Structural health assessment of a historical building by using in situ stress wave NDT: a case study in Iran

Madhoushi, Mehrab; Ebrahimi, Saeideh; Omidvar, Asghar

doi:10.1590/01047760202127012535

ABSTRACT

Background:

Many historical buildings in Iran need to be protected. In many of these buildings, wood is used as a structural element in features such as beam, pile, roof and floor systems. For this purpose, the architectural features of a historical building located in Gorgan (Northern part of Iran) and characterisation of faults, in addition to identification of wood species were conducted. Stress wave non-destructive testing (NDT) was used and wave speed (WS) was measured in tested members to evaluate the decay situation of major wooden beams of building frames and roof truss. After obtaining data related to WS, time of wave transition (TWT) was calculated and compared with control time. Structural elements were characterized in comparison with control time and classified according to decay severity.

Results:

The results showed that local hardwood species were used for construction of this building. Furthermore, in some parts of the building, there were severely defected structures, thus highlighting the importance of safety. Moreover, WS strongly depended on the types of faults.

Conclusion:

Due to high relative humidity of climate, wood structures are exposed to faults in the northern region of Iran. However, their general appearance is adequate and acceptable. For better decision making, the TWT should be accompanied by more investigation into the types of defects.

Keywords:
Historical building; Non-destructive Testing; Stress wave; Structural health assessment; Testing of materials; Timber structures

INTRODUCTION

There are many historical buildings in Iran whose protection is important from the cultural and tourism points of view. Wood is an important structural element in most of these buildings as it is used in the construction of beams, pile, roof and floor systems (Branco and Guerreiro, 2011BRANCO, M.; GUERREIRO, L. M. Seismic rehabilitation of historical masonry buildings. Engineering Structures, v. 33, n. 5, p. 626-1634, 2011. ; Madhoushi, 2016MADHOUSHI, M. Species and mechanical strengths of wood members in a historical timber building in Gorgan (North of Iran). BioResources, v. 11, n. 2, p. 5169-5180, 2016., Imanian et al. 2019IMANIAN, J.; ABOUEI, R.; MADHOUSHI, M. Recognition of indigenous knowledge in wooden house of Ziarat village and it’s role in native sustainable development. Indigenous Knowledge, v. 5, n. 10, p. 103-150, 2019. ). Although these historical buildings survived previous severe earthquakes, they are still in appropriate and acceptable conditions. This is as a result of the nature of wood materials used as loading structural member which could absorb and dissipate the energy of earthquakes (D’Ayala and Tsai, 2008; Li et al., 2015LI, X.; ZHAO, J.; MA, G,; CHEN, W. Experimental study on the seismic performance of a double-span traditional timber frame. Engineering Structures , v. 98, n. 1., p. 141-150, 2015. ; Madhoushi and Ansell, 2008; Parisi and Piazza, 2015PARISI, M. A.; PIAZZA, M. Seismic strengthening and seismic improvement of timber structures. Construction and Building Materials , v. 97, p. 55-66, 2015. ; Vieux-Champagne et al., 2014). Loading structural members ensure that earthquakes do not result in serious failure while the brick and crobe parts in shear walls have been damaged and failed (Elmenshawi et al., 2010ELMENSHAWI, a.; SOROUR, m.; MUFTI, a.; JAEGER, l. g.; SHRIVE, n. In-plane seismic behaviour of historic stone masonry. Canadian Journal of Civil Engineering, v. 37, n. 3, p. 465-476, 2010.; Simões et al., 2014SIMÕES, A.; BENTO, R.; CATTARI, S.; LAGOMARSINO, S. Seismic performance-based assessment of “Gaioleiro” buildings. Engineering Structures , v. 80, p. 486-500, 2014. ; Vieux-Champagne et al., 2014). It should be noted that despite the survival of historical buildings under previous seismic loading, they have been exposed to ruin and destruction due to several geographical and environmental reasons (Bosiljkov et al., 2010BOSILJKOV, V.; URANJEK, M.; ŽARNIĆ, R.; BOKAN-BOSILJKOV V. An integrated diagnostic approach for the assessment of historic masonry structures. Journal of Cultural Heritage, v. 11, n. 3, p. 239-249, 2010. ; Phillips and Stein, 2013PHILLIPS, R. G., STEIN, J. M. An indicator framework for linking historic preservation and community economic development. Social Indicators Research, v. 113, p. 1-15, 2013. ; Yung and Chan, 2012YUNG, E. H. K.; CHAN, E. H. W. Implementation challenges to the adaptive reuse of heritage buildings: Towards the goals of sustainable, low carbon cities. Habitat International, v. 23, n. 3, p. 352-361, 2012.). For this reason, the evaluation and preservation of wooden parts of traditional buildings are critical and important when there is a serious and scientific plan for their repair and rehabilitation (Cruz et al., 2015CRUZ, H.; YEOMANS, D.; TSAKANIKA, E.; MACCHIONI, N.; JORISSEN, A.; TOUZA, M.; MANNUCCI, M.; LOURENÇO, P. B. Guidelines for on-site assessment of historic timber structures. International Journal of Architectural Heritage, v. 9, n. 3, p. 277-289, 2015. ; Nowak et al., 2013NOWAK, T. P.; JASIEŃKO, J.; CZEPIŻAK, D. Experimental tests and numerical analysis of historic bent timber elements reinforced with CFRP strips. Construction and Building Materials , v. 40, p. 97-206, 2013. ).

