathology in roofs according to their typologies
  4. Façade pathologies
  5. Pillars and slabs pathologies
UNIT 3. BRIDGE PATHOLOGIES
  1. Foundation pathologies
  2. Pathologies in the substructure
  3. Pathologies in the superstructure of concrete bridges
  4. Pathologies in the superstructure of the arched fridge
  5. Pathologies in the superstructure of steel and composite bridges
UNIT 4. REPAIRS AND REINFORCEMENTS
  1. Underpinning in shallow foundations
  2. Repairs to concrete structures
  3. Reinforcements in concrete structures
  4. Detailed design of composite pillars
  5. Moisture and water leakage therapy

MODULE 10. MFP. MASTER´S DEGREE IN STRUCTURAL ANALYSIS AND CALCULATION

Titulación de Master structure calculation

Master Degree Structural Analysis Calculation StructuraliaMaster Degree Structural Analysis Calculation Structuralia
Master Of Professional Development in Structural Analysis and Calculation with 60 ECTS Credits awarded by the Catholic University of Murcia in collaboration with Structuralia

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Información complementaria

Master structure calculation

What is Structural Calculation?

Structural calculation or structural analysis refers to the design of structures. It must ensure the proper execution of the construction project. This involves conducting calculations to accurately measure the effects of various loads, both internal forces such as its own weight, and external forces, such as rain or any unpredictable environmental phenomena. All of this information must be properly documented in a single report.

This document implies taking action in the project's development, recording all the relevant data, and intervening in the plans of various structures.

master cálculo de estructuras structuralia

In the execution of any type of construction project you can imagine, conducting a proper structural analysis is of vital importance. It is completely necessary to determine how much load a particular structure can withstand to ensure its safe use. Whether it's a new construction project or an improvement to an existing structure, this analysis is crucial and should never be overlooked.

 

As you can see, becoming a professional in Structural Analysis and Calculation with this Structuralia Master's in Structural Calculation will open up a diverse range of job opportunities for you. Your expertise will play a key role in the development of various projects, from residential constructions to public infrastructures and industrial works. If you have a passion for construction or architecture and wish to take the final step in your education to enter the job market in the best possible way, this Structuralia Master's in Structural Calculation is designed for you.

At Euroinnova International Online Education, we share your commitment to achieving your professional goals. That's why we offer this comprehensive training program to prepare you to become an expert in this exciting field.

Keep reading if you are interested in becoming a valuable asset and obtaining a Master's Degree in Structural Analysis and Calculation with 60 ECTS credits issued by the University Isabel I in collaboration with Structuralia, all from the comfort of your home.

Types of Structural Calculation

In order to ensure the safety and feasibility of the structures being built, an expert in this area must perform numerous calculations. Here are the main types of calculations:

  1. Stress analysis: This is based on studying the reaction of a structure when an equal-magnitude load is applied in the opposite direction.

  2. Bending moment analysis: These calculations refer to the force that causes the bending of a structure when a specific amount of force is applied at a predetermined distance, resulting in deformation.

  3. Load and wind pressure analysis: Involves calculating the effects of loads and wind pressures on the structure.

  4. Shear stress analysis: Focuses on the effect of applying a force parallel or tangential to a specific area, causing the twisting of a section of the structure.

  5. Seismic movements analysis: This type of calculation considers the response of the structure to seismic forces and vibrations.

Elements that encompass structural calculation

These calculations are essential to ensure the structural integrity and safety of any construction project. A thorough analysis of these factors helps in designing and building structures that can withstand various loads and environmental conditions.

As a qualified specialist in Structural Analysis and Calculation, you will need to be knowledgeable about and closely control various factors related to structural engineering. Below are the key elements that the professional will need to address in any structural project:

  1. Predicting stiffness levels: You should be capable of predicting the stiffness levels of a structure, which is crucial for its stability and performance.

  2. Compliance with regulations: It is essential to ensure compliance with local regulations and any specific requirements related to the materials used in the construction.

  3. Performing various calculations: You will be responsible for conducting a wide range of calculations, both graphical and numerical, to design and build the structure effectively.

  4. Ensuring legal and safety requirements: You must ensure that all necessary legal requirements are met for the construction project and that the safety of workers and the public is not compromised.

  5. Interpreting detailed plans: You will work with detailed plans of the project and need to be familiar with all instructions and maintenance procedures related to the systems and materials involved.

  6. Thorough analysis of calculations: You will need to conduct a comprehensive analysis of the applied calculations, considering factors such as unpredictable external circumstances, strength calculations, modifications during construction, and the predicted use of the structure.

By mastering these elements of structural calculation, you will play a critical role in designing and constructing safe and reliable structures that meet all legal and safety standards.

Don't hesitate any longer and become a true professional in Structural Analysis and Calculation. You will be qualified to take on a high-responsibility role in the construction of all types of structures.

If you still have any questions about this training program or any other, don't hesitate to contact us through the website.

We remain at your disposal!

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