Prefabricated Concrete Component Geometry Deviation Statistical Analysis

'e research objects of this paper were the prefabricated concrete components produced by four enterprises in China, and the dimension deviation data of more than 1400 prefabricated concrete components are measured with high-precision 3D photogrammetry technology. 'e nonparametric Kruskal–Wallis test was carried out for the size deviation of the same type of components produced by different enterprises. 'e distribution characteristics of geometric parameters of typical components of prefabricated structures in China, such as beams, columns, wall boards, and composite slabs, were analyzed by using the probability statistical method. 'e Kolmogorov–Smirnov goodness-of-fit method was used to test the cumulative distribution function of dimension deviation, and the size distribution of fabricated components was studied. 'e results showed that there was no significant difference in the size deviation of the same-type component produced by different enterprises, and the range of geometric parameter uncertainty random variables was small, which was between 0.99 and 1.02. Also, the fluctuation was small, the coefficient of variation was below 0.0093, and the variability of component size deviation was small. 'e transverse dimension of the component shows a positive deviation, the vertical dimension of component shows a negative deviation, and the dimension deviation of prefabricated concrete components follows the normal distribution.


Introduction
Prefabricated building is one of the important directions of building structure development, which is conducive to the development of building industrialization. As a crucial part of the prefabricated concrete (PC) structure, the quality of prefabricated components plays an important role in the overall structural performance [1]. In terms of the splicing structure of prefabricated components, if the size of prefabricated components is too large, it would be difficult to assemble and if the size is too small, the joints between components would be too large, causing water seepage problems. From the aspect of stress performance, when analyzing the reliability of the structure according to the probability limit state design method, the failure probability of the structural part or its corresponding reliability index is used as the measurement, and the geometrical dimension variable is one of the aspects that affect the resistance of the structural part. Moreover, contemporary buildings have become lighter and more vulnerable to building movement and subsequent geometric changes [2]. e lack of uniformity of accuracy between factory-made and in-situ components and the higher level of building movements in the contemporary building are two major factors that affect the dimensional and geometric accuracy of buildings [3]. e conversion of a good design into a good product (e.g., a building) is a matter of keeping dimensional and geometric variations within tolerances that are predetermined at the design stage [4]. e acceptability of a product depends on whether its variations in size and geometry fall within set limits; thus, the bridge between design and production is tolerance. In other words, tolerances interlink design with construction because without specifying the tolerances, it is not clear whether components and subassemblies (i.e., connections of two or more components) meet the design intent regarding the accuracy of the final product [5].
At present, there are many quality control standards for fabricated components, such as German DIN18203 and DIN18202 standards, Japanese JASS10, American MNL-116 and ACI regulations, and Chinese standards GB/T51231-2016 and GB/T 51232-2016 [6][7][8][9][10]. Each standard specifies the dimensional deviation of prefabricated components. ese standards usually determine the allowable value of dimensional deviation based on traditional experiences [11], and the deviation allowable value for prefabricated components is strictly controlled and appropriately modified based on the relevant specifications of cast-in-place concrete. Scholars do not pay attention to the prefabricated component manufacturers' production capacity and have not systematically investigated the dimensional deviation of prefabricated components [12]. To determine the reliability of the concrete structure design, in the 1970s and 1980s [13], a survey of the size deviation of cast-in-place concrete structures was conducted in China [13]. Liu et al. [11] conducted the statistical investigation on the size deviation of cast-in-place concrete structures in Beijing and suggested adjusting the size deviation acceptance index, while Mao and Shi [14] conducted the statistical investigation and analysis on the section size and axis position of cast-in-place concrete structures, and they believed that the deviation of concrete section size obeys the normal distribution, yet the axis position deviation obeys the logarithmic distribution. Nowadays, there are many types of research on the size deviation of cast-in-situ structures, but there are quite few statistical studies on the size deviation of prefabricated concrete components. erefore, it is of great significance to systematically investigate the size deviation of fabricated components.
In this paper, the dimensions of fabricated concrete components of different companies in China are measured by 3D photogrammetry technology, obtaining a database of wall board, composite slab, beam, and column size deviation. e dimensional deviation distribution characteristics of fabricated components are analyzed.

