Strength of Hollow Compressed Stabilized Earth-Block Masonry Prisms

Earth represents an ecological building material that is thought to reduce the carbon footprint at a point in its life cycle. However, it is very important to eliminate the undesirable properties of soil in an environmentally friendly way. Cement-stabilized rammed earth, as a building material, has gradually gained popularity due to its higher and faster strength gain, durability, and availability with a low percentage of cement. *is paper covers a detailed study of hollow compressed cement-stabilized earth-block masonry prisms to establish the strength properties of hollow compressed cement-stabilized earth-block masonry. *e test results for masonry prisms constructed with hollow compressed cement-stabilized blocks with two different strength grades and two earth mortars with different strengths are discussed.


Introduction
Earth has been widely utilized as a building material since ancient times [1].As a natural and sustainable construction material, earth has the advantages of low embodied energy, natural moisture buffering [2], low CO 2 emission, high recyclability, and good thermal inertia [3].At present, there are many earth buildings in many countries, including Yemen, Iran, India, and China.It is reported that approximately one-fourth of the world's population lives in dwellings built from raw earth [4], which shows that the importance of earth construction remains very high worldwide.Earth can be used a building material for walls in many ways, such as earth blocks, rammed earth, and cob [5].However, there are a few undesirable properties, such as poor dimensional stability, low strength, brittle behaviour, erosion due to wind or rain, and especially, low resistance to dynamic actions [6][7][8][9][10].ese drawbacks can be reduced or eliminated by stabilizing the soil with stabilizing additives such as cement and lime [11][12][13][14].Among these stabilizing additives, cement is cost-effective and environment friendly.
Generally, cement-stabilized soil is used to make compressed cement-stabilized earth blocks compacted either manually or by hydraulically operated machines.Compressed cement-stabilized earth blocks are the most-used earth building technique and represent a modern evolution of the moulded earth block [15].
Compressed cement-stabilized earth-block construction is currently a popular topic, with growing interest due to its high levels of sustainability and thermal and acoustic performance, the low energy required for production and transport, the decrease in landfill waste, its fire resistance, and the cost of the raw material [15,16].Compressed cement-stabilized earth-block construction is a feasible solution for sustainable buildings in many developed and developing countries because cement-stabilized earth blocks offer a number of advantages, such as simple construction methods and maximal utilization of local materials [17].Much research has been undertaken to investigate the mechanical properties of compressed cement-stabilized earth blocks [18][19][20].e test results show that the effect of adding cement on the compressive stress is quite noticeable.However, most of the research on the mechanical properties of compressed cement-stabilized earth blocks has focused on solid blocks.
In remote mountainous areas and Loess Plateau region in western China, due to the lack of high-performance building materials, a large number of houses have to be built using local earth as building materials, and the local earth is often used to make adobe bricks.However, the strength of these locally made adobe bricks is low, whose raw materials are free and locally available.e seismic behaviour of these buildings built with locally made adobe bricks is poor.In order to use locally made adobe bricks for wide application, it is necessary to develop high-strength adobe bricks to improve the seismic performance of adobe brick structures.
At present, the environmental pollution in China is very serious, and green building materials are increasingly attracting everyone's attention.ere are very large market demands for ecological building materials.Earth, as a natural and sustainable construction material, has gradually attracted people's attention and captured the interest of many researchers in recent years due to its low embodied energies and low life cycle cost.
In order to make full use of locally available natural soil resources and minimize environmental impact, decrease the weight of adobe structures, and improve the construction efficiency, an extensive research program has been carried out at Tianjin Chengjian University.e aim of this project is to develop a type of hollow compressed cement-stabilized earth block (HCCSEB).
e results of this investigation could enrich the data available, documenting the behaviour of hollow compressed cement-stabilized earth-block masonry, and contributed to enlarge the application of hollow compressed cement-stabilized earth blocks when constructing rural houses in remote mountainous areas and Loess Plateau region in western China.
Hollow compressed cement-stabilized earth blocks investigated in the manuscript are intended primarily for the construction of single-storey or two-storey rural houses and were successfully used to build a two-storey building in Tianjin, China, as shown in Figure 1.
is paper presents experiments on the mechanical behaviour of HCCSEB masonry prisms.e HCCSEBs were manufactured from soil taken from Gongyi County in Henan Province, China, and ordinary Portland cement.A single HCCSEB was tested under compression and threepoint bending, and the HCCSEB masonry prisms were tested for compression behaviour and shear behaviour.

