Validation of Selected Non-Destructive Methods for Determining the Compressive Strength of Masonry Units Made of Autoclaved Aerated Concrete

Minor-destructive (MDT) and non-destructive (NDT) techniques are not commonly used for masonry as they are complex and difficult to perform. This paper describes validation of the following methods: semi-non-destructive, non-destructive, and ultrasonic technique for autoclaved aerated concrete (AAC). The subject of this study covers the compressive strength of AAC test elements with declared various density classes of: 400, 500, 600, and 700 (kg/m3), at various moisture levels. Empirical data including the shape and size of specimens, were established from tests on 494 cylindrical and cuboid specimens, and standard cube specimens 100 mm × 100 mm × 100 mm using the general relationship for ordinary concrete (Neville’s curve). The effect of moisture on AAC was taken into account while determining the strength fBw for 127 standard specimens tested at different levels of water content (w = 100%, 67%, 33%, 23%, and 10%). Defined empirical relations were suitable to correct the compressive strength of dry specimens. For 91 specimens 100 mm × 100 mm × 100 mm, the P-wave velocity cp was tested with the transmission method using the ultrasonic pulse velocity method with exponential transducers. The curve (fBw–cp) for determining the compressive strength of AAC elements with any moisture level (fBw) was established. The developed methods turned out to be statistically significant and can be successfully applied during in-situ tests. Semi-non-destructive testing can be used independently, whereas the non-destructive technique can be only applied when the developed curve fbw–cp is scaled.


Introduction
Significant variations in materials, technology, and performance cause that masonry structures are much more difficult to be diagnosed than concrete or reinforced concrete, for which the standard EN 13791:2011 [1] specifies both the methodology of tests and conclusions. Regarding masonry structures, there are no standards that classify testing methods. Methods which directly determine compressive or shear strength of a wall, are commonly assumed as destructive testing (DT). Those studies consist in testing fragments of a masonry wall [2,3]. Destructive (direct) techniques use fragments of walls or flat jacks in bed joints, and deliver test results in the form of compressive strength of the wall f k . These methods cause quite a significant damage to the wall. Consequently, the number of tests to be performed becomes sharply limited.
Non-destructive testing (NDT) conducted on masonry walls, which is per analogiam to reinforced concrete structure, include the following methods: sclerometric method, ultrasound method, and pull-out method, which are not commonly used and have not been normalized so apart from general relations specified in standards, do not contain detailed references expressed as empirical relations.
There are no procedures for determining specific compressive strength of the existing masonry wall with the actual density and moisture content. However, in some situations, drilling micro-cores, and even performing sclerometic tests is impossible. Therefore, only ultrasonic non-destructive techniques can be used to determine compressive strength.
The main aim of this article was to present the complex analysis of strength issues, which included developing empirical relations to determine compressive strength f b on the basis of tests performed on specimens of any shape and real moisture content, and to develop the universal curve representing ultrasound velocity c p and compressive strength, taking into account moisture content.
This article describes an attempt to establish the empirical curve for determining the normalized compressive strength of the AAC masonry unit, with unspecified density and moisture content f Bw using semi-non-destructive techniques. Neville's curve [20], in the commonly known form from diagnosing ordinary concrete, was used and calibrated to nominal density classes of AAC (400, 500, 600, and 700). Knowing that, apart from the effect of rising and hardening [25,26], also moisture content in AAC influences the compressive strength, tests were performed and additional empirical relations were defined. The analysis included test results [27] from 494 + 127 cylindrical and cuboid specimens used to develop empirical curves. Results obtained from destructive tests on standard cube specimens 100 mm × 100 mm × 100 mm at different moisture content were correlated with results from testing velocity of P-wave generated by point transducers with the transmission method. Developed curves and the test procedure can be employed in a widely understood diagnostic of masonry structures to evaluate the safety of AAC structures.