For repair and rehabilitation purposes, some damages cannot be seen during visual inspections. Therefore, in order to evaluate internal defects, employing a quick, efficient and economical method is necessary (Avrami, 2016AVRAMI, e. Making historic preservation sustainable. Journal of the American Planning Association, v 82, n. 2, p. 104-112, 2016. ; Branco and Guerreiro, 2011BRANCO, M.; GUERREIRO, L. M. Seismic rehabilitation of historical masonry buildings. Engineering Structures, v. 33, n. 5, p. 626-1634, 2011. ; Vicente et al., 2011VICENTE, R.; PARODI, S.; LAGOMARSINO, S.; VARUM, H.; SILVA, J. A. R. M. Seismic vulnerability and risk assessment: Case study of the historic city centre of Coimbra, Portugal. Bulletin of Earthquake Engineering, v. 9, n. 4, p.1067-1096, 2011. ).

Health assessments of wood buildings may be conducted with several non-destructive testing (NDT) methods, including X-ray (Yokoyama et al., 2009), FT-Raman spectroscopy (Moosavinejad et al. 2019MOOSAVINEJAD, S. M.; MADHOUSHI, M.; VAKILI, M.; RASOOLI, D. Evaluation of degradation in chemical compounds of wood in historical buildings using FT-IR and FT-Raman vibrational spectroscopy. Maderas. Ciencia y tecnología, v. 21, n. 3, p. 381-392, 2019.), pilodyn and resistograph (Branco et al., 2010BRANCO, J. M.; PIAZZA, M.; CRUZ P. J. S. Structural analysis of two king-post timber trusses: Non-destructive evaluation and load-carrying tests. Construction and Building Materials, v. 24, n. 3, p. 371-383, 2010. ; Calderoni et al., 2010CALDERONI, C.; DE MATTEIS, G.; GIUBILEO, C.; MAZZOLANI, F. M. Experimental correlations between destructive and non-destructive tests on ancient timber elements. Engineering Structures , v. 32, n. 2, p. 442-448, 2010.), stress wave (Ross et al., 2006) and ultrasonic (Cabaleiro et al., 2017CABALEIRO, M.; LINDENBERGH, R.; GARD, W. F.; ARIAS, P.; VAN DE KUILEN, J. W. G. Algorithm for automatic detection and analysis of cracks in timber beams from LiDAR data. Construction and Building Materials , v. 130, n. 15, p. 41-53, 2017. ) methods. All these methods may be capable of determining the density and internal conditions of wooden beam structures; however, each has its advantages and disadvantages. Among these methods, the stress wave method has more potential to determine the Young’s modulus of elasticity (Kloiber et al., 2015KLOIBER, m.; DRDÁCKÝ, m.; MACHADO, j. s.; PIAZZA, m.; YAMAGUCHI, n. Prediction of mechanical properties by means of semi-destructive methods: A review. Construction and Building Materials , v. 101, n. 2, p. 1215-1234, 2015. ; Yamasaki and Sasaki, 2010YAMASAKI, M., SASAKI, Y. Determining Young’s modulus of timber on the basis of a strength database and stress wave propagation velocity I: An estimation method for Young’s modulus employing Monte Carlo simulation. Journal of Wood Science, v. 56, n. 4, p. 269-275, 2010. ) and thus provides more valid results. The stress wave method is a more commercial (Dackermann et al., 2014DACKERMANN, u; CREWS, k.; KASAL, b; LI, j.; RIGGIO, m.; RINN, f.; TANNERT, t. In situ assessment of structural timber using stress-wave measurements. Materials and Structures, v. 47, n. 5, p. 787-803, 2014. ; Ross et al., 2005) and helpful tool for the in situ investigation of buildings as it exhibits low possible errors in comparison with other methods. Despite the longer time required for its use, it is simple and easy to use; without need for any special arrangement.