Geometry of the HCCSEBs and the Masonry System.
e general dimensions of the HCCSEBs used in this study are 390 mm (length), 190 mm (height), and 190 mm (width).
e face and web shell thickness is 50 mm.ese physical dimensions are the same as those of the hollow concrete blocks used in China, which allows single-and double-layer walls to be built.Two mortars specially designed for HCCSEBs are used in this study, i.e., M5 and M7.5.e details of the mixture proportions for M5 and M7.5 are given in Table 1.
ree cubes of 70.7 × 70.7 × 70.7 mm 3 were cast and tested at 28 days of curing time to determine the compressive strength of each mortar.
e average compressive strength of the three mortar specimens was 6.2 N/mm 2 for mortar M5 and 9.5 N/mm 2 for mortar M7.5.

Materials and Manufacturing of the HCCSEBs.
e used soil was taken from Gongyi County in Henan Province, China, which is located in the East Loess Plateau.e properties of the soil were determined according to Chinese standard GB/T 50123 [21] and are presented in Table 2. e optimum moisture content (OMC) and the maximum dry density (MDD) were 16.5% and 1710 kg/m 3 , respectively, as determined by the standard Proctor test.Ordinary Portland cement of grade 42.5 conforming to GB 175 [22] was selected as a stabilizer, and 5∼10% cement by dry mass of soil was used for the production of the HCCSEBs.
e optimum moisture content (OMC) is an important physical index of soils.e OMC was first determined by the standard Proctor test, and it served as a reference value.When manufacturing the HCCSEBs, cement was added for enhancing the strength of blocks, and it was found that the OMC could not meet the requirements of production process.erefore, the water content was adjusted according to the production process of vibration forming through a large number of trial production.
e HCCSEBs were manufactured by using a Tiger D-Series Concrete Products Machine (Figure 2), which has synchronized vibrators and counter-rotating shafts and provided programmable variable vibration as well as duallayer product capability.e machine has a vibration system, which provides a more uniform wave amplitude from the front to the rear of the mould and creates denser and more homogeneous products.e strength of the HCCSEBs was controlled by adjusting the amount of cement and the moulding pressure.Trial production of two compressivestrength-grade HCCSEBs, i.e., MU5 and MU7.5, was performed by Tianjin Yuchuan Building Materials Co., Ltd.

Methods.
ere are currently no code provisions applicable to HCCSEBs.
erefore, the evaluation of

Advances in Civil Engineering
HCCSEBs is performed according to the requirements specified in the test methods section for concrete blocks and bricks (GB/T 4111-2013) [23] and the standard for testing the basic mechanical properties of masonry (GB/T 20129-2011) [24].e HCCSEBs were tested individually for compression and flexural strength (three-point bending test), and the masonry prisms were tested under compression and shear loading (triplet test).
e HCCSEBs' characteristics are sensitive to their dry density and moisture content.e dry density of the blocks under dry conditions varied within the range from 1243 to 1369 kg/m 3 , and the moisture content ranged from 2.5 to 3.3% in air dry at the time of testing.

Compression Tests of the HCCSEBs.
e compression tests of single HCCSEBs were conducted according to Chinese code GB/T 4111-2013 [23], and the load was applied under load control at a rate of approximately 4 kN/s∼6 kN/s.Six specimen groups were tested, and each group consisted of five HCCSEBs in each strength grade.e top and bottom platens were used as testing platens to avoid cutting and capping the specimens, as shown in Figure 3(a).ese platens have the same shape as the HCCSEBs, which means that they are able to distribute the load uniformly on the top and bottom surfaces of the specimens.

ree-Point Bending Tests of the HCCSEBs.
e threepoint bending tests were performed according to Chinese code GB/T 4111-2013 [23].e specimens were supported by cylindrical metallic rollers featuring a 350 mm span.e load was applied at midspan under load control at a rate of approximately 100 N/s∼1000 N/s, as shown in Figure 3(b).Six specimen groups were tested, and each group consisted of five HCCSEBs in each strength grade.

Compression Tests of Masonry Prisms.
e compression behaviour of the HCCSEB masonry was assessed by means of compression tests on masonry prisms with dimensions of 590 mm (length), 190 mm (width), and 990 mm (height), as shown in Figure 4(a).e masonry prisms were constructed with five courses in a running bond pattern.All the prisms were moist cured for 28 days before testing.ree sets of HCCSEB prisms were designed.One set of prisms was designated A (MU5 HCCSEBs and M5 mortar), another set of prisms was designated B (MU7.5 HCCSEBs and M5 mortar), and the last set of prisms was designated C (MU7.5 HCCSEBs and M7.5 mortar); there were 9 prisms in each set.e axial strain between the top and bottom blocks and lateral strain were measured by means of two dial indicators attached to each face of the masonry prism, respectively.Compression tests of the masonry prisms were performed according to the procedure specified by Chinese code GB/T 50129-2011 [24].

