Your search keyword '"Graphical method"' showing total 13 results

1. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

2. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

3. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

4. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

5. Development of Variants of High-Performance Self-Compacting Concrete with Improved Resistance to the Attack of Sulfates

Abstract

This paper presents experimental and analytical work of which the main objective was to support the introduction of a new technology for the production of sewer pipes. In this technology, the pipes produced consist of two differently produced parts. The direct part uses conventional vibro press compacted concrete. In the curved part, on the other hand, self-compacting concrete technology is used. The cooperating company, Prefa Brno a.s., defined possible negative effects on concrete of sewer pipes. The task of the research team and now the author’s team was to propose a procedure for the development of suitable self-compacting concrete variants and subsequently the design of a methodology to verify their durability in aqueous environments containing sulfates. To increase the efficiency of the development, the model mortar method was used in the experimental work. That is, instead of the original concrete, a model mortar derived from it was tested. The principle and procedure of derivation of model mortars are described in the paper. In total, eight variants of model mortars were tested, and at least three of them fulfilled the requirements. An optional but beneficial part of the carried out work was the derivation and practical application of the time-anchored-triangles-of-cracking graphical method developed during the research. This method is used to quickly compare the degree of attack of different silicate composites tested in a common bath inducing type III corrosion.

Published

2021

6. Development of Variants of High-Performance Self-Compacting Concrete with Improved Resistance to the Attack of Sulfates

Abstract

This paper presents experimental and analytical work of which the main objective was to support the introduction of a new technology for the production of sewer pipes. In this technology, the pipes produced consist of two differently produced parts. The direct part uses conventional vibro press compacted concrete. In the curved part, on the other hand, self-compacting concrete technology is used. The cooperating company, Prefa Brno a.s., defined possible negative effects on concrete of sewer pipes. The task of the research team and now the author’s team was to propose a procedure for the development of suitable self-compacting concrete variants and subsequently the design of a methodology to verify their durability in aqueous environments containing sulfates. To increase the efficiency of the development, the model mortar method was used in the experimental work. That is, instead of the original concrete, a model mortar derived from it was tested. The principle and procedure of derivation of model mortars are described in the paper. In total, eight variants of model mortars were tested, and at least three of them fulfilled the requirements. An optional but beneficial part of the carried out work was the derivation and practical application of the time-anchored-triangles-of-cracking graphical method developed during the research. This method is used to quickly compare the degree of attack of different silicate composites tested in a common bath inducing type III corrosion.

Published

2021

7. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

8. Development of Variants of High-Performance Self-Compacting Concrete with Improved Resistance to the Attack of Sulfates

Author

Terzijski, Ivailo, Kocáb, Dalibor, Štěpánek, Petr, Strnad, Jiří, Girgle, František, Šimůnek, Petr, Terzijski, Ivailo, Kocáb, Dalibor, Štěpánek, Petr, Strnad, Jiří, Girgle, František, and Šimůnek, Petr

Abstract

This paper presents experimental and analytical work of which the main objective was to support the introduction of a new technology for the production of sewer pipes. In this technology, the pipes produced consist of two differently produced parts. The direct part uses conventional vibro press compacted concrete. In the curved part, on the other hand, self-compacting concrete technology is used. The cooperating company, Prefa Brno a.s., defined possible negative effects on concrete of sewer pipes. The task of the research team and now the author’s team was to propose a procedure for the development of suitable self-compacting concrete variants and subsequently the design of a methodology to verify their durability in aqueous environments containing sulfates. To increase the efficiency of the development, the model mortar method was used in the experimental work. That is, instead of the original concrete, a model mortar derived from it was tested. The principle and procedure of derivation of model mortars are described in the paper. In total, eight variants of model mortars were tested, and at least three of them fulfilled the requirements. An optional but beneficial part of the carried out work was the derivation and practical application of the time-anchored-triangles-of-cracking graphical method developed during the research. This method is used to quickly compare the degree of attack of different silicate composites tested in a common bath inducing type III corrosion.

