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220822 ||| eng |
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|a 9783036518916
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|a 9783036518909
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|a books978-3-0365-1891-6
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100 |
1 |
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|a Schabowicz, Krzysztof
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245 |
0 |
0 |
|a Testing of Materials and Elements in Civil Engineering
|h Elektronische Ressource
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260 |
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|a Basel, Switzerland
|b MDPI - Multidisciplinary Digital Publishing Institute
|c 2021
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300 |
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|a 1 electronic resource (578 p.)
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653 |
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|a non-destructive testing
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653 |
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|a orthotropic shear modulus
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653 |
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|a industrial waste management
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653 |
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|a fibre bragg grating sensors
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653 |
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|a failure mode
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653 |
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|a short-time Fourier transform
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653 |
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|a resonance frequency test
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653 |
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|a reinforced concrete beams
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653 |
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|a reinforced concrete
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653 |
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|a wood
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653 |
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|a PBO-FRCM
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653 |
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|a quality assessment
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653 |
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|a sodium chloride
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653 |
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|a wire mesh
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653 |
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|a signal analysis
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653 |
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|a FRP reinforcement
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653 |
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|a restrined ring calibration
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653 |
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|a mining areas
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653 |
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|a fatigue durability
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653 |
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|a waste paper sludge ash (WPSA)
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653 |
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|a Technology: general issues / bicssc
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653 |
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|a large-scale facade model
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653 |
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|a carbonation
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653 |
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|a freeze-thaw cycles
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653 |
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|a bending strength
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653 |
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|a X-ray microtomography
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653 |
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|a FRTP
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653 |
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|a stiffness
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653 |
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|a non-destructive techniques (NDT)
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653 |
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|a effective area ratio
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653 |
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|a diagnostic testing
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653 |
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|a volumetric parameters
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653 |
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|a convolutional neural networks
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653 |
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|a recycled steel fibres
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653 |
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|a compressive strength
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653 |
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|a ring shear test
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653 |
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|a fast Fourier transform
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653 |
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|a capable design moment
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653 |
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|a early age concrete
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653 |
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|a numerical analysis
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653 |
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|a rock bolt
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653 |
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|a texture
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653 |
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|a opening size
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653 |
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|a scarf and splice joints
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653 |
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|a tensile strength
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653 |
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|a ventilated facades
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653 |
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|a quasi-brittle cement composites
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653 |
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|a P-wave velocity
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653 |
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|a base layer
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653 |
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|a concrete cracking test
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653 |
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|a sustainable test methods
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653 |
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|a digital image correlation
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653 |
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|a damage processes detection before loading
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653 |
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|a damage variable
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653 |
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|a partition walls
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653 |
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|a X-ray
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653 |
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|a rivet
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653 |
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|a connection
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653 |
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|a shear
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653 |
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|a test uncertainty
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653 |
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|a FRCM
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653 |
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|a microstructure characteristics
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653 |
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|a energy absorption
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653 |
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|a grain-size characteristics
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653 |
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|a concrete centrifugation
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653 |
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|a hydration kinetics
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653 |
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|a AE acoustic emission
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653 |
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|a ultrasound measurements
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653 |
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|a image processing
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653 |
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|a high-strength concrete
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653 |
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|a test apparatus
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653 |
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|a ultrasounds
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653 |
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|a slip resistance value
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653 |
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|a mineral-cement emulsion mixtures
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653 |
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|a acoustic emission method
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653 |
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|a ESD resin
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653 |
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|a storage systems
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653 |
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|a column
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653 |
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|a stop-splayed scarf joints ('bolt of lightning')
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653 |
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|a testing of building materials
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653 |
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|a grout mixtures
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653 |
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|a flexural tensile strength
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653 |
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|a fibre-reinforced concrete
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653 |
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|a resistance strain
