Next Article in Journal
Graphene-Based Spatial Light Modulator Using Metal Hot Spots
Next Article in Special Issue
Acoustic Emission and Numerical Analysis of Pine Beams Retrofitted with FRP and Poplar Wood
Previous Article in Journal
Hyaluronic Acid-Conjugated with Hyperbranched Chlorin e6 Using Disulfide Linkage and Its Nanophotosensitizer for Enhanced Photodynamic Therapy of Cancer Cells
Previous Article in Special Issue
Biomechanical Behaviour and Biocompatibility of Ureidopyrimidinone-Polycarbonate Electrospun and Polypropylene Meshes in a Hernia Repair in Rabbits
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Pine Beams Retrofitted with FRP and Poplar Planks: Mechanical Behavior

by
Francisco J. Rescalvo
,
Chihab Abarkane
*,
Elisabet Suárez
,
Ignacio Valverde-Palacios
and
Antolino Gallego
Building Engineering School, University of Granada, Campus Fuentenueva s/n., 18071 Granada, Spain
*
Author to whom correspondence should be addressed.
Materials 2019, 12(19), 3081; https://doi.org/10.3390/ma12193081
Submission received: 16 August 2019 / Revised: 13 September 2019 / Accepted: 16 September 2019 / Published: 21 September 2019

Abstract

:
The paper presents an experimental analysis of the bending behavior of pine beams (Pinus Sylvester) retrofitted with fiber reinforced plastic (FRP) and poplar planks used as external covering. Poplar wood was chosen because of its rapid growth in planted forests, its homogeneity and attributes for sustainable local development, and high CO2 absorption rate. Vibration tests were also conducted in order to evaluate the stiffness in a non-destructive way and compare it with that obtained by means of the destructive tests. Three types of reinforcement were compared, namely: basalt fabric (FB), carbon fabric (FC) and carbon laminate (LC). In addition, some pine beams were reinforced only with poplar planks and used as control specimens in order to evaluate the improvement provided by the FRP. It was observed that a strong delamination preceded the final breakage of beam. Moreover, the results indicated that stiffness is provided mainly by the poplar plank and not by the FRP, as was expected.

1. Introduction

The most traditional retrofitting systems of wood structures are made with metallic components (basically steel). As a technological alternative, the use of composite materials for reinforcement, in particular, fiber reinforced plastics (FRP), offers numerous advantages such as lower extra weight and easier installation. Their development has been very important at a global level during the last decades. These lightweight materials are capable of withstanding high mechanical stresses, so that structures are very resistant and very light at the same time. In addition, they have properties ensuring exceptional performance, such as corrosion resistance and high strength. Reinforcing wood beams using FRP materials started in the 1960s [1,2,3], demonstrating that installing fiberglass (GFRP) wrapping under the wood element in a U-shape produces a significant increase of its ultimate strength, an increase of ductility (which is of vital importance for the structural safety), and makes the wood element able to endure greater deflections. Improvements of 50% and 20% in strength and stiffness, respectively, were obtained by some authors by means of the use of GFRP [4,5].
Meier’s work [6] is recognized as one of the pioneers in the use of carbon fiber reinforced plastic (CFRP) as reinforcement of wooden structures. Subsequently, Triantafillou and collaborators [7,8] reported relevant results about the reinforcement with CFRP pultruded laminates placed on the bottom side of the timber: (i) Failure pattern of the specimen changes from brittle to ductile; (ii) a 1% of CFRP material of the cross-sectional area produces an increase in resistance of 60%; and (iii) less CFRP than GFRP material is required to achieve the same effectiveness of the reinforcement (i.e., the CFRP is more efficient that the GFRP in terms of mechanical properties of the reinforced element). Fiorelli et al. [9] indicated that, depending on the type (GFRP or CFRP) and amount of material (from 0.4% to 3%), stiffness increases from 15% to 60%. Valluzi et al. [10] used CFRP sheets, and the ultimate strength improved up to 100%. The great importance of the humidity conditions of the wood during the CFRP-wood adhesion process was also reported. Similar studies can be found in [11,12,13].
Buell and Saadatmanesh [14] compared four reinforcement layouts, considering both tension and compression zones for location of the FRP. Improvements were about 17–27% in stiffness, 40–53% in flexural strength, and 36–68% in shear strength. They also considered some layouts of reinforcement that wrapped the lateral sides of the wood beam, demonstrating that this solution produces a substantial improvement in the ductility, due to the lateral shear reinforcement. Similar results were obtained by the authors of [8,15,16,17], who proposed the use of sheets of U-shaped CFRP fabric fully wrapping the bottom and lateral faces of the wood specimen. Since that date, many papers have been published (see [18] for a large description of previous results and literature).
However, despite this boom in the use of FRP as a reinforcement for wooden structures, there are still much reluctance among professionals and building owners regarding its practical implementation, mainly due to three reasons: (i) Its visual impact; (ii) its high price, especially in the case of FRP carbon; and (iii) its lower sustainability and greater environmental impact and ecological footprint, especially when compared to wood; (iv) The relevance of the bond between materials, either FRP–wood or wood–wood [19,20]. As an alternative to reduce visual impact, this work proposes the use of poplar wood planks to cover the FRP. Poplar wood has good properties that fit perfectly with sustainable construction values [21]: (i) It can be obtained from cultivated forests, reducing pressure on natural forests and promoting sustainable local development; (ii) it is fast growing (between 10–15 years in many areas of the planet), which confers a very high CO2 absorption rate when compared with other species; (iii) an adequate management of the plantations produces very good quality wood, free of knots and with much homogeneity, being able to reach values of modulus of elasticity (MOE) even slightly higher than 10,000 MPa; (iv) it has a high resistance, MOR (modulus of rupture), comparable to that of many conifers; and (v) it has a very low density, which is interesting from a structural point of view.
In this context, the present work compares the mechanical behavior of three FRP reinforcement configurations (basalt fabric, carbon fabric and carbon laminate), in which epoxy resin has been used as adhesive for the FRP-wood joint typically used in the case of FRP. In all cases, a poplar plank is also used to cover the reinforcement. As a reinforcement alternative, the poplar plank layout without any FRP is proposed and analyzed using a polyurethane resin as is typically used for the wood–wood joint of the laminated beams. The experimental results analyze the resistance and the stiffness improvements of the four configurations. Also, a theoretical analysis based in the parallel axis theorem is presented.

