We propose a new method to strengthen structural masonry. To study on the axial compression behavior of masonry columns’ strengthening with a bamboo scrimber bar mesh mortar layer, axial compression tests of twelve masonry columns have been completed: nine strengthened columns and three unstrengthened columns. The failure process, bearing capacity, and failure mode are carried out. The strengthening method of bamboo scrimber bar mesh mortar layer permits the upgrade of the columns’ bearing capacity. The effects of bamboo bar ratio and mortar strengthening ratio on bearing capacity of the reinforced columns are compared. We propose the method for calculating the axial bearing capacity of such a reinforced column. The calculation results agree well with the experimental results, and the research results are available for engineering application.
Most of China’s rural houses use self-built masonry structures. Self-built masonry structures often have many defects and high vulnerability. Because of the constraints of China’s urbanization development stage and the current economic development, the existing self-built masonry structures in rural areas will be in existence for a long time. Therefore, it is a need to strengthen existing masonry structures.
Standard strengthening methods for masonry structures [
Bamboo is a biomass material with a short growth cycle and excellent industrial performance. We know China is the kingdom of bamboo. According to statistics, there are 110 million tons of idle bamboo forest resources in China. The bamboo has a high tensile strength. However, bamboo prices are much lower than steel. The replacement of high-contamination, high-energy, nonrenewable steel bars in the structure with bamboo not only conforms to the current condition of China but also contribute to the sustainable development of the construction industry and protecting the environment.
At present, two examples of engineered bamboo are laminated: bamboo and bamboo scrimber [
This paper proposes a method of the bamboo scrimber bar mesh mortar layer to strengthen the masonry structures. Through the axial compression experiment, bearing capacity, ductility, failure form, and bamboo bar strain of the reinforced brick columns and the unreinforced brick columns are studied. Based on the experiment, the influence of parameters such as bamboo bar ratio and mortar strengthening ratio on bearing capacity of reinforced brick columns are analysed. A method for calculating the axial bearing capacity of such a reinforced brick column is proposed.
Four groups of specimens are designed for this experiment. There are three specimens in each group, thus forming a total of twelve specimens. All the brick columns are 370 mm wide, 240 mm thick, and 720 mm tall. The brick columns are composed of MU10 brick and M2.5 cement mortar. The brick columns are built on the reinforced concrete bases whose dimensions are 550 mm wide, 400 mm thick, and 200 mm tall and whose strength class is C30. After the specimens have been built and cured for seven days, the dirt and scraps on the surfaces of the specimens are removed. After drilling with an electric drill, L-shaped shear pins made of φ6 rebar are implanted on the surfaces of the specimens. The shear pins are implanted to a depth of 60 mm and bonded by Goodbond modified epoxy adhesive. Bamboo scrimber bars are cut from bamboo scrimber plates produced by YiyangTaohuajiang Bamboo Development Co., Ltd. The section size of bamboo bars is 10 × 10 mm. A mixture of epoxy resin and polyamide resin is applied to the surfaces of bamboo bars. Then, sand is evenly spread on bamboo bars to enhance the bonding performance of bamboo bars and cement mortar. The longitudinal bamboo bars and horizontal bamboo bars are tied by steel wire. The bamboo bar mesh is fixed on the surfaces of the brick columns by the shear pins. Strengthened mortar with strength class M15 and 40 mm thick is applied to the brick columns for three times. The parameters of specimens are listed in Table
Parameters of specimens.
Specimen group | Vertical bamboo bar | Horizontal bamboo bar | Strengthening method |
---|---|---|---|
ZA | — | — | — |
ZB | 10 × 10@240 | 10 × 10@220 | Double sides |
ZC | 10 × 10@120 | 10 × 10@220 | Double sides |
ZD | 10 × 10@120 | 10 × 10@220 | Four sides |
Schematic diagram of specimens.(a) The front elevation of ZA. (b) The side elevation of ZA. (c) The front elevation of ZB. (d) The profile of ZB. (e) The front elevation of ZC. (f) The profile of ZC. (g) The front elevation of ZD. (h) The side elevation of ZD.
The process of making bamboo scrimber bar: (a) bamboo board, (b) cutting into strips, (c) gluing sand, and (d) binding bamboo bars.
According to the method of
Experimental test methods for bamboo scrimber.
Test parameter | Test schematic | Direction |
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Specimen size |
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a | Parallel to grain | 6 | c |
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a | Parallel to grain | 6 | d |
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b | Parallel to grain | 6 | 15 mm × 15 mm × 15 mm |
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b | Parallel to grain | 6 | 15 mm × 15 mm × 60 mm |
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ftb, tensile strength; Etb, tensile elastic modulus; fcb, compressive strength; Ecb, compressive elastic modulus.
Material properties for bamboo scrimber.
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|
|
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158.61 | 21.28 | 91.50 | 4.55 |
The compressive strength of bricks and mortar is tested by the test method in
Compressive strength of mortar.