Overview of Sample Acquisition.
e focus is mainly on the component forms existing in prefabricated building structures: beams, columns, wall panels, and composite slabs. In terms of survey objects, components produced by prefabricated component factories in different regions of China are mainly selected. Random sampling is used for each type of component. Detailed information about the number of survey samples is shown in Table 1.

Measurement
Method. Prefabricated building production and installation have higher precision requirements than traditional cast-in-situ concrete structures. e traditional measurement method for prefabricated concrete buildings is mainly using steel rulers, and there are problems with the use of steel rulers in measuring the dimensions of prefabricated concrete components, such as insufficient accuracy, large errors, and difficulty in measuring the edge corners of the component dimensions. e HL-3DP is a medium-range photogrammetry scanner type. It was designed for medium-space applications such as building, civil and survey, and forensics. ree-dimensional photogrammetry known as HL-3DP was applied for prefabricated concrete, and the scanned data were managed with their associated software HOLON3DP. HL-3DP is a high-accuracy and medium-range photogrammetry system. It is associated with a high-resolution camera. Table 2 shows the specification of HL-3DP. erefore, in this article, HL-3DP three-dimensional photogrammetry was adopted to collect sample data. Figure 1 shows the on-site measurement of prefabricated components. e relative error of this method is less than 5%, and the absolute error is less than 0.01 mm. e measurement of the size of the prefabricated component, thus, resulted in high precision in terms of both experimental error and measurement accuracy.

Accuracy Assessment.
Accuracy assessment was also performed in this study. e findings show that the 3D photogrammetry of HL-3DP can provide high accuracy of the building structure. To get a systematic accuracy assessment, the evaluation of the estimate accuracy was carried out using equation (1), where x represents each value in the dataset, x represents the mean of all values in the dataset, and n represents the number of value in the dataset.
e root-mean-square error (RMSE) was used to measure the differences between values observed. According to Mao and Shi [14], RMSE is commonly used in the research field to describe the accuracy of features and it is acceptable to measure the error and estimate the quality of features. e lower the RMSE value, the better the accuracy. Table 3 shows the dimensional measurement difference between the measuring steel tape and photogrammetry system. Meanwhile, the analysis for this study included the comparison of measurement between the photogrammetry system and conventional method (measuring steel tape) with the design value. e comparison is performed and recorded in Table 4. e RMSE value of the photogrammetry system data was 0.60 mm while that of the measuring steel tape method was 0.94 mm. As the result, the tolerance of the photogrammetry system model is well within the 0.01millimeter level. e photogrammetry system model has a lower tolerance compared to the measuring steel tap. is proved that the photogrammetry system method was accurate.

Results of Sample Collection
In the process of statistical analysis of the geometric parameters of the components, because the design dimensions of the components are not the same, to analyze and compare the variation of the dimensions described by the uncertainty of the geometric parameters with the random variable K A [15], which can be expressed as shown in equation (2), where a is the actual value of the geometric parameter of the component and a K is the standard value of the geometric parameter of the component (usually the design value), When analyzing the variability of the geometric dimensions of components, variables such as length, width, and height are regarded as independent random variables.
Taking the same type of component produced by the same enterprise as a matrix, its statistical parameters are analyzed with a subsample of capacity n > 50. Integrating the statistical analysis results of various enterprises, the weighted average of the same type of component size variation is used to reflect the variation level of geometric dimensions. is paper is based on the measured data, and the number of subsamples participating in the statistical analysis is the weight (the capacity is n) [16]. Statistical parameters of random variables with uncertain geometric dimensions of various components were obtained as follows: where n i is the subsample capacity of the geometric characteristic value of a certain construction unit, μ K A is the average value under capacity n i , and δ K A is the coefficient of variation under n i capacity. According to equations (2) and (3), the statistical parameters of the random variable of the geometric parameters of the component can be obtained.