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653 |
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|a nuclear magnetic resonance
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653 |
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|a corrosion
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653 |
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|a bender elements test
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653 |
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|a scanning electron microscopy
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653 |
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|a geopolymer concrete
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653 |
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|a visible light transmittance
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653 |
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|a sound spectrum
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653 |
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|a reclaimed asphalt
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653 |
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|a brick walls
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653 |
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|a erosional stability
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653 |
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|a grouting quality
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653 |
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|a galvanostatic pulse method
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653 |
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|a low-module polypropylene fibres
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653 |
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|a roughness
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653 |
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|a transfer learning
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653 |
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|a asphalt mix
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653 |
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|a capacity
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653 |
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|a statistical-fuzzy method
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653 |
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|a CT scan
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653 |
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|a fiber composites
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653 |
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|a civil engineering
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653 |
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|a concrete
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653 |
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|a destructive test
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653 |
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|a mechanical properties of polyethylene
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653 |
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|a polyethylene pipe
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653 |
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|a residual shear stress
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653 |
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|a bearing capacity
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653 |
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|a elements
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653 |
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|a PBO mesh
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653 |
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|a cement
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653 |
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|a Al-Ti laminate
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653 |
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|a post-tension
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653 |
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|a morphology
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653 |
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|a relative mass loss
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653 |
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|a structural health monitoring
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653 |
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|a strength of structures
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653 |
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|a plasterboards
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653 |
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|a detection
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653 |
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|a classification
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653 |
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|a unconfined compressive strength
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653 |
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|a ultrasonic tomography
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653 |
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|a carpentry joints
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653 |
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|a methods of assessment
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653 |
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|a sustainability
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653 |
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|a mechanical properties
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653 |
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|a pattern recognition
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653 |
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|a expansion joint
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653 |
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|a validation of test methods
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653 |
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|a recycling
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653 |
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|a neural network
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653 |
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|a acoustic emission diagnostic
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653 |
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|a bottom-ash
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653 |
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|a cement-fiber boards
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653 |
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|a degradation of glass panels
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653 |
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|a machine learning
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653 |
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|a clustering AE signal
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653 |
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|a groundwater
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653 |
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|a cladding
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653 |
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|a building materials
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653 |
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|a acceptance angle
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653 |
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|a k-means algorithm
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653 |
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|a spin-lattice relaxometry
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653 |
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|a compaction index
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653 |
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|a S-wave
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653 |
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|a finite element method
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653 |
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|a amplitude attenuation
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653 |
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|a Arcan shear test
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653 |
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|a landslides
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653 |
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|a random field generation
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653 |
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|a strain
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653 |
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|a fly-ash
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653 |
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|a safety
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653 |
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|a bond strength
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653 |
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|a construction material
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653 |
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|a sliding friction coefficient
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653 |
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|a P-wave
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653 |
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|a HMA dielectric constant
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653 |
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|a GFRP
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653 |
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|a complex modulus
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653 |
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|a micro-computed tomography
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653 |
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|a micro-events
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653 |
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|a brine
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653 |
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|a internal insulation
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653 |
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|a shrinkage analysis
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653 |
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|a ground penetrating radar (GPR)
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653 |
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|a restrained ring test
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653 |
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|a wood-plastic composites
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653 |
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|a concrete shrinkage cracking test
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653 |
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|a roundness
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653 |
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|a residual-state creep
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653 |
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|a cement dusty by-products (UCPPs)
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653 |
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|a methods of testing resistance to fungi