Although health assessment of wooden buildings using stress wave NDT has been reported by numerous researches, it is difficult to find any clear protocol and guideline/manual among these studies (Riggio et al., 2014RIGGIO, M.; ANTHONY, R. W.; AUGELLI, F.; KASAL, B.; LECHNER, T.; MULLER, W.; TANNERT, T. In situ assessment of structural timber using non-destructive techniques. Materials and Structures , v. 47, n. 5, p. 749-766, 2014. ). In other words, stress wave NDT is the same for all studies, but the method and strategy for evaluation and also relevant calculations vary from one study to another. Hence, presenting a global or local standard protocol is required for these types of studies.

The aim of this study was to undertake the in situ evaluation of structural wood member in a historical building (Reza-Nejad) in Gorgan, Northern Iran using stress wave non-destructive testing (NDT). The Reza-Nejad was built approximately 80 years ago. This study is the second one after that conducted by (Madhoushi, 2016MADHOUSHI, M. Species and mechanical strengths of wood members in a historical timber building in Gorgan (North of Iran). BioResources, v. 11, n. 2, p. 5169-5180, 2016.) on the use of non-destructive testing (NDT) for the investigation and health assessment of historical wooden buildings in Iran.

MATERIAL AND METHODS

Architectural and structural features

The architectural and structural features of building were visually investigated and detected followed by the drawing of general plans from different geographical views. In accordance with recommendations from previous studies and also the Cultural Heritage Organization (CHO) of Iran, several high quality photos of the building were taken from the building (Fig. 1a), in addition to various plans and profiles drawn with the use of AutoCAD software. Then each of the photographs taken from the main entrance was labelled by a distinct ID code as: A) for East plan, B) for North plan, C1) for West plan ground floor, C2) for West first floor, D) for South plan and, TB) for Truss of B section (Fig. 1b).

Fig. 1
a) A view of the building, b) Plan of the building.

Faults and wood species identification

All wooden parts of the building were visually investigated. Type and location of observed defects were marked with distinct codes on drawn plans. Also, wood types used in construction were identified in the laboratory at macroscopic and microscopic levels (Parsapajouh, 1988PARSAPAJOUH D. Atlas of wood grown in north of Iran. Tehran University Publication, 1988.). The moisture content of all the tested parts were measured by means of a portable electrical moisture meter.

Stress wave measurement

The main wooden beams of the building frame and roof truss were evaluated by stress wave NDT instrument (IML) and the wave speed (WS) was measured longitudinally (and perpendicular to grain for some rare members of truss). For this purpose, each member was tested and scanned at every 50 cm distance to obtain the best results (Fig. 2).

Fig. 2
WS measurement in a) wood beam, b), c) and d) truss.

After obtaining data relevant to WS, time of wave transition (TWT) was calculated and compared with baseline (control) time, according to the following equation (Eq. 1) as suggested by (Ross, 2015ROSS, R. J. Nondestructive Evaluation of Wood: Second edition. General Technical Report, FPL-GTR-238. USDA Forest Service, Forest Products Laboratory, 2015.), Where, T_baseline is the control time (µs), WTD is the sensors distance (m).

T_{b a s e l i n e} = 1300 x W T D

(1)

If the time of wave in samples is lower than the baseline, it implies that the sample should be considered a sound member. Conversely, if the TWT is higher than the baseline, it means that the sample should be considered a defective member. In addition, the level of defect in each section of members was calculated using Eq. 2 (Ross, 2015ROSS, R. J. Nondestructive Evaluation of Wood: Second edition. General Technical Report, FPL-GTR-238. USDA Forest Service, Forest Products Laboratory, 2015.) in order to distinguish and classify the wooden parts by severity of defect, where, T is the calculated time (µs).