Analysis of Acquisition Results.
Taking prefabricated concrete components produced by different companies as the research object, analyzing the difference in geometric uncertainty of component size in different enterprises, and calculating the average production component K A maximum, minimum, upper, and lower quartiles of each enterprise production, Figures 2-5 give a comparison of box plots. e figures show the different production enterprise production ranges of similar artifacts are similar, both in the range of 0.99 to 1.02. e abnormal port of beam members accounted for 3.4%, the abnormal points of column members accounted for 0.8%, the abnormal percentage of wall slabs accounts for 3.4%, and the abnormal percentage of composite slab slabs accounts for 1.2%. ere are fewer abnormal points, which indicates that the variability of component size deviation in the actual production process is small. e volume of the box body represents the dense and discrete degree of data distribution in the group. e length and width of beams, columns, wall panels, slabs, and width values K A of the box body are relatively short, and the fluctuation is small. Table 5 shows the comparison results of the K A value among similar components of different manufacturers. e horizontal size of the components produced by different enterprises (wall panel height, wall panel width, composite slab length, and composite slab width) dimension uncertainty is less than 1, which is biased towards negative deviation, and longitudinal member dimensions are greater than 1, which are biased toward positive deviation. e size deviation of similar PC components produced by different companies is not large, which proves the reliability of the measured data. Manufacturers have less influence on the size of prefabricated PC  components. e coefficients of variation K A are below 0.0093, and the variation is small, indicating that similar components produced by different companies have the same size characteristics.

Correlation Test of Dimensional Deviation.
With the significant level a � 0.05 as the difference, a single factor analysis of variance on the dimensions of the components produced by the four companies is performed, the differences between the components produced by each factory are discussed, and it is evaluated whether the dimensional deviations of the components can be traced to a certain extent so that the measurement results of different component factories are comparable. e Kruskal-Wallis test [17] infers whether the sample comes from the population median or the distribution pattern is significantly different. is method neither requires the data to obey the normal distribution nor does it require the homogeneity of variance. e Kruskal-Wallis test is a nonparametric test method to test whether multiple population distributions are the same. Firstly, samples in multiple groups are mixed and sorted in ascending order to find the rank of each variabl; if the values show no big difference, it can be considered that the distributions of multiple populations are not significantly different; on the contrary, if the rank means of each group are significantly different, the data of multiple groups cannot be mixed, and if the distributions of multiple samples are significantly different, the statistic constructed by the Kruskal-Wallis test is the K-W statistic, which is pR i ,R, shown as follows: where k is the number of sample groups, N is the total sample size, R i is the sum of ranks of the group I, R i is the average rank of the group I, and R is the total average rank.
Assuming that the distribution of the size deviation of similar components is the same in the company category, if p < a, the null hypothesis is rejected, and the size deviation distributions of similar components produced by different companies have significant differences; on the contrary, if p > a, then accept the null hypothesis, which means that the size deviation distribution of similar components produced by different companies has no significant difference. e nonparametric Kruskal-Wallis test was performed by SPSS19.0 software, and the analysis results are shown in Table 6. e significance value of each component size is greater than the significance level of 0.05, accepting the former hypothesis, so there is no significant difference in the size deviation of similar components produced by different

Frequency Distribution of Size Deviation
Since there is no significant difference in the size deviation of the same type components, the size deviations of the sametype components produced by different companies are integrated as a sample of the size deviation, and the distribution law of size deviation is analyzed using histograms and box plots.

Dimensional Deviation Distribution of Prefabricated
Beam Components. Calculating the difference between the measured data and the design value of the prefabricated beam, the sample size is 295, which is divided into 20 groups. e histogram is drawn with the deviation value as the abscissa and the measured frequency as the ordinate, as shown in Figure 6.
As seen in Figure 6, the dimensional deviation distribution histogram for the beam decreases from the center to the sides, and it can be seen from Figure 6 that the dimensional deviation distribution histogram of the beam is a normal distribution. e length deviation of beam components mainly concentrated in the range of 0-6 mm, e most frequent deviation is 2-4 mm, the mean is 3.02 mm, and the variance is 1.91. e width deviation range is mainly concentrated in the range of 0-3 mm, the mean value is 1.57 mm, and the variance is 1.56, e height deviation is mainly concentrated in the range of 0-5 mm, the mean value is 2.44 mm, and the variance is 3.27. e maximum, minimum, upper quartile, lower quartile, and median of the size deviations are compared using box plots, as shown in Figure 7. e characteristic values of the three-dimensional dimensional deviation of prefabricated beam components are all significantly different, and the dimensional deviations are basically positive deviations. ere is no abnormal value in the length dimension deviation, the median is located in the center of the upper and lower quartiles, and the box chart is symmetrical about the median line, indicating that the length dimension deviation is symmetrically distributed. Both height and width deviations have abnormal values. e height deviation abnormal values are concentrated on the smaller value side and the median tends to the upper quartile, indicating that the height size deviation distribution is right-skewed distribution. e width size deviation abnormal values are concentrated on the larger value side and the median tends to the lower quartile, indicating that the width deviation distribution is left-skewed distribution.

