A legal framework for sharing customs intelligence through the single window system

<p>Some customs agencies are implementing electronic single window systems. These single window systems enable an importer or exporter to digitally transmit their transaction information to the customs administration. The single window system shares relevant information with other government agencies involved in the import or export process. It relieves the importer or exporter of the need to lodge transaction information separately with each government agency. An international single window system is the interconnection of two or more national single window systems. It enables the exporter’s transaction information to be re-used in import processing, thereby reducing the amount of information required from importers. For states that already have customs intelligence-sharing agreements, a single window system could be used to exchange intelligence information about the import and export transactions processed by the system. Intelligence-sharing agreements can and should include transparent protection for human rights. The human rights relevant to this legal framework are access to justice, freedom from arbitrary search and seizure, freedom from torture and the right to privacy. The right to privacy is the human right most affected by intelligence-sharing. This thesis proposes a legal framework to enable intelligence to be shared through a single window system with transparent terms for managing human rights. This thesis suggests that public confidence would be improved by showing how privacy and other human rights are treated in the rules for customs intelligence-sharing using the system proposed here.</p>

A legal framework for sharing customs intelligence through the single window system

<p>Some customs agencies are implementing electronic single window systems. These single window systems enable an importer or exporter to digitally transmit their transaction information to the customs administration. The single window system shares relevant information with other government agencies involved in the import or export process. It relieves the importer or exporter of the need to lodge transaction information separately with each government agency. An international single window system is the interconnection of two or more national single window systems. It enables the exporter’s transaction information to be re-used in import processing, thereby reducing the amount of information required from importers. For states that already have customs intelligence-sharing agreements, a single window system could be used to exchange intelligence information about the import and export transactions processed by the system. Intelligence-sharing agreements can and should include transparent protection for human rights. The human rights relevant to this legal framework are access to justice, freedom from arbitrary search and seizure, freedom from torture and the right to privacy. The right to privacy is the human right most affected by intelligence-sharing. This thesis proposes a legal framework to enable intelligence to be shared through a single window system with transparent terms for managing human rights. This thesis suggests that public confidence would be improved by showing how privacy and other human rights are treated in the rules for customs intelligence-sharing using the system proposed here.</p>

Conservation compatible energy retrofit technologies: Part II: Documentation and assessment of conventional and innovative solutions for conservation and thermal enhancement of window systems in historic buildings

The main objective of Subtask C is to identify, assess and in some cases further develop retrofit solutions and strategies for historic buildings. The solutions should fulfil the conservation compatibility of historic buildings as well as energy efficiency goals towards lowest possible energy demand and CO2 emissions (NZEB). Further, the objective is to make the solutions available for comprehensive integrated refurbishing concepts and strategies.

Investigating thermal bridging in window systems insulated with monolithic silica aerogel.

Windows typically account for 30% to 50% of heat losses through building envelopes. Monolithic silica aerogel has thermal properties and physical characteristics which make it an attractive material for high performance glazing. Optimizing the thermal performance of individual window components can improve the thermal performance of windows insulated with monolithic silica aerogel. It is important to consider how the thermal properties can be sustained, especially when in contact with other window components such as edge and intermediate spacers and the window frame. The purpose of this research paper is to analyze French style windows insulated with four panes of monolithic silica aerogel and investigate the thermal bridging of edge and intermediate spacers and window frame in order to assess how they collectively affect the centre of glass and edge of glass regions. The research aims to determine the spacer geometry, materials, and window frame that guarantee the best performing window system.

Exploring Acoustical Approach for Pre-screening of Window Assemblies Airtightness Level in an Existing Building

Air infiltration plays a significant role in designing and evaluating the performance and air quality of a building. Air leakage through an existing building enclosure can be detected by using experimental measurements, such as blower door test, tracer gas method, and transient approach. Estimating building air permeability through these methods can be expensive, time consuming, and weather reliant. The economical and environmental effect of air infiltration through building envelope requires higher level of research on locating air leakage locations and estimating air infiltration rate through new techniques, such as acoustical methods. In this research, a general review of airtightness detection and quantification method is presented and acoustical techniques are explored more in depth. Due to the significant impact of window systems on the total air infiltration through the building envelope, the correlation between the sound transmission loss and the air permeability through seven window assemblies in an existing building are explored to investigate acoustical method further. In addition, the acoustic air leakage detection method based on the standard ASTM E1186 is instigated. The results reveal the poor correlation between the airtightness of the windows and the acoustical analysis and investigations

Exploring Acoustical Approach for Pre-screening of Window Assemblies Airtightness Level in an Existing Building

Air infiltration plays a significant role in designing and evaluating the performance and air quality of a building. Air leakage through an existing building enclosure can be detected by using experimental measurements, such as blower door test, tracer gas method, and transient approach. Estimating building air permeability through these methods can be expensive, time consuming, and weather reliant. The economical and environmental effect of air infiltration through building envelope requires higher level of research on locating air leakage locations and estimating air infiltration rate through new techniques, such as acoustical methods. In this research, a general review of airtightness detection and quantification method is presented and acoustical techniques are explored more in depth. Due to the significant impact of window systems on the total air infiltration through the building envelope, the correlation between the sound transmission loss and the air permeability through seven window assemblies in an existing building are explored to investigate acoustical method further. In addition, the acoustic air leakage detection method based on the standard ASTM E1186 is instigated. The results reveal the poor correlation between the airtightness of the windows and the acoustical analysis and investigations

Investigating thermal bridging in window systems insulated with monolithic silica aerogel.

Windows typically account for 30% to 50% of heat losses through building envelopes. Monolithic silica aerogel has thermal properties and physical characteristics which make it an attractive material for high performance glazing. Optimizing the thermal performance of individual window components can improve the thermal performance of windows insulated with monolithic silica aerogel. It is important to consider how the thermal properties can be sustained, especially when in contact with other window components such as edge and intermediate spacers and the window frame. The purpose of this research paper is to analyze French style windows insulated with four panes of monolithic silica aerogel and investigate the thermal bridging of edge and intermediate spacers and window frame in order to assess how they collectively affect the centre of glass and edge of glass regions. The research aims to determine the spacer geometry, materials, and window frame that guarantee the best performing window system.