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Università degli studi della BasilicataUniversità degli studi della Basilicata
FACOLTÀ FACOLTÀ DIDI INGEGNERIAINGEGNERIA
Corso di Laurea in Ingegneria CivileCorso di Laurea in Ingegneria CivileDipartimento di Architettura, Pianificazione ed Inf rastrutture di TrasportoDipartimento di Architettura, Pianificazione ed Inf rastrutture di Trasporto
CONSTRUCTION OF ROADS, RAILWAYS AND AIRPORTSCONSTRUCTION OF ROADS, RAILWAYS AND AIRPORTS
FinalFinal dissertationdissertation
AntivibrationAntivibration pavements for the protection of histor ical heritage pavements for the protection of historical heritage and public buildingsand public buildings
SUPERVISOR: SUPERVISOR: Ch.moCh.mo Prof. Ing. M. Prof. Ing. M. AgostinacchioAgostinacchio
ASSISTANT SUPERVISORS:ASSISTANT SUPERVISORS:Dott. Ing. G. Dott. Ing. G. CuomoCuomoDott. Ing. M. Dott. Ing. M. VonaVonaDott. Ing. R. Dott. Ing. R. DitommasoDitommaso
CANDIDATE: CANDIDATE: Mario Mario MetastasioMetastasioMatrMatr. 29442. 29442
TargetTarget
� Realization of an antivibration hot-mix pavement to assure :
1) Softening of mechanics waves produced by vehicles
public
historical
nearby buildings such as :
2) Environmental safety ,using:
cultural
generating
RubberRubber matsmats fromfrom recycledrecycled tyrestyres
“noise”
exterior and structural damages
�� The work The work hashas beenbeen developeddeveloped in 5 in 5 stagesstages: :
I)I) ChoiceChoice ofof thethe workingworking sitesite;;
II)II) DesigningDesigning ofof thethe pavementpavement;;
AnalysisAnalysis
III)III) LayingLaying ofof thethe pavementpavement;;
IV)IV) MeasurementsMeasurements anteante--postpost operamoperam;;
V)V) AnalysisAnalysis andand comparisoncomparison ofof measurementsmeasurements anteante--postpost operamoperam..
ElementaryElementary SchoolSchool “San Giovanni “San Giovanni Bosco” Via Verdi, Potenza.Bosco” Via Verdi, Potenza.
I) I) ChoiceChoice ofof the the workingworking site site
Structural characteristics:
- The 40’s;
- Reinforced concrete structure;
- Four floors;
- Rectangular scheme.
II) II) DesigningDesigning ofof the the pavementpavement
� Total gauge of the antivibration pavement: 8,5 cm
BinderBinder,,In hot -mix (4,0cm)
� Overlapping of three layers:
In hot -mix (4,0cm)
Base, Base, in granular mixture (3,0cm)
AntivibrantAntivibrant, in rubber mats (1,5cm)
� Preexisting foundations layer
MaterialsMaterials
� Rubber mat from recycled tyresToTo assureassure the the softeningsoftening ofof the the
oscillationsoscillations generatedgenerated byby a a hittinghitting mass on the mass on the pavementpavement
Length 1,25 mWide 1,00 mGauge 0,015 mDensity 730 Kg/m3
∆ Lnw = 21 dB (UNI 140/8) nudo
ISOLRUBBERISOLRUBBER
Sound-proofnudo ∆ Lnw = 37,5 dB (UNI 140/6) accoppiato
Compressive strength2,4 Kg/cm2 deformazione 10% DIN 53421
Tensile strength4,6 Kg/cm2 DIN EN ISO 1798
Elongation at break 40% DIN EN ISO 1798
Elasticity in compression 27,5 Kg/cm2
Determination of the stress-strain characteristics in the
compression
CC25 = 599 KpaCC40 = 599 KpaCC50 = 599 Kpa
Dynamic stiffness 60 MN/m3
HOTHOT--MIXMIX
� To realize the upper layer “BINDERONE”“BINDERONE”
Project curve
Apertura Vaglia (mm)
40 31,5 22,4 16 11,2 8 5,6 4 2 1 0,1
Curva Progetto 100 100 100 99,47 84,28 80,17 55,26 47,11 32,26 21,98 6,01
Fuso di riferimento Dmax = 16 mm secondo UNI Eni 13108
Apertura setacci (mm) 22,4 16 2 0,063
Passante percentuale 100 100 50 12
Passante percentuale 100 90 10 0
Percentages of use
Percentuage of bitumenRiferita al peso degli