Dimensional Deviation Distribution of Prefabricated
Column Components. Calculating the difference between the measured data and the design value of the prefabricated column, the sample size is 374, which is divided into 20 groups. e histogram is drawn with the deviation value as the abscissa and the measured frequency as the ordinate, as shown in Figure 8. As seen in Figure 8, the dimensional deviation distribution histogram for the column decreases from the center to the sides, and it can be seen from Figure 8 that the dimensional deviation distribution histogram of the column is a normal distribution. e length deviation of the column components mainly concentrated in the range of −5-1 mm, the most frequent deviation is −3-1 mm, the mean value is −2.05 mm, and the variance is 3.74; the width deviation mainly concentrated in the range of −1-3.5 mm, the most frequent deviation is 0.7-1.5 mm, the mean value is 1.34 mm, and the variance is 1.21; the height deviation is mainly concentrated in the range of −2-5 mm, the most frequent deviation is 1.5-2.5 mm, the average is 1.88 mm, and the variance is 4.34. e maximum, minimum, upper quartile, lower quartile, and median of the size deviations are compared using box plots, as shown in Figure 9. e characteristic values of the threedimensional dimensional deviation of prefabricated column components are all significantly different. ere is no abnormal value for the width dimension deviation, the median deviation of width is located in the center of the upper and lower quartiles,  and the square box chart is symmetrical about the median line, which means that the dimension deviation is symmetrically distributed. e abnormal values of height deviation are concentrated on the side of the larger value, and the median deviation tends to the upper quartile, indicating that the height dimension deviation is right-skewed distribution. Although there are outliers on both sides of the length deviation, the box chart is symmetrical about the median, and the proportion of the outliers in the upper and lower quartiles is consistent; therefore, it can be considered that the length deviation is symmetrical.

Dimensional Deviation Distribution of Prefabricated Wall Panel Components.
Calculating the difference between the measured data and the design value of the prefabricated wall panel, the sample size is 371, which is divided into 20 groups. e histogram is drawn with the deviation value as the abscissa and the measured frequency as the ordinate, as shown in Figure 10. As seen in Figure 10, the dimensional deviation distribution histogram for the wall panel decreases from the center to the sides, and it can be seen from Figure 10 that the dimensional deviation distribution histogram of the wall panel is a normal distribution. e height deviation size of prefabricated wall panels is mainly concentrated in the range of −5-0 mm, the most frequent deviation is −3.5-2.8 mm, the average is −2.39 mm, and the variance is 2.91. e width deviation mainly concentrated in the range of −3-0.5 mm, the most frequent deviation was −1-0.6 mm, the mean value was −1.13 mm, and the variance was 1.57. e thickness deviation is mainly concentrated in the  Mathematical Problems in Engineering range of −1.5-4 mm, the most frequent deviation is 1.0-1.6 mm, the average is 1.81 mm, and the variance is 4.13. e maximum, minimum, upper quartile, lower quartile, and median of the size deviations are compared using box plots, as shown in Figure 11. e characteristic values of the threedimensional dimensional deviation of prefabricated wall panel components are all significantly different. e characteristic values of the wallboard size deviation are significantly different. e height and width deviations are basically negative deviations, and the thickness deviations are basically positive deviations. e abnormal values of height and width deviations are concentrated on the larger value side, and the median deviation tends to the upper quartile indicating that the height dimension deviation and width dimension deviation are right-skewed distribution, and the thickness deviation abnormal values are concentrated on the smaller value side, which means that the thickness deviation distribution is left-skewed distribution.

