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Publications (10 of 20) Show all publications
Sattari, A. (2020). A Comparison of Energy Calculations for a Single-Family Detached Home with Two Energy Simulation Methods. International Journal of Urban and Civil Engineering, 14(5), 150-154
Open this publication in new window or tab >>A Comparison of Energy Calculations for a Single-Family Detached Home with Two Energy Simulation Methods
2020 (English)In: International Journal of Urban and Civil Engineering, E-ISSN 1307-6892, Vol. 14, no 5, p. 150-154Article in journal (Refereed) Published
Abstract [en]

For newly produced houses and energy renovations, an energy calculation needs to be conducted. This is done to verify whether the energy consumption criteria of the house -to reach the energy targets by 2020 and 2050- are in-line with the norms. The main purpose of this study is to confirm whether easy to use energy calculation software or hand calculations used by small companies or individuals give logical results compared to advanced energy simulation program used by researchers or bigger companies. There are different methods for calculating energy consumption. In this paper, two energy calculation programs are used and the relation of energy consumption with solar radiation is compared. A hand calculation is also done to validate whether the hand calculations are still reasonable. The two computer programs which have been used are TMF Energi (the easy energy calculation variant used by small companies or individuals) and IDA ICE - Indoor Climate and Energy (the advanced energy simulation program used by researchers or larger companies). The calculations are done for a standard house from the Swedish house supplier Fiskarhedenvillan. The method is based on having the same conditions and inputs in the different calculation forms so that the results can be compared and verified. The house has been faced differently to see how the orientation affects energy consumption in different methods. The results for the simulations are close to each other and the hand calculation differs from the computer programs by only 5%. Even if solar factors differ due to the orientation of the house, energy calculation results from different computer programs and even hand calculation methods are in line with each other.

Place, publisher, year, edition, pages
World Academy of Science, Engineering and Technology, 2020
Keywords
Energy Consumption, Energy Simulation, IDA ICE, energy calculation, TMF energi
National Category
Energy Engineering
Identifiers
urn:nbn:se:oru:diva-82977 (URN)
Available from: 2020-06-11 Created: 2020-06-11 Last updated: 2024-05-14Bibliographically approved
Sattari, A. (2019). Effect of Pulsative Inflow to a Small-Scale Room model: CFD Simulation of an Innovative Ventilation Solution. In: : . Paper presented at International Conference on Healthy Buildings, London, United Kingdom, November 18 - 19, 2019 (pp. 977-983). London
Open this publication in new window or tab >>Effect of Pulsative Inflow to a Small-Scale Room model: CFD Simulation of an Innovative Ventilation Solution
2019 (English)Conference paper, Published paper (Refereed)
Abstract [en]

In this study, the effects of having a pulsative inflow to a wall jet within a 2-D enclosure are investigated using both (Particle Image Velocimetry (PIV) measurements and Computational Fluid Dynamics (CFD) simulations. The main hypothesis of the study is that the pulsation can improve the mixing performance of the wall jet into the small-scale 2-Droom model. Both CFD and PIV experiments focused on comparison of downstream flow-field of a wall-jet with constant and pulsative inflow modes. 

Obtained results have proved that the pulsation has the ability to improve mixing thorough generating secondary vortices in the downstream of the wall-jet, and same global airflow pattern exists for both of the cases but with generation of more eddies and local periodical velocity variations for pulsation mode. This periodic generation of turbulence with pulsative inflo9w has happened despite the relatively low Reynolds numbers. The bigger size of boundary layer and higher turbulent kinetic energy for the pulsative inflow in comparison with the same flow rate in constant flow mode could result in more ventilation effectiveness without the need to increase flow rate. When itcomes to real-scale ventilation applications, a lower pulsated inflow could produce the same acceptable results in terms of mixing efficiency as a higher constant flow rate, which results in a more energy-efficient ventilation strategy with lower risk of draught and thus better thermal comfort. The computational is done thorough grid independency study.

The study is therefore done with 3D SST-kΩ which yielded good prediction of velocity profiles near walls. For predicting turbulence parameters in the center of the domain SAS has been used which has been successful to get close toreality results.