Specimens |
|
|
---|---|---|
ZA1, ZA2, ZA3 | 2.86 | — |
ZB1 | 2.86 | 9.60 |
ZB2 | 2.86 | 9.60 |
ZB3 | 2.86 | 10.58 |
ZC1 | 2.56 | 13.70 |
ZC2 | 2.56 | 13.70 |
ZC3 | 2.56 | 8.66 |
ZD1 | 2.56 | 14.37 |
ZD2 | 2.56 | 10.09 |
ZD3 | 2.56 | 9.49 |
The experiment is carried out in the structural experiment hall of the College of Civil Engineering, University of Central South University of Forestry and Technology. Figure
Loading device of specimens.
This test is a monotonic static loading test using a step loading. Before loading, preload to 20 kN for two minutes and then unload at a constant rate. Preloading is utilized to eliminate the gap between the loading device and the specimen and to check the sensitivity of the instrument and the firmness of the installation. After the preloading is completed, the load is gradually increased at a loading rate of 20 kN. After the specimen cracked, the load is increased at a loading rate of 10 kN until the specimen fails. The failure load takes 85% of the peak load.
From the experiment, it appears that the compressive load and vertical displacement of the columns and the strain of the bamboo scrimber bars are mainly tested. Figure
Layout of strain gauges: (a) ZB and (b) ZC and ZD.
The average test values of the specimen groups are shown in Table
Test results average.
Specimen group | Cracking load (kN) | Increasing rate of cracking load (%) | Peak load (kN) | Increasing rate of peak load (%) | Peak displacement (mm) | Increasing rate of peak displacement (%) |
---|---|---|---|---|---|---|
ZA | 287 | — | 561 | — | 2.764 | — |
ZB | 400 | 39.4 | 736.7 | 31.3 | 2.121 | −23.3 |
ZC | 433 | 50.9 | 876.7 | 56.3 | 3.449 | 24.8 |
ZD | 480 | 67.2 | 1200 | 113.9 | 2.775 | 0.4 |
Load-displacement curves of typical specimens.
After strengthening of the bamboo scrimber bar mesh mortar layer, the cracking load of the brick columns increased by 39.4%–67.2%, and the peak load increased by 39.3%–113.5%. Stiffness of the strengthening brick columns is significantly improved. However, the peak displacement increase is not apparent, and the increasing range is −23.3% to 24.8%. It indicates that the strengthening method cannot significantly increase the axial compression deformation performance of the brick columns due to the self-brittleness of the cement mortar layer.
Compared with group ZB, the longitudinal bamboo bars in group ZC brick columns are increased when the number of bar faces is the same, the cracking load of the brick columns increased by 8.25%, the peak load increased by 19%, and the peak displacement increased by 62.6%. The increase of bamboo scrimber longitudinal bar not only improves the axial bearing capacity of the brick columns but also dramatically increases the ductility of the brick columns.
Comparing with group ZD and group ZC, the stiffness of the brick columns is significantly improved as the strengthening faces number increases. Four-sided strengthening has a restraining effect on the brick columns, which significantly increases the axial bearing capacity of the brick columns.
When the vertical load reaches about 50% of the ultimate load, several vertical cracks appear on the surfaces of the brick column. The width of the cracks increases continuously during the test. When the vertical load reaches about 80% of the ultimate load, the cracks extend rapidly upwards and downwards. As the load continues to increase, the vertical cracks penetrate, the masonry mortar begins to fall off, the vertical deformation and cracks of the brick column increase sharply, and the brick column is destroyed. Figure
Typical failure of group ZA.
During the test, some horizontal cracks appear first on the strengthening surfaces corresponding to the horizontal bamboo bars when the vertical load increases to about 50% of the ultimate load. When the load is applied up to 70% of the ultimate load, several vertical cracks appear in the middle of the strengthening surfaces, two vertical cracks appear on the interface between the strengthening layers and the brick column, and new horizontal cracks appear on the strengthening surfaces corresponding to horizontal bamboo bars. With the load increases, the original cracks develop, and some other vertical cracks appear and extend. When the ultimate load is reached, the vertical cracks of the unreinforced surfaces penetrate, the horizontal cracks of the strengthening surfaces penetrate, the vertical deformation of the brick column increases continuously, and the brick column is destroyed. The typical failure mode of group ZB is shown in Figure
Typical failure of group ZB.
Several vertical cracks appear on the strengthening surfaces corresponding to the middle longitudinal bamboo bars when the vertical load reaches about 50% of the ultimate load. When the load reaches about 70% of the ultimate load, some vertical cracks appear on the interface between the strengthening layers and the brick column. At the same time, new vertical cracks and horizontal cracks appear in the corresponding position of the bamboo bar mesh on the strengthening surfaces. When the load is applied up to 90% of the ultimate load, the original vertical cracks of the unreinforced surfaces extend and widen, and new vertical cracks appear in the middle of the brick column; the original horizontal cracks and vertical cracks of the strengthening surfaces extend faster, and some new vertical cracks appear simultaneously. When reaching the ultimate load, the vertical cracks of the unreinforced surfaces penetrate; the vertical cracks of the strengthening surfaces do not penetrate, but the horizontal cracks penetrate, and the mortar of the strengthening surfaces begins to fall off. Figure
Typical failure of group ZC.