Dimensional Deviation Distribution of Prefabricated
Composite Slab Components. Because the thickness direction of the composite slab is cast-in-place concrete, the thickness of the composite slab is not counted. Calculating the difference between the measured data and the design value of the prefabricated composite slab components, the sample size is 401, which is divided into 20 groups. e histogram is drawn with the deviation value as the abscissa and the measured frequency as the ordinate, as shown in Figure 12. As seen in Figure 12, the dimensional deviation distribution histogram for composite slab decreases from the center to the sides, and it can be seen from Figure 12 that the dimensional deviation distribution histogram of the composite slab is a normal distribution. e length deviation size of the composite slab is mainly concentrated in the range of −5-0 mm, the most frequent deviation is −2.6-2.0 mm, the mean value is −2.44 mm, and the variance is 2.21; e width deviation mainly concentrated in the range of 0-3 mm, the most frequent deviation is −2.5-2.0 mm, the mean value is 1.34 mm, and the variance is 1.21. e maximum, minimum, upper quartile, lower quartile, and median of the size deviations are compared using box plots, as shown in Figure 13. e dimensional

Frequency Distribution Inspection of Dimensional
Deviation. In statistics, the Kolmogorov-Smirnov test (KS test) [18,19] is used to test whether two empirical distributions are the same or whether one empirical distribution is different from another ideal distribution. Assuming that X 1 , X 2 , . . . , X N and Y 1 , Y 2 , . . . , Y N are two Among them, S X (x) and S Y (x) are the cumulative distribution functions of the two samples, respectively. If the value of D is small, it can be judged that the two samples are from the same population. Taking into account that the versatility of the normal probability distribution to random variables and the general significance of Weibull's theory in analyzing the size effect of concrete [20], these two probability statistical distributions are compared with the size deviation values of fabricated components. By using Matlab, the normal distribution function y � normrnd(X, σ, m, n) is used to generate a sample that conforms to the normal distribution with the average value X and the standard deviation σ.
e Weibull distribution function y � weibrnd(X, a, b) is used to generate a sample that conforms to the Weibull distribution with X as the average, where a is the scale parameter and b is the shape parameter. Intuitively, the length deviation cumulative distribution and the width size deviation fit well with the normal distribution, but are significantly different with the Weibull distribution. In the deviation distribution of wallboard height and wallboard thickness, the Weibull cumulative distribution and the normal cumulative distribution function curve are in good agreement. To accurately compare and determine the best distribution, it is necessary to further calculate the maximum absolute deviation among the theoretical distribution function, the empirical distribution function, and the probability P of making the first type of error. e specific results are shown in Table 4. Among them, D is calculated according to equation (6), and the value of P is calculated under the hypothesis of the Kolmogorov distribution of the limit distribution of D.
e KS test results of size deviation frequency, normal distribution, and Weibull distribution are shown in Table 7. It can be seen from Table 7 that, in the two distributions, the maximum absolute value of the normal distribution D is the smallest, and the P value of the normal distribution is the smallest. If the significance is taken at the level of 0.05, the fitting effects of normal distribution and Weibull distribution are both acceptable, and it is obvious that the former is  better. It shows that the dimensional deviation of fabricated components conforms to the null hypothesis and normal distribution.

Conclusions
In this paper, three-dimensional surveys of more than 1,400 prefabricated components in China were carried out, and the geometric parameters of the components were statistically analyzed using probability and statistics methods, hence obtaining the following conclusions: (1) e range of the geometric parameter uncertainty random variable of the same component size produced by different enterprises shows little difference and the fluctuation is small, ranging from 0.99 to 1.02. e geometric parameter uncertainty coefficient of variation is below 0.0093, and the component size deviation variability is small.
(2) e significance of the correlation degree of the prefabricated component size deviation is greater than the level of 0.05, and there is no significant difference among the size deviations of similar components produced by different companies. (3) e histogram of the frequency distribution of prefabricated component size deviation decreases from the center to both sides, and the fitting curve has only one peak. e geometric uncertainties of the transverse dimensions of the components are all less than 1, which tend to be negative deviations, and the geometric uncertainties of the longitudinal dimensions are all greater than 1, which tend to be positive deviations. (4) e size deviation of fabricated components does not refuse to obey the normal distribution and the Weibull distribution, but it is more inclined to obey the normal distribution.
Data Availability e [xls] data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.