D e f e c t (%) = \frac{T - T_{b a s e l i n e}}{T_{b a s e l i n e}} \times 100

(2)

RESULTS

Architectural and structural characteristics

The house has a floor area of 675 m² and is currently under repair. This structure is a one-storey building, excluding the western part (ID code C1 and C2) which is a two-storey building with steps between the floors (Fig. 1a).

In this building, there is evidence of Islamic art (like the dome shaped window). Due to their special design, there is weak ventilation which in turns provides a more humid environment inside the building. The structures are rectangular and solid wood was utilized for the construction of loading structural members, such as beams, rafters, roofs, and floors in association with other traditional and masonry construction methods. The doors and windows are completely wooden and well preserved.

The average moisture content was measured in members was between 8 and 11%; however, in truss it was 1-2% more due to low ventilation.

Source of faults

The causes of faults were determined as weathering, fungus and insect attacks, surface and deep cracks on wooden members (Fig. 3). The color of the wood surface changed to dark brown and grey because of the action of various agents. Distinguishing faults were conducted separately at each 50 cm length in parts A, B, C1, C2, D and TB. Tab. 1 shows a summary of the types and total percentages of faults in the all parts of investigated members.

Fig. 3
Source of faults in wood members as a) weathering, b) fungus c)insect and d) cracks.

Thumbnail

Tab. 1
Types and percentages of faults in wooden members.

Wood species

Microscopic identification of samples showed that the load bearing wooden parts of the building were made of hardwood species native to the northern region of Iran including oak (Quercus castaneaefolia), lime tree (Tilia begonifolia), acer (Acer insigne), and beech (Fagus orientalis). Fig. 4 and 5 show the microscopical sample for transverse and tangential sections, respectively. The location of wood species in the building is shown in Fig.6 and Tab. 2.

Fig. 4
Microscopical samples of old wood compared with typical ones in cross section.

Fig. 5
Microscopical samples of old wood compared with typical ones in tangential section.

Fig. 6
Main plans of four sections of buildings and wood beams in a) A, b) B, c) C, and d) D (see for more details).

Thumbnail

Tab. 2
Position of wood samples in building, and average of WS and TWT.

WS, TWT and faults

Tab. 2 shows the average WS for main beams and truss. The WS and the TWT in wood beam and truss are shown in Fig. 7, 8, 9 and 10, for each sample. The results indicated a low WS, mostly at the two ends of members, where insects’ holes and decayed parts were most visible.

Fig. 7
WS in wood beam a) A, b) B, c) C, and d) D (see for more details).

Fig. 8
WS in wood of truss (see for more details).

Fig. 9
TWT (µs) in wood beam a) A, b) B, c) C, and d) D (see and for more details).

Fig. 10
TWT (µs) in wood of truss (see for more details).

Furthermore, the results revealed that the WS is higher in sound members as compared with decayed ones. In addition, in members exposed to insects’ attacks, humidity penetration and tensions caused by loading, more severe destruction was observed than in other members. More severe destructions were also observed in parts that were exposed to regional wind.

TWT in all studied members in comparison with control time are shown in Fig. 11. Deeper investigation of those parts in which the TWT were higher than the baseline showed that the defects were mostly color changes and large cracks and/or knots. In other words, large cracks and knows were dominant defects in these areas. However, with lower TWT, the dominant defects were mainly color changes.

Fig. 11
TWT in all studied members in comparison with control time (baseline).

DISUSSION

The building has identical architectural characteristics which are somehow similar to other typical historical buildings in Gorgan (Madhoushi, 2016MADHOUSHI, M. Species and mechanical strengths of wood members in a historical timber building in Gorgan (North of Iran). BioResources, v. 11, n. 2, p. 5169-5180, 2016.). Solid wood, of hardwood species native to Iran, was extensively utilized for the construction of loading structural members in association with other masonry construction methods. Besides inherent defects in the wooden parts, such as knots and spiral grain, different faults were observed as weathering, fungus and insect attacks mainly in parts A and B of buildings, which is consistent with (Cruz et al., 2015CRUZ, H.; YEOMANS, D.; TSAKANIKA, E.; MACCHIONI, N.; JORISSEN, A.; TOUZA, M.; MANNUCCI, M.; LOURENÇO, P. B. Guidelines for on-site assessment of historic timber structures. International Journal of Architectural Heritage, v. 9, n. 3, p. 277-289, 2015. ).