inerti4.80%
Riferita al peso della miscela
4.58%
Fattore correttivo α 0.98
Massa volumica 2.69 Mg/mc
Costante 2.65
Contenuto minimo Percentages of use
Sabbia 0-4 Aggregato 2-8 Aggregato 10-16 Aggregato 14-2236 45 19 0
Contenuto minimo di legante
4.48%
Categoria Bmin 4.4
BITUMINOUS EMULSION
� To improve and assure the cohesion within
Upper Upper layerlayer
LowerLower layerlayer
ANIONIC BITUMINOUS EMULSIONANIONIC BITUMINOUS EMULSION
Carattesristiche Metodo di prova Valori
Contenuto di acqua [%] NF-T 66-023 43<47
Contenuto di fluss. [%] C.N.R. n 100 1<3
Viscosità E a 20 C NF-T 66-020 5<8
Omogeneità a 630 [μ] NF-T 66-016 <0.2
GRANULAR MIXTURE Omogeneità a 160 [µ] NF-T 66-016 <0.25
Sedimentazione a 5 gg. C.N.R. n 124 ≤5
Indice di rottura NF-T 66-017 <98
Carica delle particelle NF-T 66-021 positiva
pH (grado di acidità) procedura interna 10\12
CHARACTERISTICS OFTHE BINDER CHARACTERISTICS OFTHE BINDER Penetrazione a 25 C
[dmm]EN 1426 70<220
Viscosità a 160 C [Pa.s-
1]EN 2595 0.060<0.160
Punto di rammollimento [ C]
EN 1427 35<46
Punto di rottura (Fraass) [ C]
EN 12593 <-10
GRANULAR MIXTURE
� For the lower layer has been used themilled from preexisting pavement
III) Laying of the pavement
� Size of the pavement
� Size of the surface covered in rubber mats
4,55 m
25,00 m4,00 m
20,00 m
LayingLaying stagesstages
� Laying pavement in 7 stages:
1° stage:
� Management of
WorkersWorkers
MachineriesMachineries
2° stage:
� Delimitation of the working area Alternate Alternate closureclosure ofof the the laneslanes
� Delimitation of the area for scarification
3° stage:
� Scarification of the preexisting pavement
Depth: 8,5cm Direction: Via Verdi-Viale Marconi
4° stage:
� Collection and storage of the milled layer on a truck
5° stage:
� Clening-up of the working area and laying of the rubber m ats from recycled tyres
� Size of the area for the rubber mats
4,00m x 20,00m
� Size of the scarificated area
4,55m x 25,00m4,55m x 25,00m
Wide: 4 raws of rubber mats without covering 0,55m To assure softening propertiesLength: 16 raws of rubber mats without covering 5,0 0m
To laying the bituminous emulsion
6° stage:
� Laying of the base layer made of granular mixture
Gauge: 3 cm
Reuse of the milled layer
� sprinkled by workers
� compacted by a roller
� deposited by a digger
77°° stage:stage:
� Laying and compaction of the binder layer (4cm)
� Reopening of the road afterscattering accross the bituminousemulsion by workers
IV) Measurements ante-post operam
DigitalDigital TromometroTromometro
� It measures seismic amplification on surface but for this te st we have used it to measure
the vibrations on a building
Barycenter long side
of the building
North
� Location of the instrument
of the building
Exit of the School
Three electrodynamic sensors (velocimeters N-S, E-W, Z)
GPS system
Acquisition of noise data, amplified and digitized at 24 bit, withprogrammable sampling frequency
512 Hz
Choice of 4 strike points for the hitting mass� Choice of 4 strike points where generating vibrations ant e-post operam
Point 1
Point 2Point 3
In front of the instrument (5,50m)
To the right of the point 1 (5,00m)
To the left of the Point 1 (5,00m)
Point 4In front of the instrument (10,00m)
Generation of the vibrations
� Positioning of the hitting mass and generation of the vibrat ions
Mass: 10 kg Height of fall: 1,10 m
Weight lifting
Positioning
Falling of the mass
V) AnalysisAnalysis and and comparisoncomparison ofof measurementsmeasurements anteante--post post operamoperam ..