Place, publisher, year, edition, pages
London: , 2019
Keywords
PIV, CFD, pulsative inflow, ventilation, walljet
National Category
Engineering and Technology Fluid Mechanics and Acoustics
Research subject
Mechanical Engineering; Building Technology
Identifiers
urn:nbn:se:oru:diva-78175 (URN)
Conference
International Conference on Healthy Buildings, London, United Kingdom, November 18 - 19, 2019
Available from: 2019-11-26 Created: 2019-11-26 Last updated: 2019-11-27Bibliographically approved
Henning, A. & Sattari, A. (2017). Evaluating thermal comfort in a Swedish block of flats: A methodological comparison. In: : . Paper presented at Healthy Buildings 2017 Europe, July 2-5, 2017, Lublin, Poland.
Open this publication in new window or tab >>Evaluating thermal comfort in a Swedish block of flats: A methodological comparison
2017 (English)Conference paper, Published paper (Refereed)
Abstract [en]

Two methodological approaches have been used to investigate thermal comfort amongoccupants in a Swedish block of flats; measurements and thermal comfort standards on the onehand, and qualitative interviews on the other. The purpose with this paper is to present, compareand discuss results from these two radically different methods. The results coincide concerningvariations of thermal comfort throughout the day, but are much less in accord in results whereoccupants express, or are presumed to complain of, thermal discomfort. The interviews showthat female occupants tend to suffer more from thermal discomfort than male occupants, a resultwhich is absent in the measurement methodology. The results give support to suggestions thatgender aspects should be taken more into account when determining and controlling thermalcomfort. The differing results also point at the importance of complementing standardizedthermal comfort measurements with surveys or qualitative interviews.

Keywords
Thermal comfort, indoor climate, occupants, methods comparison, gender
National Category
Other Civil Engineering
Research subject
Energy and Built Environments
Identifiers
urn:nbn:se:oru:diva-82957 (URN)2-s2.0-85053927536 (Scopus ID)978-83-7947-232-1 (ISBN)
Conference
Healthy Buildings 2017 Europe, July 2-5, 2017, Lublin, Poland
Projects
E2B2Social hållbarhet vid varsam energieffektiv renovering
Funder
Swedish Energy Agency
Available from: 2020-06-11 Created: 2020-06-11 Last updated: 2020-06-11
Kabanshi, A., Sattari, A., Linden, E., Wigö, H. & Sandberg, M. (2017). Experimental study on contaminant entrainment in air distribution systems with free jets. In: : . Paper presented at Healthy Buildings 2017 Europe, July 2-5, 2017, Lublin, Poland. , Article ID 0040.
Open this publication in new window or tab >>Experimental study on contaminant entrainment in air distribution systems with free jets
Show others...
2017 (English)Conference paper, Published paper (Refereed)
Keywords
Ambient entrainment, Jet development, PIV, Reynolds numbers
National Category
Energy Engineering Fluid Mechanics and Acoustics Other Civil Engineering
Research subject
Energy and Built Environments
Identifiers
urn:nbn:se:oru:diva-82958 (URN)2-s2.0-85053896607 (Scopus ID)978-83-7947-232-1 (ISBN)
Conference
Healthy Buildings 2017 Europe, July 2-5, 2017, Lublin, Poland
Available from: 2020-06-11 Created: 2020-06-11 Last updated: 2020-06-11
Sattari, A. (2015). Investigations of Flow Patterns in Ventilated Rooms Using Particle Image Velocimetry: Applications in a Scaled Room with Rapidly Varying Inflow and over a Wall-Mounted Radiator. (Doctoral dissertation). Stockholm: KTH Royal Institute of Technology
Open this publication in new window or tab >>Investigations of Flow Patterns in Ventilated Rooms Using Particle Image Velocimetry: Applications in a Scaled Room with Rapidly Varying Inflow and over a Wall-Mounted Radiator
2015 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

This thesis introduces and describes a new experimental setup for examining the effects of pulsating inflow to a ventilated enclosure. The study aimed to test the hypothesis that a pulsating inflow has potential to improve ventilation quality by reducing the stagnation zones through enhanced mixing. The experimental setup, which was a small-scale, two-dimensional (2D), water-filled room model, was successfully designed and manufactured to be able to capture two-dimensional velocity vectors of the entire field using Particle Image Velocimetry (PIV). Using in-house software, it was possible to conclude that for an increase in pulsation frequency or alternatively in the flow rate, the stagnation zones were reduced in size, the distribution of vortices became more homogeneous over the considered domain, and the number of vortices in all scales had increased. Considering the occupied region, the stagnation zones were moved away in a favorable direction from a mixing point of view. In addition, statistical analysis unveiled that in the far-field occupied region of the room model, stronger eddies were developed that we could expect to give rise to improved mixing. As a fundamental experimental study performed in a 2D, small-scale room model with water as operating fluid, we can logically conclude that the positive effect of enhanced mixing through increasing the flow rate could equally be accomplished through applying a pulsating inflow.