Shear Tests of the Masonry Prisms.
e shear behaviour of the HCCSEB masonry was assessed by means of shear tests on masonry prisms made from three HCCSEBs with average dimensions of approximately 390 × 590 × 190 mm 3 (width × height × thickness) (Figure 4(b)).
e tests were conducted in accordance with Chinese code GB/T 50129-2011 [24].e shear load was applied by means of an actuator parallel to the joints under load control at a rate of approximately 0.2 N/mm 2 per minute.ree sets of HCCSEB prisms were designed.One set of prisms was designated D (MU5 HCCSEBs and M5 mortar), another set of prisms was designated E (MU7.5 HCCSEBs and M5 mortar), and the last set of prisms was designated F (MU7.5 HCCSEBs and M7.5 mortar).ere were six prisms in each group.Six prisms were tested for each mixture, giving a total of eighteen specimens.

Compression Tests of the HCCSEBs.
e test results for single HCCSEBs with strength grade MU5 are presented in Table 3, and the test results for single HCCSEBs with strength grade MU7.5 are presented in Table 4. e  Advances in Civil Engineering nomenclature for the tests of single HCCSEBs under compression was as follows: the first and second characters refer to "MU5 under compression" or "MU7.5 under compression," the third character is the group number, and the fourth character is the specimen number.A typical failure mode of a single HCCSEB tested under compression is shown in Figure 5.
According to the requirements of the Chinese code, when compressing blocks to obtain their compressive strength, it is necessary to carry out six groups of compression tests and each group has five test specimens.Each group of tests corresponds to a coefficient of variation.It could be seen that the mean coefficient of variation of HCCSEBs with strength grade MU5 is 10.57%, and the mean  4 Advances in Civil Engineering coefficient of variation of HCCSEBs with strength grade MU7.5 is 8.63%.us, it is considered that the little variation in strength was observed when the strength of HCCSEBs was higher.

ree-Point Bending Tests of HCCSEBs.
In masonry structures, due to the fact that the surface of the block itself is not flat, the thickness of the laying mortar is not uniform, or the horizontal joint is not full, the single block is not evenly pressed in the masonry and may be in a bent state as shown in Figure 6.In Chinese code "Test methods for the concrete block and brick (GB/T 4111-2013)," there is a clear requirement for the three-point bending test.erefore, the results are presented herein.
Tables 5 and 6 present the results of the three-point bending tests of single HCCSEB with strength grades MU5 and MU7.5, respectively.e nomenclature for the threepoint bending tests of single HCCSEBs was similar to that for the single HCCSEBs under compression except that "T" stands for "three-point bending test."e flexural strength of the specimens was tested in air dry state.e failure of all specimens occurred at the midspan cross section.It can be seen that the mean flexural strength is 0.52 MPa for HCCSEBs with strength grade MU5 and 0.58 MPa for HCCSEBs with strength grade MU7.5.e mean coefficient of variation of the flexural strength exhibited features similar to that of the compressive strength of single HCCSEBs, i.e., the mean coefficient of variation for HCCSEBs with strength grade MU5 is greater than that for HCCSEBs with strength grade MU7.5.
e typical failure mode of a single HCCSEB subjected to a three-point bending test is shown in Figure 7.