2. Materials and Methods

2.1. Pine Beams

Twelve Pinus sylvestris wooden beams provided by the company Maderas Pinosoria S.L. (Casarejos, Soria, Spain) with a cross section of 90 × 60 mm2 and a length of 1240 mm were randomly selected and used as base beams. For its characterization, the density (ρp) and the dynamic MOE (modulus of elasticity) MOEdin,p, were obtained by means of a longitudinal free vibration test along the grain direction. All the wood characterization tests were performed at a 12% moisture content. Values are shown in Table 1.

2.2. Poplar Planks

The poplar wood used for the planks was extracted from a crop of the cultivar I-214 (Popululs x euramericana (Dode) Guinier “I-214”) located at Yunquera de Henares (Guadalajara, Spain). In particular, poplar planks with a cross section of 30 × 60 mm2 and a length of 960 mm were extracted from three different trees. With the remaining wood from each of these trees, four-point bending tests were carried out and measurements of the density at the moisture content of 12% were obtained, thus obtaining the static modulus of elasticity (MOEst,po), the modulus of resistance (MORpo), and the ρpo, as is shown in Table 1.

2.3. Reinforced Beams

All twelve pine beams were retrofitted with four different layouts (three beams of each particular configuration). Three of them were reinforced only with poplar planks. For the rest, three types of FRP reinforcements were used: basalt fabric (FB), carbon fabric (FC) and carbon laminate (LC). Details of the dimensions, types of reinforcements, and resins used for each configuration are shown in Table 2. For the pine/FRP/poplar layouts with fabric FRPs (FB and FC), bi-component epoxy resin supplied by MAPEI SPAIN S.A.® (Barcelona, Spain) was used. Bi-component epoxy resin supplied by DRIZORO S.A.U.® (Madrid, Spain) was used for the case of pine/FRP/poplar layout with carbon laminate (LC), while mono-component polyurethane resin PUR-20 supplied by Bakar® (Vizcaya, Spain) was used for the case of the pine/poplar layout. The workability time for the three resins is 40, 60 and 60 min at 23 °C, respectively, while the Brookfiel viscosity is 7000 (20 °C), 300 (23 °C) and 8200 (23 °C) mPa·s, respectively.
Moreover, in the case of the pine/poplar beams, since both materials have similar elastic properties, the combined modulus of elasticity MOEst,c can be theoretically obtained using Equation (1) (the parallel axis theorem or Huygens-Steiner theorem [22]):
M O E s t , c =   i = 1 N E i · I i + A i · E i · y i 2 I c
where E i is the elastic modulus, I i is the second moment of inertia in respect to its own axis, A i is the cross-section area, y i is the distance from the combined neutral axis to the neutral axis of each element for each particular wood species, i. I c is the combined second moment of inertia.
In order to ensure an optimal moisture content, both wood species were conditioned at 20 ± 1 °C and 65 ± 5% relative humidity in a climatic chamber. The reinforcement process followed the steps described in [18] with a 12% mean moisture content of the beams. In this case, the curing time of the most unfavorable resin, i.e., the epoxy resin (7–10 days), was taken for all beams. After the reinforcement process, the beams were sanded in order to eliminate any cross-section imperfections that may have been generated during the application of the poplar planks. Once the elaboration process was finished, the beams were relocated into the climatic chamber in order to ensure an adequate moisture content during the tests.

2.4. Vibration Test

All the specimens were supported by their geometric center and subjected to free vibration tests conducted along the longitudinal direction (grain direction). A Fakopp SD-02 accelerometer (Fakopp Entreprise Bt., Agfalva, Hungary) was placed at one end of the beam, hitting a hammer on the opposite end. The response signal was recorded with a Picoscope® 4424 oscilloscope (Pico Technology, Wyboston, UK) with 80 MS/s and the fundamental resonance frequency of each beam was obtained, f1. With this frequency, and assuming the yielding and propagation of one-dimensional volume waves, the dynamic modulus of elasticity of the beam, MOEdin, can be estimated as [23,24]
v = 2 L f 1
  M O E d i n = ρ v 2  
where v is the propagation velocity of the elastic wave, L is the beam length and ρ is the beam density.

2.5. Four-Point Bending Test

All the specimens were subjected to a four-point bending test, as shown in Figure 1, following the UNE-EN 408: 2011 + A1: 2011 standard [25]. A testing machine model S-110 from CONTROLS S.A (Toledo, Spain) was used, with an electric actuator with a maximum load capacity of 100 kN. In order to measure the maximum tensile strains in the center of the beam and compare the strains of pine and poplar wood, 6 strain gauges were glued on the mid-cross section of each beam, as shown in Figure 2. From the bending tests, the MOR and the static MOEst were obtained. MOEst was calculated as the slope of the stress-strain plot between 20% and 50% of the MOR. For this, the strain of the gauge located on the face of maximum tensile stress was used (gauge 3). Gauge 6 measured the strain in the maximum compression area.

