Acquire the most advanced and up-to-date knowledge in the field of Building Rehabilitation and Energy Saving with a highly qualified expert and training impact"

The key concepts of analysis such as transmittances and conductivities of materials and construction details will be presented, as well as how to calculate them in order to compare parameters of different intervention options.

We will analyze different types of insulating materials for foundations, facades, roofs, slabs in contact with the outside air either in floor or roof layout, as well as singular encounters such as the insulation of retaining walls in contact with the building and encounters with skids of installations and chimneys of buildings.

We will describe various ways to optimize other more unique types of constructions such as prefabricated buildings, with wood construction solutions either with light frame or with CLT panels, Steel-Frame or modular industrialized metal and concrete construction as future experiences with various innovative solutions.

We will complete the analysis of the different constructive details of the different envelope types by means of an in-depth thermographic study that will allow us to have a practical knowledge of the energetic reality of the proposed solutions.

The key concepts of analysis will be presented, such as the technical data of the composition of carpentry and glazing, transmittances, air permeability, water tightness, wind resistance, as well as how to calculate them in order to compare parameters of different intervention options.

In addition, the types of existing glazing, their composition and the optimization of each composition according to the technical requirements of the work will be analyzed.

We will describe the importance of solar protection, analyzing the different types depending on the layout and the optimization and uniqueness of each opening based on the technical requirements of the site.

We will describe the latest high energy performance carpentries offered by the market and the trends of the sector, as well as singular cases of technical value.

Join the elite, with this highly effective training training and open new paths to help you advance in your professional progress"

This Postgraduate diploma in Passive Energy Optimization Measures in Buildings contains the most complete and up-to-date program on the market. The most important features include:

• Latest technology in online teaching software
• Highly visual teaching system, supported by graphic and schematic contents that are easy to assimilate and understand
• Practical cases presented by practising experts
• State-of-the-art interactive video systems
• Teaching supported by telepractice
• Continuous updating and recycling systemsTECH Global University
• Self-regulating learning: full compatibility with other occupations
• Practical exercises for self-evaluation and learning verification
• Support groups and educational synergies: questions to the expert, debate and knowledge forums
• Communication with the teacher and individual reflection work
• Content that is accessible from any fixed or portable device with an Internet connection
• Internet connection
• Supplementary documentation databases that are permanently available, even after the course has concluded

With the experience of active professionals and the analysis of real cases of success in the application and use of energy saving systems in buildings"

Our teaching staff is made up of professionals from different fields related to this specialty. In this way, we ensure that we provide you with the educational update we are aiming for. A multidisciplinary team of professionals trained and experienced in different environments, who will develop the theoretical knowledge in an efficient way, but above all, they will bring their practical knowledge from their own experience to the course: one of the differential qualities of this training.

This mastery of the subject matter is complemented by the effectiveness of the methodological design. Developed by a multidisciplinary team of e-learning experts, it integrates the latest advances in educational technology. This way, you will be able to study with a range of comfortable and versatile multimedia tools that will give you the operability you need in your education.

The design of this program is based on Problem-Based Learning: an approach that conceives learning as a highly practical process. To achieve this remotely, we will use telepractice: with the help of an innovative interactive video system, and learning from an expert, you will be able to acquire the knowledge as if you were actually dealing with the scenario you are learning about. A concept that will allow you to integrate and fix learning in a more realistic and permanent way.

With a methodological design based on proven teaching techniques, this innovative course will take you through different teaching approaches to allow you to learn in a dynamic and effective way"

Our innovative telepractice concept will give you the opportunity to learn through an immersive experience, which will provide you with a faster integration and a much more realistic view of the contents: “learning from an expert"

The contents of this program have been developed by the different experts on this course, with a clear purpose: to ensure that our students acquire each and every one of the necessary skills to become true experts in this field.

A complete and well-structured program that will take you to the highest standards of quality and success.

A comprehensive teaching program, structured in well-developed teaching units, oriented towards learning that is compatible with your personal and professional life"

Module 1. Energy Efficiency in the Envelope

1.1. Main Concepts

1.1.1 Materials
1.1.2 Thicknesses
1.1.3 Conductivity
1.1.4 Transmittance

1.2. Foundation Insulation

1.2.1 Materials
1.2.2 Layout
1.2.3 Technical Justifications
1.2.4 Innovation Solutions

1.3. Facade Insulation

1.3.1 Materials
1.3.2 Layout
1.3.3 Technical Justifications
1.3.4 Innovation Solutions

1.4. Roof Insulation

1.4.1 Materials
1.4.2 Layout
1.4.3 Technical Justifications
1.4.4 Innovation Solutions

1.5. Floor Slab Insulation: Floors

1.5.1 Materials
1.5.2 Layout
1.5.3 Technical Justifications
1.5.4 Innovation Solutions

1.6. Floor Slab Insulation: Ceilings

1.6.1 Materials
1.6.2 Layout
1.6.3 Technical Justifications
1.6.4 Innovation Solutions

1.7. Basement Wall Insulation

1.7.1 Materials
1.7.2 Layout
1.7.3 Technical Justifications
1.7.4 Innovation Solutions

1.8. Installation Skids Vs. Chimneys

1.8.1 Materials
1.8.2 Layout
1.8.3 Technical Justifications
1.8.4 Innovation Solutions

1.9. Envelope in Prefabricated Buildings

1.9.1 Materials
1.9.2 Layout
1.9.3 Technical Justifications
1.9.4 Innovation Solutions

1.10. Innovation Solutions

1.10.1 Thermography Analysis
1.10.2 Thermography According to Layout
1.10.3 Development of Thermographic Analysis
1.10.4 Solutions to be Implemented