Compression Tests of HCCSEB Masonry Prisms.
e responses of HCCSEB masonry prisms to compression were roughly divided into three phases.In the first phase (before the first crack was initiated), no obvious damage was found, and the test specimen was in the elastic state.In the second phase, the cracks initiated, gradually propagated, and tended to merge with increasing loading, and the test specimen was in an elastic-plastic state.In the third phase, vertical cracks propagated quickly, crossing mortar bed joints and blocks, and the bearing capacity of the specimen suddenly decreased and brittle failure occurred.e typical failure mode for the HCCSEB masonry prisms is shown in Figure 8.On the whole, the failure mode of the HCCSEB masonry prisms due to compression is similar to that of ordinary hollow-block concrete masonry prisms.Failures of masonry prisms under    compression are usually caused by a tension crack that propagates through the blocks and mortar in the direction of the applied force.Table 7 presents the results of the compression tests of the HCCSEB masonry prisms.It can be seen that the compressive strength of the HCCSEB masonry prisms could be enhanced by increasing the strength of the mortar or the units.e coefficient of variation for the strength of the three groups of HCCSEB masonry prisms varied between 13.9% and 19.7%, showing that the strength exhibited relatively high scattering.
Relative to Group A, Group B exhibited a 5% increase in the compressive strength, and Group C exhibited a 9% increase in compressive strength compared with Group B, which shows that the effect of the mortar's strength on the mechanical properties of HCCSEB masonry is stronger than those of the HCCSEB's strength.
A predictive model with high prediction accuracy for predicting the compressive strength of HCCSEB masonry is proposed based on multiple regression analysis.e compressive strength f m of the HCCSEB masonry can be calculated using the following equation: where f m is the mean compressive strength of HCCSEB masonry (MPa), f 1 is the mean compressive strength of HCCSEB (MPa), and f 2 is the mean compressive strength of the mortar (MPa).
A comparison of the calculated and measured values for HCCSEB masonry is presented in Table 8.It can be seen that the calculated results are in remarkably good agreement with the measured values.
e stress-strain relationship of masonry is essential for predicting the strength and deformation of masonry structures in analytic modelling.e stress-strain curves for HCCSEB masonry prisms under compression are presented in Figure 9.
e experimental results show that if the compressive stress and strain are normalized with respect to the compressive strength and the peak strain, respectively, the resulting normalized stress-strain curves are close to each other.Normalized stress-strain curves are obtained by using the maximum compressive stress to normalize the compressive stress and the reference strain to normalize compressive strain.e reference strain is defined by the strain corresponding to the maximum compressive stress.
Equations to represent the relationship between the normalized compressive stress and strain were derived using parabolic regression.e best-fit curves are highlighted in red in Figure 9.
e best-fit equations are as follows: (b) (c) It can be seen from Figure 9 that the best-fit curve using the proposed equation is in good agreement with the normalized curve for each specimen; therefore, the parabolic constitutive relation is reasonable.9 presents the results of the shear tests of HCCSEB masonry prisms.It can be seen that the shear strength of the HCCSEB masonry prisms can be improved by increasing the strength of the mortar.

Shear Tests of HCCSEB Masonry Prisms. Table
e coefficient of variation in strength for the three groups of HCCSEB masonry prisms varied between 3.52% and 5.19%, which shows that the strength exhibited relatively low scattering.
e failure of all the specimens experienced shear bond failures at block mortar interface, and the typical failure mode for the prisms is shown in Figure 10, where the middle block slides relative to the left and right blocks.e shear failure of HCCSEB masonry prisms occurs by brittle fracture.When shear bond failure occurred, the bearing capacity was immediately lost, and the blocks themselves remain intact without any damage.

Conclusions
is paper presents an experimental program in which the mechanical behaviour of hollow compressed cementstabilized earth blocks and masonry prisms is assessed.
e mechanical tests performed on single HCCSEBs showed that the mean compressive strength reaches approximately e failure mode of the HCCSEB masonry prisms under compression is similar to that of hollow-block masonry prisms made from ordinary concrete.Failure of masonry prisms under compression is usually caused by a tension crack that propagates through the blocks and mortar in the direction of the applied force.
Triplicate tests showed that the stronger the mortar was, the greater the shear strength was.e failure of HCCSEB triplicate-test specimens occurred at the bed joint where the middle block slides relative to the left and right blocks.Advances in Civil Engineering would like to thank Tianjin Yuchuan Building Materials Co., Ltd., for providing the HCCSEBs for testing.

Figure 1 :
Figure 1: A two-storey hollow compressed cement-stabilized earth-block masonry structure in China.

Figure 2 :
Figure 2: Machine used for manufacturing the HCCSEBs.

Figure 3 :Figure 4 :
Figure 3: Testing of the individual HCCSEBs under (a) compression and (b) three-point bending.

Figure 5 :
Figure 5: Typical failure mode of a single HCCSEB tested under compression.

Figure 6 :
Figure 6: Complex stress state of blocks in masonry structures.

Figure 7 :
Figure 7: Typical failure mode for a single HCCSEB tested under three-point bending.

Figure 8 :
Figure 8: Typical failure mode for the HCCSEB masonry prisms tested under compression.

4. 2
MPa for HCCSEBs with strength grade MU5 and 6 MPa for HCCSEBs with strength grade MU7.5; the mean flexural strength reached 0.52 MPa for HCCSEBs with strength grade MU5 and 0.58 MPa for HCCSEBs with strength grade MU7.5.ese measured mechanical properties were slightly lower than the corresponding design values, which show that the manufacturing technology and the mixtures should be further optimized and improved.

Figure 9 :
Figure 9: Stress-strain curves of masonry prisms in compression.

Figure 10 :
Figure 10: Typical failure mode of the masonry prisms tested under shear loading.

Table 1 :
e mixture proportions of two mortars.

Table 2 :
Summary of the soil properties.

Table 3 :
Compression test results for HCCSEBs with strength grade MU5.

Table 5 :
Flexural strength tests results for HCCSEBs with strength grade MU5.

Table 7 :
e results of the compression tests of HCCSEB masonry prisms.

Table 9 :
e results of the shear tests of HCCSEB masonry prisms.