Specimens, Technique of Tests, and Analysis
Tests included four series of masonry units with thickness within the range of 180-240 mm and different classes of density: 400, 500, 600, and 700, from each 20 masonry units were randomly selected. Six series of cores with varying diameters were taken from each masonry unit. Six series of square specimens having different side length and height were drilled from masonry units using a diamond saw. Cuboid specimens included blocks with dimensions of 100 mm × 100 mm × 100 mm, which were used as basic specimens for determining the strength f B (in accordance with Appendix B to the standard EN 771-4 [16]). Drilled core and cube specimens are illustrated in Figure 1. All specimens drilled from blocks were dried until constant weight at a temperature of 105 • C ± 5 • C (for at least 36 h).
Depending on the specimen size, loading rate was 2400 N/s or 100 N/s. Due to the size of specimens, two types of machines having an operating range of 100 kN and 3000 kN, and the class of accuracy of 0.5, were used (according to EN 772-1 [28]; Figure 2). Compressive strength f B was determined for cube specimens 100 mm × 100 mm × 100 mm (dried until constant weight). The summary of our test results for core and cube specimens is shown in Tables 1 and 2. Tables show dimensions and strength of each tested specimen, average strength and coefficient of variation for each tested series. Arrows indicate the direction of AAC growth. When dried until constant weight, each cuboid specimen was weighed and its apparent density was calculated (Table 3). . Specimens before tests [27]: (a) core specimens, and (b) cube specimens. Figure 1. Specimens before tests [27]: (a) core specimens, and (b) cube specimens.
Materials 2019, 12 FOR PEER REVIEW 9 cracks developed at the upper edges, and they formed two truncated pyramids at failure ( Figure  3a). In specimens with slenderness ratio h/d = 2, a vertical crack in the mid-length of the base appeared first, and then secondary diagonal cracks formed near corners of specimens ( Figure 3b). The arrangement of cracks in specimens of bigger volume at failure was similar to dense specimens ( Figure 3c).
(a) (b) Figure 2. Testing compressive strength of AAC specimens [27]: (a) tests on cores using a strength testing machine with an operating range of 100 kN, and (b) tests on cuboid specimens using a strength testing machine with an operating range of 3000 kN.

Figure 2.
Testing compressive strength of AAC specimens [27]: (a) tests on cores using a strength testing machine with an operating range of 100 kN, and (b) tests on cuboid specimens using a strength testing machine with an operating range of 3000 kN.    Development of cracks in cuboid specimens of different dimensions was recorded with an optical measuring system ( Figure 3). In dense specimens with slenderness ratio h/b = 1, diagonal  Development of cracks in cuboid specimens of different dimensions was recorded with an optical measuring system ( Figure 3). In dense specimens with slenderness ratio h/b = 1, diagonal cracks developed at the upper edges, and they formed two truncated pyramids at failure (Figure 3a). In specimens with slenderness ratio h/d = 2, a vertical crack in the mid-length of the base appeared first, and then secondary diagonal cracks formed near corners of specimens ( Figure 3b). The arrangement of cracks in specimens of bigger volume at failure was similar to dense specimens (Figure 3c).