In addition, this thesis introduces and describes an experimental setup for study of air flow over a wall-mounted radiator in a mockup of a real room, which has been successfully designed and manufactured. In this experimental study, the airflow over an electric radiator without forced convection, a common room-heating technique, was measured and visualized using the 2D PIV technique. Surface blackening due to particle deposition calls for monitoring in detail the local climate over a heating radiator. One mechanism causing particle deposition is turbophoresis, which occurs when the flow is turbulent. Because turbulence plays a role in particle deposition, it is important to identify where the laminar flow over radiator becomes turbulent. The results from several visualization techniques and PIV measurements indicated that for a room with typical radiator heating, the flow over the radiator became agitated after a dimensionless length, 5.0–6.25, based on the radiator thickness.

Surface properties are among the influencing factors in particle deposition; therefore, the geometrical properties of different finishing techniques were investigated experimentally using a structured light 3D scanner that revealed differences in roughness among different surface finishing techniques. To investigate the resistance to airflow along the surface and the turbulence generated by the surfaces, we recorded the boundary layer flow over the surfaces in a special flow rig, which revealed that the types of surface finishing methods differed very little in their resistance and therefore their influence on the deposition velocity is probably small. 

Abstract [sv]

Det övergripande syftet med den första studien i avhandlingen var att undersöka hypotesen att ett pulserande inflöde till ett ventilerade utrymme har en potential till att förbättra ventilationens kvalitet genom att minska stagnationszoner och därigenom öka omblandningen. För genomförande av studien byggdes en experimentuppställning i form av en tvådimensionell (2D) småskalig modell av ett ventilerat rum. Strömningsmediet i modellen var vatten. Det tvådimensionella hastighetsfältet registrerades över hela modellen med hjälp av Particle Image Velocimetry (PIV). Vid ett stationärt tillflöde bildas ett stagnationsområde i centrum av rumsmodellen. Vid ett pulserade inflöde genererades sekundära virvlar. Med en egen utvecklad programvara var det möjligt att kvantifiera statistiken hos virvlarna. Det pulserade inflödet gjorde att inom området där det vid stationärt tillflöde fanns en stagnationszon ökade antalet virvlar i alla storlekar och fördelningen av virvlar blev mera homogen än tidigare. Detta kan förväntas ge upphov till förbättrad omblandning. Baserat på en grundläggande experimentell studie utförd i en småskalig tvådimensionell rumsmodell med vatten som strömningsmedium kan vi logiskt dra slutsatsen att ett pulserande tilluftsflöde har en potential att förbättra omblandningen. 

I en fortsatt studie i avhandlingen visuliserades och mättes hastighetsfältet och därefter beräknades statistiska värden av exempelvis medelhastighet, standardavvikelse och skjuvspänning hos hastighetsfluktuationerna i luftströmmen över en väggmonterad radiator med 2D-PIV-teknik.  Bakgrunden till studien är att en bidragande orsak till partikelavsättning på väggytor är turbofores som uppträder vid en turbulent luftström. Studien genomfördes genom uppbyggnad av en fullskalig rumsmodell. Eftersom turbulens spelar en roll vid partikelavsättning genom turbofores är det viktigt att identifiera var det laminära flödet över radiatorn blir turbulent. Resultaten baserat på visualisering och PIV-mätningar indikerade att, för ett rum med denna typ av radiatoruppvärmning, blev flödet över radiatorn turbulent efter en dimensionslös längd lika med 5,0‒6,25 gånger radiatorns tjocklek.

Ytors egenskaper är viktiga vid partikelavsättning. Därför har de geometriska egenskaperna hos några olika metoder för ytbehandling undersökts experimentellt med hjälp av en scanner för strukturerat 3D-ljus. Resultaten visar på skillnader i ytråhet hos de olika ytbehandlingsmetoderna. För att undersöka motståndet mot luftströmning längs ytan och den turbulens som genereras av ytorna registrerade vi gränsskiktsflödet över ytorna i en speciell luftströmningsrigg. Detta påvisade att motståndet hos de olika typerna av ytbehandlingsmetoder skilde sig mycket litet åt och därför är troligt vid deras påverkan på depositionshastigheten mycket liten. 