The results of this study is in agreement with previous ones by (Dackermann et al.; 2014DACKERMANN, u; CREWS, k.; KASAL, b; LI, j.; RIGGIO, m.; RINN, f.; TANNERT, t. In situ assessment of structural timber using stress-wave measurements. Materials and Structures, v. 47, n. 5, p. 787-803, 2014. , Ross, 2015ROSS, R. J. Nondestructive Evaluation of Wood: Second edition. General Technical Report, FPL-GTR-238. USDA Forest Service, Forest Products Laboratory, 2015.); which indicated that stress wave passes more rapidly through intact samples than decayed. This difference was used as a key to distinguish sound parts from defected ones. Moreover, the results indicated that the parts affected by moisture penetration and extensive loading exhibited more severe decays and faults compared to other parts and thus showed more destruction (Riggio et al., 2014RIGGIO, M.; ANTHONY, R. W.; AUGELLI, F.; KASAL, B.; LECHNER, T.; MULLER, W.; TANNERT, T. In situ assessment of structural timber using non-destructive techniques. Materials and Structures , v. 47, n. 5, p. 749-766, 2014. ). This finding should be considered for in situ investigation of timber buildings.

Moreover, the finding revealed that the WS wave should be considered and compared with the types of defects of area, especially with cracks and knots as Fig. 12 shows. This figure demonstrates these findings as a general pattern. These findings were not reported by previous investigations, as WS has majorly been used as an indicator and method of identification of defects without types of faults.

Fig. 12
Types of defects in comparison with control time (baseline).

With regards to defect percentages, in general, member D showed severe and critical decayed parts in some sections, for example: 87, 174, 384 and 424%.. Other members showed lower defect percentages.

CONCLUSIONS

Due to high relative humidity of climate, wood structures are exposed to faults in the northern region of Iran. However, their general appearance is adequate and acceptable. Wooden parts of the studied house suffered color alteration as well as fungus and insect attacks. TWT in wooden parts is dependent on the defect amount, thus, stress wave would move faster in healthy wooden parts than in destroyed ones. In some parts, there were severe defective members which are very critical from a safety point of view. The results indicated that for better decision making, the TWT should be accompanied by more investigation into the types of defect, especially in those parts where TWT are higher than control time.

ACKNOWLEDGEMENTS

The authors gratefully acknowledges the financial support from the research deputy of Gorgan University of Agricultural Sciences and Natural Resources, and official support from the Cultural Heritage Organization of Iran

REFERENCES

AVRAMI, e. Making historic preservation sustainable. Journal of the American Planning Association, v 82, n. 2, p. 104-112, 2016.
BOSILJKOV, V.; URANJEK, M.; ŽARNIĆ, R.; BOKAN-BOSILJKOV V. An integrated diagnostic approach for the assessment of historic masonry structures. Journal of Cultural Heritage, v. 11, n. 3, p. 239-249, 2010.
BRANCO, J. M.; PIAZZA, M.; CRUZ P. J. S. Structural analysis of two king-post timber trusses: Non-destructive evaluation and load-carrying tests. Construction and Building Materials, v. 24, n. 3, p. 371-383, 2010.
BRANCO, M.; GUERREIRO, L. M. Seismic rehabilitation of historical masonry buildings. Engineering Structures, v. 33, n. 5, p. 626-1634, 2011.
CABALEIRO, M.; LINDENBERGH, R.; GARD, W. F.; ARIAS, P.; VAN DE KUILEN, J. W. G. Algorithm for automatic detection and analysis of cracks in timber beams from LiDAR data. Construction and Building Materials , v. 130, n. 15, p. 41-53, 2017.
CALDERONI, C.; DE MATTEIS, G.; GIUBILEO, C.; MAZZOLANI, F. M. Experimental correlations between destructive and non-destructive tests on ancient timber elements. Engineering Structures , v. 32, n. 2, p. 442-448, 2010.
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LI, X.; ZHAO, J.; MA, G,; CHEN, W. Experimental study on the seismic performance of a double-span traditional timber frame. Engineering Structures , v. 98, n. 1., p. 141-150, 2015.
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YUNG, E. H. K.; CHAN, E. H. W. Implementation challenges to the adaptive reuse of heritage buildings: Towards the goals of sustainable, low carbon cities. Habitat International, v. 23, n. 3, p. 352-361, 2012.