Published

2021

9. Engineering graphics for thermal assessment: 3D thermal data visualisation based on infrared thermography, GIS and 3D point cloud processing software

Author

Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, Amaro Mellado, José Lázaro, Universidad de Sevilla. Departamento de Expresión Gráfica e Ingeniería en la Edificación, Universidad de Sevilla. Departamento de Ingeniería Gráfica, Universidad de Sevilla. TEP970: Innovación Tecnológica, Sistemas de Modelado 3d y Diagnosis Energética en Patrimonio y Edificación, Universidad de Sevilla. TEP107: Estructuras y Geotecnia, Antón García, Daniel, and Amaro Mellado, José Lázaro

Abstract

Engineering graphics are present in the design stage, but also constitute a way to communicate, analyse, and synthesise. In the Architecture-Engineering-Construction sector, graphical data become essential in analysing buildings and constructions throughout their lifecycles, such as in the thermal behaviour assessment of building envelopes. Scientific research has addressed the thermal image mapping onto three-dimensional (3D) models for visualisation and analysis. However, the 3D point cloud data creation of buildings’ thermal behaviour directly from rectified infrared thermography (IRT) thermograms is yet to be investigated. Therefore, this paper develops an open-source software graphical method to produce 3D thermal data from IRT images for temperature visualisation and subsequent analysis. This low-cost approach uses both a geographic information system for the thermographic image rectification and the point clouds production, and 3D point cloud processing software. The methodology has been proven useful to obtain, without perspective distortions, 3D thermograms even from non-radiometric raster images. The results also revealed that non-rectangular thermograms enable over 95% of the 3D thermal data generated from IRT against rectangular shapes (over 85%). Finally, the 3D thermal data produced allow further thermal behaviour assessment, including calculating the object’s heat loss and thermal transmittance for diverse applications such as energy audits, restoration, monitoring, or product quality control.

Published

2021

10. Prediction of Satellite Shadowing in Smart Cities with Application to IoT

Author

Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, Baena Lecuyer, Vicente, Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, and Baena Lecuyer, Vicente

Abstract

The combination of satellite direct reception and terrestrial 5G infrastructure is essential to guarantee coverage in satellite based-Internet of Things, mainly in smart cities where buildings can cause high power losses. In this paper, we propose an accurate and fast graphical method for predicting the satellite coverage in urban areas and SatCom on-the-move scenarios. The aim is to provide information that could be useful in the IoT network planning process, e.g., in the decision of how many terrestrial repeaters are really needed and where they should be placed. Experiments show that the shadowed areas predicted by the method correspond almost perfectly with experimental data measured from an Eutelsat satellite in the urban area of Barcelona.

Published

2020

11. Prediction of Satellite Shadowing in Smart Cities with Application to IoT

Author

Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, Baena Lecuyer, Vicente, Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, and Baena Lecuyer, Vicente

Abstract

The combination of satellite direct reception and terrestrial 5G infrastructure is essential to guarantee coverage in satellite based-Internet of Things, mainly in smart cities where buildings can cause high power losses. In this paper, we propose an accurate and fast graphical method for predicting the satellite coverage in urban areas and SatCom on-the-move scenarios. The aim is to provide information that could be useful in the IoT network planning process, e.g., in the decision of how many terrestrial repeaters are really needed and where they should be placed. Experiments show that the shadowed areas predicted by the method correspond almost perfectly with experimental data measured from an Eutelsat satellite in the urban area of Barcelona.

Published

2020

12. Prediction of Satellite Shadowing in Smart Cities with Application to IoT

Author

Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, Baena Lecuyer, Vicente, Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, and Baena Lecuyer, Vicente

Abstract

The combination of satellite direct reception and terrestrial 5G infrastructure is essential to guarantee coverage in satellite based-Internet of Things, mainly in smart cities where buildings can cause high power losses. In this paper, we propose an accurate and fast graphical method for predicting the satellite coverage in urban areas and SatCom on-the-move scenarios. The aim is to provide information that could be useful in the IoT network planning process, e.g., in the decision of how many terrestrial repeaters are really needed and where they should be placed. Experiments show that the shadowed areas predicted by the method correspond almost perfectly with experimental data measured from an Eutelsat satellite in the urban area of Barcelona.

Published

2020

13. Prediction of Satellite Shadowing in Smart Cities with Application to IoT

Author

Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, Baena Lecuyer, Vicente, Universidad de Sevilla. Departamento de Teoría de la Señal y Comunicaciones, Universidad de Sevilla. Departamento de Ingeniería Electrónica, Ministerio de Industria, Turismo y Comercio. España, Hornillo Mellado, Susana, Martín Clemente, Rubén, and Baena Lecuyer, Vicente

Abstract

The combination of satellite direct reception and terrestrial 5G infrastructure is essential to guarantee coverage in satellite based-Internet of Things, mainly in smart cities where buildings can cause high power losses. In this paper, we propose an accurate and fast graphical method for predicting the satellite coverage in urban areas and SatCom on-the-move scenarios. The aim is to provide information that could be useful in the IoT network planning process, e.g., in the decision of how many terrestrial repeaters are really needed and where they should be placed. Experiments show that the shadowed areas predicted by the method correspond almost perfectly with experimental data measured from an Eutelsat satellite in the urban area of Barcelona.

Published

2020