Place, publisher, year, edition, pages
Stockholm: KTH Royal Institute of Technology, 2015. p. 38
Series
TRITA-IES ; 2015:2
Keywords
Particle Image Velocimetry (PIV), experimental study, structured light 3D scanning system, ventilation, varying flow rate, room model, wall-mounted radiator, air, water, flow, Particle Image Velocimetry (PIV), experimentell studie, scanningsystem för strukturerat 3D-ljus, ventilation, varierande tilluftsflöde, rumsmodell, väggmonterad radiator
National Category
Other Engineering and Technologies not elsewhere specified Civil Engineering Mechanical Engineering
Research subject
Engineering Mechanics; Civil and Architectural Engineering; Energy Technology
Identifiers
urn:nbn:se:oru:diva-82960 (URN)978-91-7595-600-8 (ISBN)
Public defence
2015-06-10, Hall F3, Lindstedtsvägen 26, KTH, 15:40 (English)
Opponent
Supervisors
Available from: 2020-11-10 Created: 2020-06-11 Last updated: 2020-11-10Bibliographically approved
Sattari, A. (2015). Particle Image Velocimetry Visualization and measurement of Airflow over a Wall-Mounted Radiator. The International Journal of Ventilation, 14(3), 289-302
Open this publication in new window or tab >>Particle Image Velocimetry Visualization and measurement of Airflow over a Wall-Mounted Radiator
2015 (English)In: The International Journal of Ventilation, ISSN 1473-3315, E-ISSN 2044-4044, Vol. 14, no 3, p. 289-302Article in journal (Refereed) Published
Abstract [en]

A common room-heating technique involves the use of a wall-mounted radiator without forced convection. The cold surrounding air passes adjacent to the warm surfaces of the radiator where it absorbs heat and gains momentum to rise along the wall surface and finally circulate in the entire room. Understanding the properties of heated airflows is important for several purposes. To understand the flow process it is important to identify where the transition from laminar to turbulent flow occurs and to quantify the turbulent fluctuations. With the objective to characterize the airflow in the vicinity of wall surfaces, the local climate over the radiator was visualized and measured using a two-dimensional particle image velocimetry technique. The PIV technique yields 2D vector fields of the flow. The resulting vector maps were properly validated and post-processed using in-house software to provide the average streamlines and other statistical information such as standard deviation, average velocity, and covariance of the entire vector field. The results show that, for a room with a typical heating power, the airflow over the radiator becomes agitated after an ordinate of N = 5 - 6.25 over the radiator upper level, in which N is the dimensionless length based on the thickness of the radiator. Practical problems encountered in near-wall PIV measurements include generating a homogeneous global seeding that makes it possible to study both plume and entraining region, as well as optical problems due to near-surface laser reflection that makes the measurement process more complicated.

Place, publisher, year, edition, pages
Taylor & Francis, 2015
Keywords
Air circulation, Airflow, Heating radiator, Particle image velocimetry (PIV), Turbulence, Velocity field
National Category
Other Engineering and Technologies not elsewhere specified
Identifiers
urn:nbn:se:oru:diva-82959 (URN)10.1080/14733315.2015.11684087 (DOI)2-s2.0-84951072805 (Scopus ID)
Funder
Swedish Energy Agency, 2011-002440
Available from: 2015-05-25 Created: 2020-06-11 Last updated: 2020-08-17Bibliographically approved
Sattari, A. & Sandberg, M. (2014). Particle Image Velocimetry (PIV) visualization of air flow over a wall-mounted radiator. In: : . Paper presented at ROOMVENT, 13th SCANVAC International Conference on Air Distribution in Rooms, São Paulo, Brazil, October 19-22, 2014..
Open this publication in new window or tab >>Particle Image Velocimetry (PIV) visualization of air flow over a wall-mounted radiator
2014 (English)Conference paper, Published paper (Refereed)
Abstract [en]