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653 |
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|a ultrasound tests
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653 |
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|a industrial floors
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653 |
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|a monitoring FBG
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653 |
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|a reclaimed asphalt pavement (RAP)
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653 |
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|a natural frequency
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653 |
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|a steel-concrete connection joint
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653 |
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|a power transmission tower
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653 |
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|a foamed asphalt mixtures with cement (FAC)
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653 |
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|a aggregate
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653 |
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|a corrosion of reinforcement
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653 |
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|a mechanical behavior
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653 |
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|a superplasticizer
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653 |
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|a laboratory testing
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653 |
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|a ready-mixed concrete
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653 |
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|a steel fibres
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653 |
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|a hybrid truss bridge
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653 |
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|a testing
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653 |
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|a strength distribution
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653 |
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|a fire safety
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653 |
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|a wavelet analysis
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653 |
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|a hygrothermal processes
|
653 |
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|a dynamic elastic modulus
|
653 |
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|a elastic range
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653 |
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|a flexural test
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653 |
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|a computer simulation
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653 |
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|a controlled low-strength material (CLSM)
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653 |
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|a particle crushing
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653 |
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|a static test
|
653 |
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|a backfill material
|
653 |
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|a road pavement thickness estimation
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653 |
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|a monitoring fibre Bragg grating
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653 |
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|a ground-penetrating radar (GPR)
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653 |
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|a X-ray analysis
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653 |
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|a sand
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653 |
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|a concrete floors
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653 |
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|a dynamic response
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653 |
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|a elastic-plastic material
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653 |
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|a semivariograms
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653 |
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|a tilting angle
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653 |
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|a static elastic modulus
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653 |
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|a tab connector
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653 |
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|a phase composition analysis
|
653 |
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|a slip resistance
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653 |
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|a large-slab ceramic tile
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653 |
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|a autogenous shrinkage cracking
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653 |
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|a stiffness modulus
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653 |
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|a defects
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653 |
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|a fracture energy
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653 |
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|a ramp test
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653 |
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|a historical masonry wall
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653 |
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|a moisture resistance
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653 |
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|a monitoring
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653 |
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|a sandstone
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653 |
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|a comparability of test methods
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653 |
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|a quasi-plastic material
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653 |
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|a close-range photogrammetry
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653 |
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|a traditional and quasi-brittle cement composites
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653 |
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|a resistivity
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653 |
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|a flexural strength
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653 |
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|a porosity
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653 |
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|a windblown sand
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653 |
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|a frictional work
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653 |
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|a hydration processes
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653 |
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|a wall temperature
|
653 |
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|a shear wave velocity
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653 |
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|a moisture content
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653 |
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|a girder
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653 |
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|a infiltration damage
|
653 |
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|a static behaviour
|
653 |
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|a nondestructive method
|
653 |
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|a acoustic methods
|
653 |
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|a non-destructive test
|
653 |
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|a particle flow code (PFC2D)
|
653 |
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|a experimental research
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653 |
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|a granite floor
|
653 |
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|a diagnostic
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653 |
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|a cracking
|
653 |
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|a saturation front
|
653 |
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|a fracture
|
653 |
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|a thermal analysis
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653 |
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|a cable
|
653 |
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|a strain/stress distribution
|
653 |
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|a fiber cement board
|
653 |
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|a conformity criteria
|
653 |
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|a proton
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700 |
1 |
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|a Schabowicz, Krzysztof
|
041 |
0 |
7 |
|a eng
|2 ISO 639-2
|
989 |
|
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|b DOAB
|a Directory of Open Access Books
|
500 |
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|a Creative Commons (cc), https://creativecommons.org/licenses/by/4.0/
|
028 |
5 |
0 |
|a 10.3390/books978-3-0365-1891-6
|
856 |
4 |
2 |
|u https://directory.doabooks.org/handle/20.500.12854/76856
|z DOAB: description of the publication
|
856 |
4 |
0 |
|u https://www.mdpi.com/books/pdfview/book/4324
|7 0
|x Verlag
|3 Volltext
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|a 414
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|a 900
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|a 610
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|a 333
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|a 620
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|a This book was proposed and organized as a means to present recent developments in the field of testing of materials and elements in civil engineering. For this reason, the articles highlighted in this editorial relate to different aspects of testing of different materials and elements in civil engineering, from building materials to building structures. The current trend in the development of testing of materials and elements in civil engineering is mainly concerned with the detection of flaws and defects in concrete elements and structures, and acoustic methods predominate in this field. As in medicine, the trend is towards designing test equipment that allows one to obtain a picture of the inside of the tested element and materials. Interesting results with significance for building practices were obtained.
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