3. Results and Discussion

The strain measured by the six gauges as a function of time are shown on Figure 3 for two particular specimens (pine/poplar and pine/FRP-FC/poplar beams). In both cases, as expected, the maximum strains were obtained at the upper (tensile) and bottom (compression) external faces. Similarly, due to the symmetrical position, the strain measured by gauges 2 and 4 were similar to each other. This also occurred between gauges 1 and 5. Comparing the strain at the poplar plank and the strain at the adjacent points at the pine beam, greater values were observed at the poplar plank, due to the pine being closer to the neutral line. The mean value of the maximum tensile strain value, at which breakage occurs, was 3444, 3673, 3318 and 3261 με, for the RB_P, RB_P_FB, RB_P_FC and RB_P_LC layouts, respectively.
As shown in Table 1, the poplar plank is stiffer than the pine beam. This causes a significant difference in the strains between the two types of wood, which cannot be absorbed by the resin. This induced the aforementioned delamination. As an example, in Figure 3, it can be observed that for the RB_P_1 beam, this difference in strains is very significant (around 136% at the moment of the final failure). This can be the cause of the final delamination.
Two types of mechanical behaviors were observed:
  • Type A: Beams in which the strains increase permanently until the end of the test. The final failure was caused by a FRP-wood or poplar-pine delamination, followed by a sudden and brittle fracture of the pine beam. Specimen RB_P_1 (Figure 4) is an example of Type A behavior. Moreover, three failure modes were observed in the pine beams after delamination: Type 1: Shear; Type 2: Tensile; Type 3: Shear–tensile mixture.
  • Type B: Beams in which the strains increase permanently up to a particular intermediate load, in which FRP-wood delamination occurs. At this point, there is a sudden drop in the load and the strains, particularly in the tensile area. At this moment, the strains in the poplar plank become very low, because it is detached. After this drop, a gradual rise of the load occurs until the final brittle fracture of the pine beam, following one of failure modes previously mentioned: 1, 2 or 3. Specimen RP_P_FC_1 (Figure 5) is an example of beams with a Type B behavior.
Figure 6 shows the stress-time and stress-strain diagrams for the particular case of gauge 3. Table 3 shows the summary of the mechanical results, including the MOE (static and dynamic) and the MOR. The variation of the dynamic MOE, before and after reinforcement is also shown, in order to compare the influence of the reinforcement. Firstly, it is observed that all the reinforced beams have a lower density than base pine beams (between 7% and 9% less). This is due to the lower density of the poplar wood, despite the mass introduced by the FRP and the resins.
The average MOR of the twelve beams is 30.6 MPa with a low standard deviation, despite the heterogeneity of the base pine wood. It is observed that the average values for the carbon reinforcement layouts (FC and LC) are slightly higher than those without FRP (17% and 8%, respectively) and basalt fiber (FB). This homogeneity of the results between beams, with and without FRP reinforcement, is due to the fact that the main failure is induced by a strong delamination. Keeping these results in mind, and also considering the different distribution of strains between the two pieces of wood (pine and poplar), delamination seems to occur due to the difference in the mechanical behaviour between both species, not due to a lack of FRP/wood bonding.
Comparing the dynamic modulus before (MOEdin,p) and after reinforcement (MOEdin), an improvement between 14.8% and 20.2% is obtained. However, the increase obtained by using only the poplar plank (18%) is very comparable, or even greater, than that obtained when using FRP. This demonstrates that the improvement is basically provided by the poplar plank, since it has a similar, or even greater MOE, than the base pine beam. This fact is remarkable in pine/poplar beams, since the MOEdin,p of pine beams is 6730 MPa on average, compared to the 10,261 MPa of static modulus of poplar planks (MOEst,po). It is important to note that dynamic modulus is obtained from a vibration test longitudinally to the wood grain, thus being able to hide the improvement of the FRP. This effect is more evident if the static modulus obtained from the mechanical test (MOEst) is compared with the theoretical MOEst,c calculated for the pine/poplar beams (RB_P specimens). In this case, the mean variation between the theoretical and the experimental elastic MOE is very low (−4%). It is also remarkable that the pine/FRP/poplar specimens provide very similar values to the theoretical calculation of the MOE without taking the FRP into consideration (3%, 1%, 1% of variation for the FB, FC and LC layouts, respectively). These results seem to indicate that:
  • When there is a wooden reinforcement element (as poplar plank) with a considerable thickness and mass compared to that of the FRP (30 mm for the poplar plank versus 0.14 or 1 mm for the FRP), and its MOE is greater or comparable to that of the base beam (around 10,000 MPa for the poplar wood versus 8000–9000 MPa for the pine wood), the contribution of the FRP becomes less relevant.
  • As stated before, the failure mode in all configurations is caused by a significant delamination. This makes the MOR values modest and lower than those of the poplar plank, which never breaks. This delamination seems to have been premature and motivated by a lack of adhesion or by an excessive shear stress in the area close to the lower supports.

4. Conclusions

A mechanical characterization of pine beams reinforced with FRP and poplar wood planks has been carried out. Three types of pine/FRP/poplar configurations were evaluated (basalt fabric (FB), carbon fabric (FC) and carbon laminate (LC)), which were compared with the pine/poplar one.
Two failure modes were observed: (i) Type A, in which the load had an increasing tendency until a final brittle failure caused by the FRP–wood or wood–wood delamination; (ii) Type B, in which, after the preliminary delamination, the specimen still retained some load capacity, mainly due to the fibers which remained adhered or partially adhered to the pine base beam. In both cases, FRP-wood or wood-wood delamination was produced at similar MOR values (30.6 MPa), causing high damage to the base beam. This delamination could be associated with the differences in the mechanical behavior of the two wood species and a high stress concentration at the support areas.
Comparing the dynamic elastic modulus, MOEdin,p and MOEdin before and after reinforcement, it was observed that the main improvement was due to the poplar plank instead of the FRP. This fact is verified by comparing the theoretical combined modulus, MOEst,c, and the static modulus, MOEst (less than 1% difference). This suggests that the use of a wood element of relevant thickness and mass with an elastic modulus comparable to or greater than the base beam (8000–9000 MPa), makes the contribution of the FRP scarce or almost null. A wider analysis will be conducted in the future, including numerical simulations and a higher number of specimens.