When the load reaches about 40% of the ultimate load, the horizontal cracks appear on the four strengthening surfaces corresponding to the horizontal bamboo bars. As the load increases, the vertical crack appears in the corresponding position of the vertical bamboo bars. As the load continues to increase, the vertical and lateral cracks extend and widen, forming “#”-shaped cracks on the strengthening surface. When the ultimate load is reached, the vertical cracks penetrate in the long-side strengthening surface; in the short-side strengthening surface, the horizontal cracks penetrate in the middle position, and the strengthening mortar layer is arched and separated from the brick column; the brick column is destroyed. After the experiment, the strengthening mortar layers are cut and observed. The bamboo bar mesh and the brick column are still tightly combined. In the corresponding position of the brick column and the strengthening surfaces, a plurality of vertical cracks penetrated. Figure
Typical failure of group ZD.
The vertical load-bamboo bar strain curves of the typical specimens in group ZB, ZC, and ZD are shown in Figure
Load-bamboo bar strain curves: (a) ZB, (b) ZC, (c) ZD, and (d) comparison graph.
The conclusions are as follows: At the initial stage of loading, the strain of bamboo bars increases linearly. The strain rate of the bamboo bars at the top of the column is the fastest, the strain growth rate in the middle of the column is second, and the strain growth rate of the bottom of the column is the slowest. It shows that the deformation coordination ability of the bamboo bars and the brick column is good. After the vertical load is increased to 650 kN, the strain of the bamboo bars increases rapidly in the group ZB. When the vertical load is added to 750 kN, the strain of the bamboo bars of group ZC developed rapidly. Compared with group ZB, due to the increase of the number of bamboo bars, the axial bearing capacity and ductility of the brick columns of group ZC is improved. From these results, it appears that the compressive strength of the bamboo bars is more fully utilized, with the increasing ultimate strain of the bamboo bars of group ZC. For the brick columns of group ZD, when the vertical load reaches 1170 KN, the strain of the bamboo bars increases rapidly. Due to the confinement effect formed by the four-side strengthening, the brick columns are in a triaxial compression state, and the compressive strength of the bamboo bars is efficiently used. When the specimens are destroyed, the strengthening mortar layers are arched, the middle brick columns are crushed, and the strain of the bamboo bars increases rapidly.
Figure
(a) Curve of bamboo bar ratio vs. capacity enhancement ratio. (b) Curve of mortar strengthening ratio vs. capacity enhancement ratio.
According to the correlation analysis between the strengthening ratio and the capacity enhancement ratio of the brick column, the axial compression bearing capacity of the strengthened brick column can be simplified to the superposition of bearing capacity of the brick column and the strengthening layers. Refer to the calculation formula 6.2.1 of the external steel bar mesh mortar layer strengthening method in Code for design of strengthening masonry structures in [
Using formula (
Comparison between calculated and experimental values of the limit load of columns.
Specimen | Experimental values |
Experimental values |
Calculated values |
Calculated values |
|
---|---|---|---|---|---|
ZB1 | 640.0 | 561.0 | 239.5 | 800.5 | 1.250 |
ZB2 | 740.0 | 561.0 | 239.5 | 800.5 | 1.082 |
ZB3 | 830.0 | 561.0 | 261.0 | 822.0 | 0.990 |
ZC1 | 890.0 | 561.0 | 341.9 | 902.9 | 1.014 |
ZC2 | 870.0 | 561.0 | 341.9 | 902.9 | 1.038 |
ZC3 | 870.0 | 561.0 | 232.3 | 793.3 | 0.912 |
ZD1 | 1300.0 | 561.0 | 657.3 | 1218.3 | 0.937 |
ZD2 | 1100.0 | 561.0 | 483.4 | 1044.4 | 0.949 |
ZD3 | 1200.0 | 561.0 | 459.0 | 1020.0 | 0.850 |
Average | 1.003 | ||||
Variance | 0.013 |
The bamboo scrimber bars replace the steel bars and are used to strengthen low-cost masonry houses in rural areas, which is environmentally friendly. The bamboo scrimber bar mesh mortar layer can improve the cracking load, ultimate bearing capacity, and stiffness of the brick column under the axial pressure. With the increasing longitudinal bamboo bar ratio, the ductility of the brick column is improved. The strengthening layers improve the crack form and failure mode of the brick column. The four-side strengthening mode gives fullplay to the compressive strength of the bamboo bars compared with the two-side strengthening mode. According to the analysis of the test results, we propose the calculation formula of the axial bearing capacity of the brick column strengthened by bamboo scrimber bar mesh mortar layer. The calculation formula facilitates the application of the strengthening method in the strengthening and transformation of the masonry structures in rural areas.
Some data used to support the findings of this study are included within the article. All datasets generated during the current study are not publicly available because the data also form part of an ongoing study but are available from the corresponding author on reasonable request.
The authors declare that they have no conflicts of interest.
Hongyao Liu and Min Lei contributed equally to this work.
This research was financially supported by the China Scholarship Council (Grant no. CSC201908430245). The opinions and findings in this paper are those of authors and do not represent those of sponsors.