A common room heating technique is to use a wall-mounted radiator without forced convection. The cold surrounding air passes adjacent to the warm surfaces of the radiator, gets heated, and the buoyancy difference gives this heated air a momentum to rise along the wall surface (as plume) and finally circulate and get mixed into the whole room. The properties of heated plumes are important for assessing the risk of soiling of the wall surfaces through particle deposition driven by thermophoresis and turbophoresis. It is important to identify where there is a transition from laminar to turbulent flow. With the objective to characterize the plume of heated air flow in the vicinity of wall surface, the airflow over the radiator is visualized and measured using the two-dimensional Particle Image Velocimetry (2D PIV) technique. The PIV technique yields two-dimensional vector fields of the flow. The resulted vector maps are size and peak validated and post processed using in house developed software to provide the average streamlines. In the near wall PIV measurements there are practical problems; generating a homogeneous global seeding that makes it possible to study both the plume and the surrounding entrainment region, and optical problems due to strong laser reflection from the wall surface which limits the investigation area. These issues are dealt with in the present study. In addition to visualization with PIV, visualization with a CMOS video camera was also conducted.

Keywords
radiator, PIV, thermophoresis, turbophoresis, visualization
National Category
Other Engineering and Technologies not elsewhere specified
Identifiers
urn:nbn:se:oru:diva-82961 (URN)
Conference
ROOMVENT, 13th SCANVAC International Conference on Air Distribution in Rooms, São Paulo, Brazil, October 19-22, 2014.
Note

QC 20140828

Available from: 2014-08-13 Created: 2020-06-11 Last updated: 2023-05-29Bibliographically approved
Fallenius, B. E. G., Sattari, A., Fransson, J. H. M. & Sandberg, M. (2013). Experimental study on the effect of pulsating inflow to an enclosure for improved mixing. International Journal of Heat and Fluid Flow, 44, 108-119
Open this publication in new window or tab >>Experimental study on the effect of pulsating inflow to an enclosure for improved mixing
2013 (English)In: International Journal of Heat and Fluid Flow, ISSN 0142-727X, E-ISSN 1879-2278, Vol. 44, p. 108-119Article in journal (Refereed) Published
Abstract [en]

Optimal control of inlet jet flows is of broad interest for enhanced mixing in ventilated rooms. The general approach in mechanical ventilation is forced convection by means of a constant flow rate supply. However, this type of ventilation may cause several problems such as draught and appearance of stagnation zones, which reduces the ventilation efficiency. A potential way to improve the ventilation quality is to apply a pulsating inflow, which has been hypothesised to reduce the stagnation zones due to enhanced mixing. The present study aims at testing this hypothesis, experimentally, in a small-scale two-dimensional water model using Particle Image Velocimetry with an in-house vortex detection program. We are able to show that for an increase in pulsation frequency or alternatively in the flow rate the stagnation zones are reduced in size and the distribution of vortices becomes more homogeneous over the considered domain. The number of vortices (all scales) increases by a factor of four and the swirl-strength by about 50% simply by turning on the inflow pulsation. Furthermore, the vortices are well balanced in terms of their rotational direction, which is validated by the symmetric Probability Density Functions of vortex circulation (Γ) around Γ= 0. There are two dominating vortex length scales in the flow, namely 0.6 and 0.8 inlet diameters and the spectrum of vortex diameters become broader by turning on the inflow pulsation. We conclude that the positive effect for enhanced mixing by increasing the flow rate can equally be accomplished by applying a pulsating inflow.

Place, publisher, year, edition, pages
Elsevier, 2013
Keywords
Pulsating flow, Room ventilation, Vortex statistics, Wall-jet instability, Kelvin-Helmholtz instability, Roll-up of vortices
National Category
Fluid Mechanics and Acoustics
Identifiers
urn:nbn:se:oru:diva-82964 (URN)10.1016/j.ijheatfluidflow.2013.05.004 (DOI)000329594600009 ()2-s2.0-84888432075 (Scopus ID)
Funder
Swedish Research CouncilGöran Gustafsson Foundation for promotion of scientific research at Uppala University and Royal Institute of TechnologyUniversity of Gävle
Note

QC 20140122

Available from: 2014-01-22 Created: 2020-06-11 Last updated: 2021-04-13Bibliographically approved
Sattari, A. & Sandberg, M. (2013). PIV Study of Ventilation Quality in Certain Occupied Regions of a Two-Dimensional Room Model with Rapidly Varying Flow Rates. The International Journal of Ventilation, 12(2), 187-194
Open this publication in new window or tab >>PIV Study of Ventilation Quality in Certain Occupied Regions of a Two-Dimensional Room Model with Rapidly Varying Flow Rates
2013 (English)In: The International Journal of Ventilation, ISSN 1473-3315, E-ISSN 2044-4044, Vol. 12, no 2, p. 187-194Article in journal (Refereed) Published
Abstract [en]