Author Contributions

A.G. and F.J.R. designed the experiments. I.V.-P. contributed to the testing machine and strain gage instrumentation. C.A. and E.S. made data analyses and plotted the results. F.J.R. carried out the experiments. A.G., C.A. and F.J.R. wrote the paper.

Funding

This work was made possible thanks to the financial support of the COMPOP_Timber project “Desarrollo de productos de ingeniería elaborados a base de tablones y chapas de chopo con inserciones de material compuesto para su uso en construcción”, BIA2017-82650-R.

Acknowledgments

The authors thank Maderas Pinosoria, from Casarejos (Soria, Spain) for the pine raw material supply and discussions.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Theakston, F. A feasibility study for strengthening timber beams with fiberglass. Can. Agric. Eng. 1965, 7, 17–19. [Google Scholar]
  2. Biblis, E. Analysis of wood-fiberglass composite beams within and beyond the elastic region. FPJ 1965, 15, 81–88. [Google Scholar]
  3. Kellogg, R.; Wangaard, F. Influence of fiber strength on sheet properties of hardwood pulps. Tappi 1964, 47, 361. [Google Scholar]
  4. Rowlands, R.; Van Deweghe, R.; Laufenberg, T.L.; Krueger, G. Fiber-reinforced wood composites. Wood Fiber Sci. 1986, 18, 39–57. [Google Scholar]
  5. Moulin, J.M.; Pluvinage, G.; Jodin, P. FGRG: Fibreglass reinforced gluelam—A new composite. Wood Sci. Technol. 1990, 24, 289–294. [Google Scholar] [CrossRef]
  6. Meier, U. Carbon fiber-reinforced polymers: Modern materials in bridge engineering. Struct. Eng. Int. 1992, 2, 7–12. [Google Scholar] [CrossRef]
  7. Triantafillou, T.C.; Deskovic, N. Innovative prestressing with FRP sheets: Mechanics of short-term behavior. J. Eng. Mech. 1991, 117, 1652–1672. [Google Scholar] [CrossRef]
  8. Triantafillou, T.C. Shear reinforcement of wood using FRP materials. J. Mater. Civ. Eng. 1997, 9, 65–69. [Google Scholar] [CrossRef]
  9. Fiorelli, J.; Dias, A.A. Analysis of the strength and stiffness of timber beams reinforced with carbon fiber and glass fiber. Mater. Res. 2003, 6, 193–202. [Google Scholar] [CrossRef] [Green Version]
  10. Valluzzi, M.R.; Garbin, E.; Modena, C. Flexural strengthening of timber beams by traditional and innovative techniques. J. Build. Appr. 2007, 3, 125–143. [Google Scholar] [CrossRef]
  11. De Jesus, A.M.; Pinto, J.M.; Morais, J.J. Analysis of solid wood beams strengthened with CFRP laminates of distinct lengths. Constr. Build. Mater. 2012, 35, 817–828. [Google Scholar] [CrossRef]
  12. Neubauerová, P. Timber beams strengthened by carbon–fiber reinforced lamellas. Procedia Eng. 2012, 40, 292–297. [Google Scholar] [CrossRef]
  13. Kimand, Y.J.; Harries, K.A. Modeling of timber beams strengthened with various CFRP composites. Eng. Struct. 2010, 32, 3225–3234. [Google Scholar]
  14. Buell, T.W.; Saadatmanesh, H. Strengthening timber bridge beams using carbon fiber. J. Struct. Eng. 2005, 131, 173–187. [Google Scholar] [CrossRef]
  15. Ajdukiewicz, A.; Brol, J.; Malczyk, A.; Wlaszczuk, M. Rehabilitation of the highest wooden tower in Poland. Struct. Eng. Int. 2000, 10, 161–163. [Google Scholar] [CrossRef]