Determining an Empirical Curve in Air-Dry Conditions
If strength of the material depends on its defects, such as pores or voids, then individual specimens of different shapes can have significantly different values. These aspects are covered by Weibull's statistical theory of material strength [29,30], which states that strength of the material is reversely proportional to the volume of the tested specimen at the same probability of failure: where σ 1 and σ 2 are failure stresses for specimens with volume V 1 and V 2 , respectively; m is constant. The exponential type of Equation (2) is similar to hyperbole and is used during tests on compressive and tensile strength of dense specimens. Neville [20] developed a similar hyperbolic relation with regard to its course, while testing specimens of different slenderness. This relation is used to determine compressive strength of concrete in specimens with shape and dimensions different from those of standard specimens (blocks 150 mm × 150 mm × 150 mm). The empirical curve for ordinary concrete is expressed as: where V is specimen volume, h is specimen height, and d is the smallest side dimension of the specimen.
Replacing strength f c,cube150 obtained from standard specimens 150 mm × 150 mm × 150 mm with strength f B for specimens 100 mm × 100 mm × 100 mm drilled from masonry units, and the ratio 152hd with volume of the standard specimen 100hd, the relationship (3) can be expressed as: where f B is the compressive strength of normalised specimen 100 mm × 100 mm × 100 mm with moisture content w = 0, f c is the compressive strength of a specimen with any shape and dimensions, and moisture content w = 0, a and b are constant coefficients for the curve, y = f c / f B is the ratio of compressive strength, and x = V/(100hd) + h/d is the dimensionless coefficient representing the effect of specimen volume and slenderness. Requested parameters of the curve (4) were determined by searching a local minimum sum of squares difference: using the following relationships: When the system of linear equations was differentiated and solved, the following relations were obtained expressed in the form facilitating the construction of a correlation table: For defining compliance of the curve, some uncertainty was assumed to be neglected during measurements x (the specimen geometry). Additionally, uncertainties of all y values were the same (the same significance of measurements resulting from identical measuring techniques). To estimate the coefficient of correlation, the following values were calculated: -error of estimate where: -sum of errors: and then coefficient of correlation: The paper [27] compares curve correlations developed for cuboid and cylindrical specimens. Obtained values of curve coefficients a and b are compared in Table 4. Comparison of test results and the common curve is shown in Figure 4.
For defining compliance of the curve, some uncertainty was assumed to be neglected during measurements x (the specimen geometry). Additionally, uncertainties of all y values were the same (the same significance of measurements resulting from identical measuring techniques). To estimate the coefficient of correlation, the following values were calculated: -error of estimate where: and then coefficient of correlation: (12) The paper [27] compares curve correlations developed for cuboid and cylindrical specimens. Obtained values of curve coefficients a and b are compared in Table 4. Comparison of test results and the common curve is shown in Figure 4. When specimens 100 mm × 100 mm × 100 mm were used, the value of curve dominator was V/100hd + h/d = 2, and strength ratios calculated according to equations from Table 4 were fc/fB ≠ 1. To obtain the ratio fc/fB = 1 from normalized specimens, curves needed to be translated in parallel to the intercept axis using the additive correction factor Δb for the common curve: When specimens 100 mm × 100 mm × 100 mm were used, the value of curve dominator was V/100hd + h/d = 2, and strength ratios calculated according to equations from Table 4 were f c /f B = 1.
To obtain the ratio f c /f B = 1 from normalized specimens, curves needed to be translated in parallel to the intercept axis using the additive correction factor ∆b for the common curve: To demonstrate the correct scaling of curves, the approximate variance correlation test was applied. This approach is also adequate for linear and non-linear correlations [31]. Statistical values were calculated for each curve from Table 4 using the following formula: where degrees of freedom were f 2 = n − k − 1 and f 1 = k (k = 1), and the assumed statistical significance α = 5%. The obtained statistical values were compared to critical values from the Fisher-Snedecor tables (F α,f1,f2 ). Statistical results are presented in Table 4. Analyses demonstrated that correlations were significant at the assumed statistical significance equal to 5%, thus the proposed model based on the general Neville relation was statistically significant. Besides, descriptive statistics based on the Guillford scale [32] was applied. It describes the correlation degree of individual curves. For concrete with the lowest density, obtained values R were sufficient for evaluating the relationship as poor, and for other classes of density R > 0.5, correlations could be regarded as moderate and the value of correlation factor as real. For the common curve, the obtained coefficient was R = 0.512. Thus, the relationship was moderate and real.

Calibrating a Curve in Air-Dry Conditions
Many curves developed for specific density of AAC were replaced with a curve that was more favourable for diagnostic purposes and could be used to determine the strength of AAC with any density and moisture content. Coefficients a and b determined for concrete with specific density within the defined ranges and presented in Table 4, as well as coefficients a w and b w of the common curve were used to develop correlations illustrated in Figure 5.
Materials 2019, 12 FOR PEER REVIEW 13 within the defined ranges and presented in Table 4, as well as coefficients aw and bw of the common curve were used to develop correlations illustrated in Figure 5.
where: aw = 0.321, and bw = 0.730 (see Table 4). The formation of AAC curve with any density, when a and b values have been determined, requires a correction for the coefficient b which results in the strength ratio obtained from the curve (13) at V/(100hd) + h/d = 2.