Module 2. Energy Savings in Windows and Glazing

2.1. Types of Joinery

2.1.1 Single Material Solutions
2.1.2 Mixed Solutions
2.1.3 Technical Justifications
2.1.4 Innovation Solutions

2.2. Transmittance

2.2.1 Definition
2.2.2 Regulations
2.2.3 Technical Justifications
2.2.4 Innovation Solutions

2.3. Air Permeability

2.3.1 Definition
2.3.2 Regulations
2.3.3 Technical Justifications
2.3.4 Innovation Solutions

2.4. Water Tightness

2.4.1 Definition
2.4.2 Regulations
2.4.3 Technical Justifications
2.4.4 Innovation Solutions

2.5. Wind Resistance

2.5.1 Definition
2.5.2 Regulations
2.5.3 Technical Justifications
2.5.4 Innovation Solutions

2.6. Types of Glasses

2.6.1 Definition
2.6.2 Regulations
2.6.3 Technical Justifications
2.6.4 Innovation Solutions

2.7. Glass Composition

2.7.1 Definition
2.7.2 Regulations
2.7.3 Technical Justifications
2.7.4 Innovation Solutions

2.8. Solar Shading

2.8.1 Definition
2.8.2 Regulations
2.8.3 Technical Justifications
2.8.4 Innovation Solutions

2.9. High Energy Performance Joinery

2.9.1 Definition
2.9.2 Regulations
2.9.3 Technical Justifications
2.9.4 Innovation Solutions

2.10. High Energy Performance Glasses

2.10.1 Definition
2.10.2 Regulations
2.10.3 Technical Justifications
2.10.4 Innovation Solutions

Module 3. Energy Savings in Thermal Bridges

3.1. Main Concepts

3.1.1 Definition
3.1.2 Regulations
3.1.3 Technical Justifications
3.1.4 Innovation Solutions

3.2. Constructive Thermal Bridges

3.2.1 Definition
3.2.2 Regulations
3.2.3 Technical Justifications
3.2.4 Innovation Solutions

3.3. Geometric Thermal Bridges

3.3.1 Definition
3.3.2 Regulations
3.3.3 Technical Justifications
3.3.4 Innovation Solutions

3.4. Thermal Bridges due to Material Change

3.4.1 Definition
3.4.2 Regulations
3.4.3 Technical Justifications
3.4.4 Innovation Solutions

3.5. Analysis of Singular Thermal Bridges: The Window

3.5.1 Definition
3.5.2 Regulations
3.5.3 Technical Justifications
3.5.4 Innovation Solutions

3.6. Analysis of Singular Thermal Bridges: The Splayed

3.6.1 Definition
3.6.2 Regulations
3.6.3 Technical Justifications
3.6.4 Innovation Solutions

3.7. Analysis of Singular Thermal Bridges: The Pillar

3.7.1 Definition
3.7.2 Regulations
3.7.3 Technical Justifications
3.7.4 Innovation Solutions

3.8. Analysis of Singular Thermal Bridges: The Forging

3.8.1 Definition
3.8.2 Regulations
3.8.3 Technical Justifications
3.8.4 Innovation Solutions

3.9. Thermal Bridge Analysis with Thermography

3.9.1 Thermographic Equipment
3.9.2 Work Conditions
3.9.3 Detection of Encounters to be Corrected
3.9.4 Thermography in the Solution

3.10. Thermal Bridge Calculation Tools

3.10.1 Therm
3.10.2 Cypetherm He Plus
3.10.3 Flixo
3.10.4 Case Study 1

Module 4. Energy Savings in Airtightness

4.1. Main Concepts

4.1.1 Definition of airtightness vs. watertightness
4.1.2 Regulations
4.1.3 Technical Justifications
4.1.4 Innovation Solutions

4.2. Control of Airtightness in the Enclosure

4.2.1 Location
4.2.2 Regulations
4.2.3 Technical Justifications
4.2.4 Innovation Solutions

4.3. Tightness Control in Installations

4.3.1 Location
4.3.2 Regulations
4.3.3 Technical Justifications
4.3.4 Innovation Solutions

4.4. Pathologies

4.4.1 Condensations
4.4.2 Moisture
4.4.3 Energy Consumption
4.4.4 Low Comfort

4.5. Comfort

4.5.1 Definition
4.5.2 Regulations
4.5.3 Technical Justifications
4.5.4 Innovation Solutions

4.6. Indoor Air Quality

4.6.1 Definition
4.6.2 Regulations
4.6.3 Technical Justifications
4.6.4 Innovation Solutions

4.7. Noise Protection

4.7.1 Definition
4.7.2 Regulations
4.7.3 Technical Justifications
4.7.4 Innovation Solutions

4.8. Tightness Test: Thermography

4.8.1 Thermographic Equipment
4.8.2 Work Conditions
4.8.3 Detection of Encounters to be Corrected
4.8.4 Thermography in the Solution

4.9. Smoke Testing

4.9.1 Smoke Test Equipment
4.9.2 Work Conditions
4.9.3 Detection of Encounters to be Corrected
4.9.4 Smoke Test in the Solution

4.10. Blower Door Test

4.10.1 Blower Door Test Equipment
4.10.2 Work Conditions
4.10.3 Detection of Encounters to be Corrected
4.10.4 Blower-Door Test in the Solution

This program will allow you to advance in your career comfortably"