� Data analysis throughTime domain
Frequency domain
TIME DOMAIN ANALYSISTIME DOMAIN ANALYSIS
� peak values of the oscillations ante-post operam
FREQUENCY DOMAIN ANALYSISFREQUENCY DOMAIN ANALYSIS
� Spectral parameters Maximum value for Fourier’s spectrum recorded on velocimeter tracks
Fourier’s spectruma area
This analysis has been conducted before and after the layi ng of the pavement
Data Data analysisanalysis usingusing ““MatlabMatlab” (” (MathworksMathworks) software) software
Management of recorded data using
the database of “Grilla” software
Codified file in
file ASCII
� Matlab data analysis in two stages:
11°° stage (stage (TimeTime domain domain analysisanalysis))
Comparison of amplitude of the ascillations in the Time doma in:
< ante-post operam;
< N-S, E-W, Z;
< 4 strike points;
< 10 strikes for each point.
Example
<Records, ante post operam , of the Time domain ana lysis for the first strike,
in strike point 2, in the three directions W-E,N-S e Z.
DAMPING FACTOR(ξ)
Stikes
W-E N-S Z
Ante Post Ante Post Ante Post
1 2,21 4,98 2,42 3,24 4,99 4,48
2 1,87 4,45 3,49 4,62 2,58 3,812 1,87 4,45 3,49 4,62 2,58 3,81
3 1,81 4,12 0,11 3,40 5,74 2,83
4 2,65 3,32 2,12 3,68 4,98 6,14
5 2,60 3,63 2,68 3,45 5,69 5,66
6 2,17 4,16 3,24 3,02 5,78 3,60
7 1,90 5,97 3,27 4,43 4,37 2,46
8 1,92 4,30 2,42 4,28 4,35 5,10
9 1,92 2,46 2,41 3,33 4,77 2,97
10 2,07 4,03 2,82 5,06 5,32 3,50
Mean 2,11 4,14 2,50 3,85 4,86 4,06
STD 0,30 0,94 0,95 0,69 0,96 1,25
<Trend of the peaks of the oscillations, Post/Ante operam ,
In Time domain, for strike points 1,2,3 e 4 in dire ction N-S
2° stage (Frequency domain analysis)
A) Comparison between the amplitudes of the oscillation s in Frequency domain:
Example:
< ante-post operam;
< W-E,N-S,Z;
< 4 strike points;
< 10 strikes for each point.
<Fourier’s <Fourier’s spectraspectra forfor the the oscillationsoscillations, first strike , first strike forfor the strike the strike pointpoint 1 1
<Trend of the peaks of the oscillations, Post/Ante operam ,
in Frequency domain, for strike points 1,2,3,4 in d irection N-S.
B) Comparison between Fourier’s spectra areas:< ante-post operam;
< W-E,N-S,Z;
< 4 strike points;
< 10 strikes for each point.
Example:
<Trend of Fourier’s spectra areas, Post/Ante operam , for strike points 1,2,3,4 in direction N-S
CONCLUSIONS
Comparing results , recorded ante-post operam, we have regi stered:
� For each pulsepulse , this configuration reduces the length of the recording in t heconfiguration post-operam thanks to the increae of the damp ing factor ;
� This configuration significantly reduces the smaximum spectral amplitudeamplitude forfor thethecomponentscomponents inin thethe horizontalhorizontal planeplane ;
� There are increases of the values for the vertical component probably attributable toproblems related to the laying ot the rubber mats.
FUTURE DEVELOPMENTS
Improving the laying of the rubber mats:
�It would be of considerable interest, not being in literatur e, realizing a correct protocol forthe laying of the rubber mats inside the road pavement;
�It would be desiderable to be able to perform test in situ and i n laboratory in order tocontrol all the variables for the real scale experimentt.
Improving the data analysis:
�It would be interesting investigate the causes that generat e the amplifications of themaximum spectral amplitude for the vertical component in th e plane;
�Could be very interesting investigate a scheme to laying the rubber mats case by case inorder to reduce the amplifications which damage the buildin gs.