  16. Rescalvo, F.J.; Suarez, E.; Abarkane, C.; Cruz-Valdivieso, A.; Gallego, A. Experimental validation of a CFRP laminated/fabric hybrid layout retrofitting and repairing timber beams. Mech. Adv. Mater. Struc. 2018, 1–8. [Google Scholar] [CrossRef]
  17. Rescalvo, F.J.; Valverde-Palacios, I.; Suarez, E.; Gallego, A. Experimental and analytical analysis for bending load capacity of old timber beams with defects when reinforced with carbon fiber strips. Compos. Struct. 2018, 186, 29–38. [Google Scholar] [CrossRef]
  18. Rescalvo, F.J.; Valverde-Palacios, I.; Suarez, E.; Gallego, A. Experimental comparison of different carbon fiber composites in reinforcement layouts for wooden beams of historical buildings. Materials 2017, 10, 1113. [Google Scholar] [CrossRef] [PubMed]
  19. Gustafsson, P.J. Tests and test results on mechanical properties of adhesive bond lines. In COST Action E13–Wood Adhesion and Glued Products; Johansson, C.J., Pizzi, T., Van Leemput, M., Eds.; Citeseer: Pennsylvania State University Park, PA, USA, 2002; pp. 7–24. [Google Scholar]
  20. Matej, J.; Sernek, M. Shear strength development of the phenol–formaldehyde adhesive bond during cure. Wood Sci. Technol. 2009, 43, 153. [Google Scholar]
  21. CAB International, Food and Agriculture Organization of the United Nations. Poplars and Willows: Trees for Society and the Environment; Isebrands, J.G., Richardson, J., Eds.; CAB International FAO: Wallingford, UK, 2014. [Google Scholar]
  22. Mallick, P.K. Composites Engineering Handbook; CRC Press: Boca Raton, FL, USA, 1997. [Google Scholar]
  23. Casado, M.; Acuña, L.; Vecilla, D.; Relea, E.; Basterra, A.; Ramón, G.; Lopez, G. The influence of size of predicting the elastic modulus of Populus x euramericana timber using vibration techniques. In Proceedings of the 1st International Conference on Structures and Arquitecture, ICSA 2010, Guimaraes, Portugal, 21–23 July 2010. [Google Scholar]
  24. Vega, A.; Dieste, A.; Guaita, M.; Majada, J.; Baño, V. Modelling of the mechanical properties of Castanea sativa Mill. Structural timber by a combination of non-destructive variables and visual grading parameters. Eur. J. Wood Wood Prod. 2012, 70, 839–844. [Google Scholar]
  25. UNE-EN 408:2011+A1:2012. Estructuras de madera. Madera aserrada y madera laminada encolada para uso estructural. In Determinación de Algunas Propiedades Físicas y Mecánicas; Asociación Española de Normalización: Madrid, Spain, 2012. [Google Scholar]
Figure 1. Reinforced beam design and four-point bending test set-up. Distances in mm.
Figure 1. Reinforced beam design and four-point bending test set-up. Distances in mm.
Materials 12 03081 g001
Figure 2. Location of the strain gauges along the mid-cross section of the reinforced beams.
Figure 2. Location of the strain gauges along the mid-cross section of the reinforced beams.
Materials 12 03081 g002
Figure 3. Strain versus time for beams RB_P_1 (failure mode type A) and RB_P_FC_1 (failure mode type B).