The use of supply jet flows is the most common type of air distribution for general ventilation. Usually the supply flow rate is constant or slowly varying (VAV-systems) to cope with a varying load. A novel air distribution method, with the potential to reduce stagnation and to increase the ventilation efficiency, is to introduce rapid flow variations (pulsations). This paper reports on a fundamental study of this type of air distribution. The purpose of the study was to explore the effect of flow variations on stagnant zones and the levels of the turbulent kinetic energy and the relative turbulence intensity. A small scale room model is used that consists of an enclosure with a ventilation supply at the bottom and an extract at the top of the opposite wall. Water was used as an operating fluid and the model had a design which mainly generated a two-dimensional flow. The size of the model made it possible to investigate the two-dimensional velocity vector field using the Particle Image Velocimetry (PIV) method in regions corresponding to occupied regions. Further post processing was conducted from the resulting vector fields. The comparison between cases of constant inflow and pulsated inflow (flow variations with frequency of 0.5 Hz) was conducted for three domains: two belonging to the far-field occupied zone and one belonging to the near-field, downstream of the supply wall jet.

Place, publisher, year, edition, pages
Taylor & Francis, 2013
Keywords
PIV, ventilation, varying flow rate, flow pulsation, room model
National Category
Building Technologies
Identifiers
urn:nbn:se:oru:diva-82962 (URN)000329605700011 ()
Available from: 2013-09-10 Created: 2020-06-11 Last updated: 2020-08-17Bibliographically approved
Sandberg, M., Sattari, A. & Mattsson, M. (2013). Plaster finishes in historical buildings: Measurements of surface structure, roughness parameters and air flow characteristics. In: A. Troi and E. Luchi. (Ed.), Conference proceedings: Cultural heritage preservation – 3rd European Workshop on Cultural Heritage Preservation. Paper presented at 3rd European Workshop on Cultural Heritage Preservation (EWCHP), Bozen, Italy, September 15-17, 2013. (pp. 69-75).
Open this publication in new window or tab >>Plaster finishes in historical buildings: Measurements of surface structure, roughness parameters and air flow characteristics
2013 (English)In: Conference proceedings: Cultural heritage preservation – 3rd European Workshop on Cultural Heritage Preservation / [ed] A. Troi and E. Luchi., 2013, p. 69-75Conference paper, Published paper (Refereed)
Abstract [en]

Soiling of surfaces in historical buildings by deposition of particles is a common problem. Minimizing soiling is an important goal for conservation of structures and objects. The surfaces give rise to an interference with the air motions along the surfaces. Properties of surfaces may therefore influence the particle deposition. It is well known that with increasing roughness of the surfaces the particle deposition rate increases. The properties of surfaces in historical buildings are not well documented.  We have investigated samples of surfaces finished by wood float finish, steel float finish and brushed finish. As a reference we have used an MDF board. The geometrical properties of the surfaces have been documented by using the stripe projection method. The resistance to airflow along the surface and the turbulence generated by the surfaces has been investigated by recording the boundary layer flow over the surfaces in a special flow rig. The work reported is part of a project where the process of soiling is studied both in laboratory and in field studies. The air velocity adjacent to the surfaces will be recorded with both PIV (Particle Image Velocimetry) and hot-wire technique. The temperature gradient close to the walls will be recorded with cold-wire technique.

Keywords
Soiling, Plasters, Particle deposition, Surface structure, Surface roughness, Churches
National Category
Building Technologies
Identifiers
urn:nbn:se:oru:diva-82963 (URN)978-88-88307-26-8 (ISBN)
Conference
3rd European Workshop on Cultural Heritage Preservation (EWCHP), Bozen, Italy, September 15-17, 2013.
Projects
Church project
Funder
Swedish Energy Agency, 2011-002440
Available from: 2013-09-24 Created: 2020-06-11 Last updated: 2020-08-17Bibliographically approved
Organisations
Identifiers
ORCID iD: ORCID iD iconorcid.org/0000-0003-2421-7792

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