Calibrating an Empirical Curve in Moisture Conditions
Properties of AAC and ordinary concrete depend on moisture contents [25,33,34], which cause a clear reduction in compressive and tensile strengths, and degradation of insulating parameters. Thus, other tests also focused on the effect of moisture content in AAC, which was a ratio of absorbed water to the mass of dry material: where mw is the mass of wet specimen, and ms is the mass of specimen dried until constant weight. The maximum moisture content (absorbality) wmax in AAC corresponded to the level of water, at which no further increase in mass mw was observed as the effect of passage of (capillary) water. Relative moisture was calculated as the ratio of current and maximum moisture w/wmax.
The total number of 127 specimens 100 m × 100 m × 100 m, divided into five six-element series, was prepared from AAC blocks with varying densities. Each specimen was put into containers The following relationships describing curve coefficients as a function of AAC densities were developed on the basis of results shown in Figure 5, using the method of least squares: where: a w = 0.321, and b w = 0.730 (see Table 4). The formation of AAC curve with any density, when a and b values have been determined, requires a correction for the coefficient b which results in the strength ratio obtained from the curve (13) at V/(100hd) + h/d = 2.

Calibrating an Empirical Curve in Moisture Conditions
Properties of AAC and ordinary concrete depend on moisture contents [25,33,34], which cause a clear reduction in compressive and tensile strengths, and degradation of insulating parameters. Thus, other tests also focused on the effect of moisture content in AAC, which was a ratio of absorbed water to the mass of dry material: where m w is the mass of wet specimen, and m s is the mass of specimen dried until constant weight.
The maximum moisture content (absorbality) w max in AAC corresponded to the level of water, at which no further increase in mass m w was observed as the effect of passage of (capillary) water. Relative moisture was calculated as the ratio of current and maximum moisture w/w max .
The total number of 127 specimens 100 m × 100 m × 100 m, divided into five six-element series, was prepared from AAC blocks with varying densities. Each specimen was put into containers filled with water to saturate it with water as the effect of passage of (capillary) water. Specimens were weighed every 6 h and moisture content w was calculated each time. Maximum moisture content in each type of AAC was assumed to be determined at first, and then specimens were dried until the required moisture content. Strength tests were expected to be performed at the following levels of relative moisture: w/w max = 100%, 67%, 33%, 23%, 10%, and 0%. Average test results for individual series of specimens are shown in Table 5.
Maximum moisture content in AAC depended on nominal density. At the density increase in the range from ρ = 397 kg/m 3 to 674 kg/m 3 , the maximum moisture content was varying within w max = 53.3-89.9%, which made it possible to determine a straight line of the least square in the following form: w max = −1.23 ρ 1000 + 1.34 when 397 kg/m 3 ≤ ρ ≤ 674 kg/m 3 .
At each moisture level, destructive tests were performed to determine the strength of wet concrete f Bw , and the results are illustrated in Figure 6a as a function of moisture w. Figure 6b presents the obtained strength values with respect to the strength f B of dry (w = 0) AAC as a function of relative moisture w/w max .
Two empirical lines were drawn on the basis of obtained results and used to determine the relative strength of AAC as a function of relative moisture in the following form: Strength f Bw calculated from Equations (18) and (19) included the moisture effect, so it did not require conversion to average normalized compressive strength f b .
Materials 2019, 12 FOR PEER REVIEW 14 levels of relative moisture: w/wmax = 100%, 67%, 33%, 23%, 10%, and 0%. Average test results for individual series of specimens are shown in Table 5. Maximum moisture content in AAC depended on nominal density. At the density increase in the range from ρ = 397 kg/m 3 to 674 kg/m 3 , the maximum moisture content was varying within wmax = 53.3-89.9%, which made it possible to determine a straight line of the least square in the following form: At each moisture level, destructive tests were performed to determine the strength of wet concrete fBw, and the results are illustrated in Figure 6a as a function of moisture w. Figure 6b presents the obtained strength values with respect to the strength fB of dry (w = 0) AAC as a function of relative moisture w/wmax.
Two empirical lines were drawn on the basis of obtained results and used to determine the relative strength of AAC as a function of relative moisture in the following form: Strength fBw calculated from Equations (18) and (19) included the moisture effect, so it did not require conversion to average normalized compressive strength fb.    Figure 6b also shows the value of factor ηw = 0.8 recommended by the standard EN 772-1 [19], and used to take into consideration the effect of moisture level. The standard recommendation provides the safe reduction of compressive strength only for the moisture level w/wmax = 0.2. Tests on walls with higher moisture content showed that compressive strength could be even reduced by 40%, that is, over twice more than the provisions recommend.  Figure 6b also shows the value of factor η w = 0.8 recommended by the standard EN 772-1 [19], and used to take into consideration the effect of moisture level. The standard recommendation provides the safe reduction of compressive strength only for the moisture level w/w max = 0.2. Tests on walls with higher moisture content showed that compressive strength could be even reduced by 40%, that is, over twice more than the provisions recommend. Test results for wet AAC were not thoroughly analyzed with reference to microstructure. It can be assumed that AAC structure will expand the most at moisture content in a range of 30%, and consequently compressive strength will be reduced. To sum it up, determination of compressive strength of the wall f k required at first, taking into account varying shape and moisture, in-situ estimation of moisture content, specimen drilling, estimation of density, and compressive strength, and then the conversion relevant to moisture. Compressive strength calculated from the Equations (18) or (19) could be substituted to the Equation (1).