Figure 3. Strain versus time for beams RB_P_1 (failure mode type A) and RB_P_FC_1 (failure mode type B).
Materials 12 03081 g003
Figure 4. Picture of the final delamination and pine fracture. RB_P_1 specimen. Type A.
Figure 4. Picture of the final delamination and pine fracture. RB_P_1 specimen. Type A.
Materials 12 03081 g004
Figure 5. (Left) Picture of the delamination during the test at an intermediate load value; (Right) pine fracture at the end of the loading. RB_P_FC_1 specimen. Type B.
Figure 5. (Left) Picture of the delamination during the test at an intermediate load value; (Right) pine fracture at the end of the loading. RB_P_FC_1 specimen. Type B.
Materials 12 03081 g005
Figure 6. (Left) Stress–time plots. (Right) Stress–strain plots.
Figure 6. (Left) Stress–time plots. (Right) Stress–strain plots.
Materials 12 03081 g006aMaterials 12 03081 g006b
Table 1. Mechanical properties of pine beams and poplar planks.
Table 1. Mechanical properties of pine beams and poplar planks.
BeamMOEdin,p (MPa)ρp (kg/m3)MOEst,po (MPa) *MORpo (MPa) *ρpo (kg/m3) *
RB_P_1561654410,26138374
RB_P_26465538
RB_P_38108528
RB_P_FB_17989485944142357
RB_P_FB_27709544
RB_P_FB_37239553
RB_P_FC_18411523944142357
RB_P_FC_27186481
RB_P_FC_311,000591
RB_P_LC_111,77361010,14248400
RB_P_LC_29203571
RB_P_LC_38775544
Mean value8290543982143372
Standard deviation175438400418
* indicates that the values are identical for three beams of the same reinforcement configuration.
Table 2. Reinforced beams: Nomenclature, types and main FRP characteristics.
Table 2. Reinforced beams: Nomenclature, types and main FRP characteristics.
ConfigurationReinforcement TypeFRPResinConsumption (g/m2)FRP Thickness (mm)FRP Grammage (g/m2)
RB_PPoplar-PUR-20 --
RB_P_FBFB/PoplarBasalt FabricMAPEWRAP 212800.14400
RB_P_FCFC/PoplarCarbon FabricMAPEWRAP 219300.17300
RB_P_LCLC/PoplarCarbon LaminateMAXEPOX CS8001.4-
Table 3. Mechanical results for the 12 tested specimens.
Table 3. Mechanical results for the 12 tested specimens.
BeamMOR (MPa)MOEst (MPa)MOEst,c (MPa)MOEdin (MPa)Variation of MOEdin Respect to MOEdin,p (%)Variation of Mean MOEst Respect to Mean MOEst,c (%)ρ (kg/m3)Variation of Mean ρ Respect to Mean ρp (%)Type of Failure
RB_P_126.381207648697224.1 507 A-1
RB_P_229.495908126794822.9 494 A-3
RB_P_330.67940805088919.7 489 A-1
Mean value28.885508275793718.0−4497−7.5
Standard deviation2.290571396081590.7
RB_P_FB_132.984508624902312.9 454 A-1
RB_P_FB_229.181608467899316.6 495 B-2
RB_P_FB_324.980008202832114.9 504 A-1
Mean value29.082038431877914.83485−8.1
Standard deviation4.02282133971.91271.5
RB_P_FC_135.192608862994518.2 479 B-3
RB_P_FC_230.181808173899425.1 452 B-3
RB_P_FC_335.7959010,31812,0639.7 532 B-3
Mean value33.69010911710,33416.61488−8.1
Standard deviation2.8709109515397.76402.0
RB_P_LC_132.6969011,05913,45814.3 559 A-3
RB_P_LC_230.89760961411,09520.6 523 B-1
RB_P_LC_329.510,009937311,23728.1 496 A-1
Mean value31.0982010,01511,93020.21526−8.5
Standard deviation0.81309124474.510170.3
Global mean value30.688968960974518.10499−8.1
Standard deviation3.281499218736.19300.4