HIGHLIGHTS

0
Stress wave method was employed for assessment of wood members in a historical building in Iran.
2
The times of wave transition in wood members were compared with the control value.
3
Identification of wood species of building were conducted.
4
Stress wave speed strongly depended on the types of faults.

Publication Dates

Publication in this collection
02 July 2021
Date of issue
2021

History

Received
19 Apr 2020
Accepted
06 Oct 2020

/This is an open-access article distributed under the terms of the creative commons attribution license, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AVRAMI, e. Making historic preservation sustainable. Journal of the American Planning Association, v 82, n. 2, p. 104-112, 2016.

[2] BOSILJKOV, V.; URANJEK, M.; ŽARNIĆ, R.; BOKAN-BOSILJKOV V. An integrated diagnostic approach for the assessment of historic masonry structures. Journal of Cultural Heritage, v. 11, n. 3, p. 239-249, 2010.

[3] BRANCO, J. M.; PIAZZA, M.; CRUZ P. J. S. Structural analysis of two king-post timber trusses: Non-destructive evaluation and load-carrying tests. Construction and Building Materials, v. 24, n. 3, p. 371-383, 2010.

[4] BRANCO, M.; GUERREIRO, L. M. Seismic rehabilitation of historical masonry buildings. Engineering Structures, v. 33, n. 5, p. 626-1634, 2011.

[5] CABALEIRO, M.; LINDENBERGH, R.; GARD, W. F.; ARIAS, P.; VAN DE KUILEN, J. W. G. Algorithm for automatic detection and analysis of cracks in timber beams from LiDAR data. Construction and Building Materials , v. 130, n. 15, p. 41-53, 2017.

[6] CALDERONI, C.; DE MATTEIS, G.; GIUBILEO, C.; MAZZOLANI, F. M. Experimental correlations between destructive and non-destructive tests on ancient timber elements. Engineering Structures , v. 32, n. 2, p. 442-448, 2010.

[7] CRUZ, H.; YEOMANS, D.; TSAKANIKA, E.; MACCHIONI, N.; JORISSEN, A.; TOUZA, M.; MANNUCCI, M.; LOURENÇO, P. B. Guidelines for on-site assessment of historic timber structures. International Journal of Architectural Heritage, v. 9, n. 3, p. 277-289, 2015.

[8] D’AYALA, D. F. ; TSAI, P. H. Seismic vulnerability of historic Dieh-Dou timber structures in Taiwan. Engineering Structures , v. 30, n. 8, p. 2101-2113, 2008.

[9] DACKERMANN, u; CREWS, k.; KASAL, b; LI, j.; RIGGIO, m.; RINN, f.; TANNERT, t. In situ assessment of structural timber using stress-wave measurements. Materials and Structures, v. 47, n. 5, p. 787-803, 2014.

[10] ELMENSHAWI, a.; SOROUR, m.; MUFTI, a.; JAEGER, l. g.; SHRIVE, n. In-plane seismic behaviour of historic stone masonry. Canadian Journal of Civil Engineering, v. 37, n. 3, p. 465-476, 2010.

[11] KASAL, b.; ANTHONY, r, w. Advances in in situ evaluation of timber structures. Progress in Structural Engineering and Materials, v. 6, n. 2, p. 94-103, 2004.

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Section	Types of defects (%)
Section	Insect holes	Change of color to grey	Mold	Change of color to dark brown	Check and split
Eastern part (A)	37.5	31.2	37.5	12.5	50
Northern part (B)	69.5	43.4	48	21.7	60
Western part, ground floor (C1)	12.5	43.7	0	62.5	0
Western part, first floor (C2)	0	0	0	0	4
Southern part (D)	90.9	13.6	0	0	50
Truss	70	0	60	100	50

Position	Species	WS (m/s)	TWT (µs)
Eastern part (A)	Oak	2708 (±944)	432.59
Northern part (B)	Oak	2146 (±1033)	780.06
Western part, ground floor (C1)	Oak, Acer	3695 (±577)	278.26
Western part , first floor (C2)	Acer	3848 (±305)	261.44
Southern part (D)	Beech, Basswood	1848 (±1264)	950.23
Truss	Oak	2952 (±637)	671.33

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