Ultrasonic Non-Destructive Method
The application of traditional cylindrical transducers may be difficult, as it requires the agent coupling with the tested surface. Tests on very porous and coarse materials, such as AAC, with cylindrical transducers may be also problematic. Measuring the distance of the wave is also difficult, especially if tests are performed only at one side [35][36][37]. Measurements are simpler and easier to perform when transducers having local contact with concrete are applied. Waveguides for this type of transducers are in cone shape or can be formed according to the exponential curve. As energy produced by ultrasound is lower than in cylindrical transducers with a larger contact surface, the spacing of transducers at one-side access to ordinary concrete with density of ca. 2500 kg/m 3 should not exceed 25 cm, and at both-side access-15 cm [37].

Testing Technique of Specimens
Non-destructive tests on AAC were performed using the ultrasonic testing, commonly applied for testing strength of concrete [38,39], and testing masonry walls [4][5][6]. Ultrasonic testing was conducted on block specimens 100 mm × 100 mm × 100 mm drilled from masonry units (Figure 7). Wet specimens with relative moisture w/w max = 100%, 67%, 33%, 23%, and 10%, and specimens dried until constant weight w/w max = 0% were used in tests. Each series of elements included at least > 20 specimens, and 91 specimens in total were tested.
The PUNDIT LAB instrument (Proceq SA, Schwerzenbach, Switzerland) was utilized for measurements of the ultrasonic pulse velocity. Commercial exponential transducers with the waveguide length L = 50 mm, diameters ø 1 = 4.2 mm and ø 2 = 50 mm, and frequency 54 kHz were employed. The applied research methodology and equipment was also used for testing also for ultrasonic tomography for concrete [40,41] or masonry [42,43].
Each specimen was put on a pad insulating from shock and outdoor noise, and then transducers were applied to walls and the measurement was made with the transmission method. Transducers were in contact with specimens at an angle of 90 • within distance between transducers measured every time with an accuracy up to ±1 mm. Time was measured with an accuracy up to ±0.1 µs. The measurement results are presented in Table 6.
In AAC specimens dried until constant weight, the velocity of ultrasounds was varying from 1847 m/s in concrete of class 400 kg/m 3 to 2379 m/s in concrete of class 700 kg/m 3 . An increase in P-wave velocity c p was also proportional to density increase in wet specimens.
Materials 2019, 12 FOR PEER REVIEW 16 this type of transducers are in cone shape or can be formed according to the exponential curve. As energy produced by ultrasound is lower than in cylindrical transducers with a larger contact surface, the spacing of transducers at one-side access to ordinary concrete with density of ca. 2500 kg/m 3 should not exceed 25 cm, and at both-side access-15 cm [37].

Testing Technique of Specimens
Non-destructive tests on AAC were performed using the ultrasonic testing, commonly applied for testing strength of concrete [38,39], and testing masonry walls [4][5][6]. Ultrasonic testing was conducted on block specimens 100 mm × 100 mm × 100 mm drilled from masonry units (Figure 7). Wet specimens with relative moisture w/wmax = 100%, 67%, 33%, 23%, and 10%, and specimens dried until constant weight w/wmax = 0% were used in tests. Each series of elements included at least > 20 specimens, and 91 specimens in total were tested.
The PUNDIT LAB instrument (Proceq SA, Schwerzenbach, Switzerland) was utilized for measurements of the ultrasonic pulse velocity. Commercial exponential transducers with the waveguide length L = 50 mm, diameters ø1 = 4.2 mm and ø2 = 50 mm, and frequency 54 kHz were employed. The applied research methodology and equipment was also used for testing also for ultrasonic tomography for concrete [40,41] or masonry [42,43].
Each specimen was put on a pad insulating from shock and outdoor noise, and then transducers were applied to walls and the measurement was made with the transmission method. Transducers were in contact with specimens at an angle of 90° within distance between transducers measured every time with an accuracy up to ±1 mm. Time was measured with an accuracy up to ±0.1 µs. The measurement results are presented in Table 6.
In AAC specimens dried until constant weight, the velocity of ultrasounds was varying from 1847 m/s in concrete of class 400 kg/m 3 to 2379 m/s in concrete of class 700 kg/m 3 . An increase in P-wave velocity cp was also proportional to density increase in wet specimens. Figure 7. A test stand for measuring ultrasound velocity: (a) specimen geometry and elements of the stand (given in millimeters), (b) geometry of exponential transducer, and (c) a test stand; 1, tested AAC specimen 100 mm × 100 mm × 100 mm; 2, exponential transducers; 3, cables connecting transducers with recording equipment; 4, recording equipment; and 5, an insulating pad. Figure 7. A test stand for measuring ultrasound velocity: (a) specimen geometry and elements of the stand (given in millimeters), (b) geometry of exponential transducer, and (c) a test stand; 1, tested AAC specimen 100 mm × 100 mm × 100 mm; 2, exponential transducers; 3, cables connecting transducers with recording equipment; 4, recording equipment; and 5, an insulating pad.

Calibrating a Curve in Air-Dry Conditions
Performed tests showed that density and relative moisture affected the velocity of P-waves in AAC. By performing steps described in Section 2.2, at first the correlation curve was determined which presented ultrasound velocity in AAC specimens in air-dry conditions as a function of compressive strength f B . At the beginning, the curve representing the relationship between the average measured ultrasound velocity as a function of compressive strength f Bw of wet AAC, grouping results by AAC density (Figure 8a). Higher sound velocity was found in concrete with greater density and compressive strength. Linear dependence, equations of which are illustrated in Figure 8a, are adequately precise approximations. Figure 8b illustrates results for compressive strength and corresponding ultrasound velocity of dry AAC (w/w max = 0%), selected from each density class of AAC. Then, the relationship c p -f B was calculated with the least square method. For example, Figure 8b also shows the relationship of concrete with maximum moisture content (w/w max = 100%), obtained similarly.
For concrete with moisture content w/w max = 0%, the following empirical relationship was obtained: f B = a c p 2 + bc p + c = 5.73 × 10 −6 c p 2 − 1.46 × 10 −2 c p + 10. For concrete with moisture content w/wmax = 0%, the following empirical relationship was obtained: ( ) ( ) Curve (20) covers results from testing all densities of AAC, where the obtained coefficient of correlation is R 2 = 0.98.

Calibrating a Curve in Moisture Conditions
The practical use of obtained test results required the common curve covering both the varying density of AAC and the moisture impact. For this purpose, the common curve including all moisture levels w/wmax and densities, was found with the least square method (Figure 9a). The equation of the common curve was: Then, equations for individual curves were developed with reference to AAC density. Test results are presented in Table 7. The obtained coefficient values were compared to coefficients aw, bw, and cw for the common curve, and then plotted to the graph Figure 9b.

Calibrating a Curve in Moisture Conditions
The practical use of obtained test results required the common curve covering both the varying density of AAC and the moisture impact. For this purpose, the common curve including all moisture levels w/w max and densities, was found with the least square method (Figure 9a). The equation of the common curve was: when 1315 m/s < c p ≤ 2379 m/s.
Then, equations for individual curves were developed with reference to AAC density. Test results are presented in Table 7. The obtained coefficient values were compared to coefficients a w , b w , and c w for the common curve, and then plotted to the graph Figure 9b.   A parabolic relation of the compressive strength of wet AAC f bw -c p illustrated in Figure 9a was the same as for ordinary concrete [1]. Linear and parabolic relations were obtained for solid brick [21,44]. Generally, the result was similar to predictions. Taking into account that ultrasound velocity depends on the modulus of elasticity E, Poisson's ratio ν, and density ρ, and connected with the relationship c p = E(1 − ν)/ρ(1 + ν)(1 − 2ν), it was easily demonstrated that greater density caused by moisture content resulted in an increase in the modulus of elasticity. Obtained curves shown in Figure 9b are statistic. High R 2 values represent non-linear correlations. All curves had the minimum at moisture content in the range of w/w max = 0.4-0.5. As a consequence, a difference in results with reference to the common curve will be the biggest. The curve obtained at this moisture content f bw -c p was likely to be shifted downwards. Further studies require additional tests at moisture content in the range of w/w max = 0.4-0.5. Step Description Semi-Non-Destructive Testing Reference Non-Destructive (ultrasonic) Testing Reference 1 Determining moisture content by weight w in AAC at the tested (in-situ) point Equation (16) Determining moisture content by weight w in AAC at the tested point Equation (16) 2 Calculating maximum moisture content w max in AAC Equation (17) Calculating maximum moisture content w max in AAC Equation (17) 3 Drilling specimens from AAC, drying them until constant weight and calculating density ρ -Determining P-waves velocity (c p = L/t,) using the transmission method after measuring the path length L and time t. -4 Calculating coefficients a and b of the empirical curve Equations (14) and (15) Calculating coefficients a and b of the empirical curve Equations (22) (18) and (19) Calculating characteristic compressive strength of AAC masonry Equation (1) 9 Calculating characteristic compressive strength f k of AAC masonry Equation (1)

Conclusions
The preformed tests confirmed the effect of specimen shape on compressive strength in the analyzed type of autoclaved aerated concrete and on the method of specimen failure. Regardless of AAC density, compressive strength determined at specific volumes and slenderness was found to be similar to the strength of standard specimens. The greatest strength was found in specimens with the smallest volume. Compressive strength of specimens with the greatest volume was much lower than in case of standard cube specimens with dimensions of 100 mm × 100 mm × 100 mm.
Maximum moisture content was increasingly reversely proportional to AAC density, and moisture significantly reduced strength with reference to the strength of AAC tested in air-dry conditions. The greatest 30% reduction in compressive strength was observed at moisture content w = 0-30%. This observation was particularly important because moisture content of masonry is ca. 10-15%. Higher moisture levels caused a drop in strength by 10%. AAC moisture coefficient η w = 0.8 recommended by the standard PN-EN 772-1 may give dangerously overestimated strength of masonry with moisture content w > 20%.
The non-destructive ultrasonic testing demonstrated the profound effect of density and moisture. An increase in P-waves velocity was proportional to density of AAC (maximum velocity was 2379 m/s in concrete with density of 700 kg/m 3 , minimum velocity was 1847 m/s in concrete with density of 400 kg/m 3 ). Increasing density of AAC caused a significant reduction of the velocity.
Two complementary techniques were used. The first semi-non-destructive test can determine compressive strength of masonry units based on testing specimens of any shape. This technique can be used independently if at least 18 specimens can be prepared (cf. EN 13791:2009 [1])-like for concrete. The second is the non-destructive ultrasound method, which cannot be generally used without scaling the obtained curve. However, the great advantage of this solution is the reduced number of specimens to be prepared and scaled. The number of six drilled cores or cuboid specimens can be assumed as minimum. After scaling the curve, measurements can be made at any number of points and AAC strength can be determined. Performed tests indicated the impact of AAC density and moisture on both compressive strength and ultrasound velocity. These methods have some material limitations with reference to density 397 kg/m 3 ≤ ρ ≤ 674 kg/m 3