Share and Cite

MDPI and ACS Style

Rescalvo, F.J.; Abarkane, C.; Suárez, E.; Valverde-Palacios, I.; Gallego, A. Pine Beams Retrofitted with FRP and Poplar Planks: Mechanical Behavior. Materials 2019, 12, 3081. https://doi.org/10.3390/ma12193081

AMA Style

Rescalvo FJ, Abarkane C, Suárez E, Valverde-Palacios I, Gallego A. Pine Beams Retrofitted with FRP and Poplar Planks: Mechanical Behavior. Materials. 2019; 12(19):3081. https://doi.org/10.3390/ma12193081

Chicago/Turabian Style

Rescalvo, Francisco J., Chihab Abarkane, Elisabet Suárez, Ignacio Valverde-Palacios, and Antolino Gallego. 2019. "Pine Beams Retrofitted with FRP and Poplar Planks: Mechanical Behavior" Materials 12, no. 19: 3081. https://doi.org/10.3390/ma12193081

APA Style

Rescalvo, F. J., Abarkane, C., Suárez, E., Valverde-Palacios, I., & Gallego, A. (2019). Pine Beams Retrofitted with FRP and Poplar Planks: Mechanical Behavior. Materials, 12(19), 3081. https://doi.org/10.3390/ma12193081

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop