Abstract

To improve accuracy of safety state evaluation results for ancient timber buildings and to know the real state of the building, a safety grade evaluation model of ancient timber buildings is established based on attribute mathematic theory. From the perspective of macro, micro, qualitative, and quantitative, 22 factors may adversely affect the safety state of ancient timber building are considered in this model. First, evaluation system is established, and evaluation indexes are selected based on former study, seismic damage data, and Chinese current code about ancient timber buildings. In the evaluation system, whole building is divided into four parts, which are wood frame, enclosing wall, foundation, and plinth. Different parts contain different components. Every component has its own evaluation indexes. Second, based on the AHP and entropy method, the comprehensive empowering method is used to determine the weights of the indexes. Third, the attribute recognition model is established to identify the safety grade of components or units. Fourth, based on the evaluation results of components, safety grade of units is identified. Then, safety degree of the entire building is determined by the minimum safety grade of units. At last, the model is applied to the “Liben hall” in village Siping, Zhejiang province, China, and the assessment results are consistent with the results of damage identification.

1. Introduction

Ancient timber buildings play an important role in Chinese oriental culture and civilization. One-third of Chinese cultural relics sites consist of timber buildings [1]. Compared with various modern buildings, such as concrete structure, the bearing system of ancient timber buildings is quite different. Wood is an important load-bearing material for ancient timber buildings. The mechanical properties of wood are complex. Wood is anisotropic material, and different kinds of wood have different mechanical properties. And the mechanical properties of wood material change along with the environment, such as temperature, humidity, time, and so forth [2]. All of this make safety evaluation for ancient timber building becomes harder.

Different kinds of methods have been used to assess safety states of ancient timber buildings, such as finite element simulation, model test, theoretical analysis, stochastic and probabilistic analysis, and nondestructive detection and evaluation. Chen [3] analyzed the structural weakness of Yingxian wood pagoda. FEM models were constructed for the pagoda using ABAQUS. Li [4] built a model of Shang Youge by ANSYS software to study the structural characteristics and seismic performance of ancient wood structure. Xue et al. [5] put up with a seismic damage evaluation model for Chinese ancient timber building by theoretical and experimental methods. Huan et al. [6] proposed a vulnerability analysis method for ancient timber architecture based on probabilistic and Copulas. A shaking table test using a scale model of single-bay palace wood frame was carried out by Zhang [7] to study its dynamic characteristics. Shaking table tests and static lateral loading tests of full-scale traditional wood frame were carried out by Suzuki et al. [8] to study response characteristics of Japanese traditional wood buildings. A shaking table test of 1/5 scale wooden pagoda was carried out by Song et al. [9] to study its dynamic characteristics. Finite element simulation and the model experiment method can fully demonstrate the stress state of ancient wooden structures. The limitations of these two methods make them difficult to apply in the building code. First, the complex structures and properties of wood frames of ancient timber buildings are difficult to simulate by finite element software. Deviation would be caused if the model was simplified. Second, the experimental method costs more money and time, and the deviation caused by the scale effect is hard to predict and estimate. Usually, the wood used in the experiment is nondamaged, which is different from the actual damaged state of the ancient buildings. So, whether the experiment and simulation results can demonstrate the real state of the building or not is hard to evaluate.

Nondestructive test and evaluation have been applied to safety assessment of ancient timber buildings. Three-dimensional stress wave test was carried out by Dai et al. [10] to detect the cavity area of wood components. Resistograph®3450-P/S was used by Huang et al. [11] to detect inside wood decay of ancient architecture, and the relationship between mechanical properties of wood materials and decay levels are analyzed. Typical assessment methods including observation, ruler measurement, nondestructive testing, three-dimensional laser imaging scanning, and finite element analysis were used by Zhou et al. [12] to evaluate the safety levels of Chinese ancient wood structures. Nondestructive testing is intuitionistic and convenient. Internal damage of timber components can be quickly detected. However, the comprehensive effects of all damages on the timber component need further study.

Research studies on mortise and mortise joint of ancient timber structures were conducted by many researchers. Chang et al. [13] studied the factors that affect the rational stiffness of timber joints, and an equation was established to estimate the initial rotational stiffness of timber joints. Column-girder joint specimens were tested by Han et al. [14] to study their mechanical properties. A series of 15 tests of traditional pegged mortise and tenon connections of green oak are conducted by Shanks and Walker [15]; the stiffness and ultimate strength of the tenon under tension, bending, and shear are investigated. King et al. [16] conducted an experiment on three naturally deteriorated joints of traditional Chinese wood frames. Low-cyclic reversal loading tests on damaged dovetail mortise-tenon joints were conducted by Xie et al. [17] to study the aseismic behaviors. Gao et al. [18] investigated the aseismic characteristics of corbel bracket. These studies focus on the joints of traditional wood structures. However, it is rare to find the research about how damage joints affect the safety state of the whole structure.

Chinese ancient timber buildings have been existing for hundreds years, and lots of factors, such as natural disasters, climate, and human activities, may affect their safety sates. In order to consider all the factors into consideration to improve the accuracy of evaluate results, an evaluation method based on attribute recognition theoretical model [19] is proposed in this paper. Attribute recognition theoretical model has been applied into civil engineering. Zhong [20] established a comprehensive evaluation model for existing RC structures based on attribute recognition theoretical theory to evaluate the durability of the structures. He et al. [21] evaluated the structure behavior of dam by attribute recognition theory. However, attribute recognition theoretical theory is rarely used in the field of timber structure and ancient buildings.

This paper purposed an evaluation method for ancient timber building based on attribute recognition theory. First, based on former research studies and seismic data, main parameters affecting the safety state of ancient timber buildings are selected, sorted, and analyzed. Second, evaluation system for ancient timber buildings is established. Third, evaluation model is established to identify the safety states of components by attribute recognition theory. Fourth, the safety states of the whole structure based on the evaluation results are evaluated.

2. Attribute Recognition Theory Model

Attribute recognition theory model includes 3 parts: single index attribute measure analysis, multiple index synthetic attribute measure analysis, and attribute recognition analysis.

Attribute recognition theory model could estimate the influence of various factors on the component at the same time. In the object space , there are components or units, which are , which need to be evaluated. Each component or unit has evaluate indexes, which are . The measured series of values from a component or unit for index is . Let be some attribute space and be an ordered series of safety grades in the attribute space .

2.1. Calculation of Weights of Indexes

Weights are essential for accurate evaluation results. To take full advantage of subjective and objective opinions, combination weights are calculated based on subjective and objective weights. Analytic hierarchy process (AHP) [22] is used to calculate subjective weights of indexes, which is . Entropy weight method (EWM) [23] is used to calculate objective weights of indexes, which is . The combinatorial weights could be calculated by the following equation: and are importance degree of subjective and objective weights, which can be calculated by the following equations:where is the number of evaluation indexes; are members of weight vector; and .

2.2. Single Index Attribute Measure Analysis

The attribute measure of index value , which takes the attribute levels from . Suppose or , then the standard grades of every index can be established, which is shown in Table 1.

Then,

If , single index attribute measure function could bewhere , .

2.3. Multiple Index Synthetic Attribute Measure Analysis

Multiple index synthetic attribute measurements of a component or unit, which is , can be calculated by equation (7) that includes each attribute measure and combination weights.

2.4. Attribute Recognition Analysis

Attribute recognition model could be built based on the weights and synthetic attribute measure of indexes. The model includes confidence criterion , and . Generally [24].

Increase the value of until equation (8) is satisfied, then the component or unit belongs to safety grade .

3. Evaluation System and Classification Standards

3.1. Evaluation System

Based on historical seismic damage data [25], mechanical properties, and Chinese current national codes [2629] of ancient timber buildings, appropriate evaluation indexes are selected. Divide an ancient timber building into four units, which are wood frame, enclosing walls, plinths of columns, and foundation. Units consist of many components. Different components have different evaluation indexes. Totally, 22 evaluation indexes are selected, and the evaluation system is shown in Figure 1.

3.2. Classification Standards of Indexes

Wood frames are the main load-bearing system of an ancient timber building. As service time of the building becomes longer and longer, mechanical property of wood would be decreased [30]. Wood frame of ancient timber building consists of beams, purlins, Fang, column, Dougong, and mortise-tenon joints.

Wood beams and Fang are the vertical structural members bearing the load on the roof and weight of roof. Fang is quite similar with beams, which is used to connect two columns in longitudinal direction of ancient timber building. Components that connect columns in transverse direction are named beams. The horizontal loads are transmitted by beams and Fang in ancient timber buildings. Based on references [2, 31, 32, 33], the deflection, lateral bending, decay area, insect-attacked area, and cracking degree are selected as the evaluation indexes of the beams, purlins, and Fang. According to the damage degree, the beams, purlins, and Fang of an ancient timber building are divided into four safety levels, , , , and ; from to , the damage degree gradually increases. These are listed in Table 2.

Wood columns are the vertical structural member transmitting axial compressive loads in ancient timber building. When earthquake occurs, wood columns also bear the horizontal shear force. With service time increasing, ancient timber buildings would be damaged by long-term load effect and biological and natural factors, such as wind, rain, corrosive gas, mould, and insect. Referring to references [2, 26, 31, 32], bending degree, decay area, insect-attacked area, and cracking degree are selected as evaluation indexes of a column, which is shown in Table 3.

In Table 3, is the semiqualitative and semiquantitative index. In order to improve accuracy of evaluation result, equation is used to quantify . is the weight, and is the depth of the crack. In order to get a reasonable weight, advices from 2 professors, 1 doctor and 1 master, are adopted. Four couple of weights are obtained, which are [0.3,0.7], [0.4,0.6], [0.1,0.9], and [0.3,0.7]. Then, analytical hierarchy process is used to get the final criteria. Judgment matrix is

And the final weight is 0.3 and 0.7. Details are listed in Table 4.

A Dougong is formed by placing a large wooden block (Dou) on top of a column to provide a secure base for an interlocking pair of brackets (gong) above it. These then support subsequent Dou and Gong layers and ultimately a cross beam without glue or fasteners [34]. Dougong is usually used in large wood frame ancient timber buildings, which could support roof and provide a large space for palace at the same time. Usually Dougong is placed on column or beam. Dougong is an important part of ancient timber building for its exquisite shape and seismic capacity [35]. Figure 2 shows a Dougong of Liben hall. Layer of Dougong has good deformability, energy dissipation, and seismic capacity. References [31, 36] show main damages of Dougong are cracks of the components, obliqueness, decay, deterioration, and insect attacks on the wood. Decay, deterioration, and insect attacks on the wood are sorted as a same evaluation index, which is defined as section damage. The details are shown in Table 5.

Mortise and tenon joints are unique connection between columns and beams or Fang of ancient timber buildings. Semirigid characteristics make the joints have good energy dissipation capacity and seismic capacity. Based on references [36, 37], a classification standard for mortise and tenon joints’ damage degree is established. This is shown in Table 6.

The foundations of ancient architecture have existed for at least hundreds of years. Thus, generally uneven settlement of the foundation does not occur. However, some natural disasters such as earthquakes, tsunamis, and mud-rock flows may rock the foundation and affect the safety state of the foundation. Based on the foundation design code of China [38, 39], a safety evaluation index of the foundation of ancient timber architecture is shown in Table 7.

Columns of ancient timber buildings are directly placed on the surface of pier stones. So, the contact area between column foot and plinth is very important for the safety of the whole building. Based on former study [31], a safety evaluation index for plinth in ancient timber architecture is shown in Table 8.

Enclosing walls of ancient timber buildings do not carry or transmit loads. According to Chinese codes [26] and reference [31], weathering degree, tilt angle, and cracks of every single wall are analyzed and chosen as evaluation indexes; the classification standard is shown in Table 9.

3.3. Attribute Measure Function of Single Indexes

In the safety state evaluation process of an ancient timber building, the whole building is divided into different units. Units contain different components. 22 evaluation indexes are selected in this paper, which are shown in Figure 1. Attribute measure functions of single indexes can be built by equations (4)–(6). And , , , , and are qualitative indexes; attribute measure functions are shown in Table 10.

4. Study Case

4.1. Introduction of Liben Hall

Liben hall is located in Siping village, Jinhua city, Zhejiang Province, China. The village is provincial model village for its beautiful environment, distinct cultural characteristics, and history. And the village was named as “historically and culturally famous village of China” in 2010. History of the village can be dated to Ming Dynasty (1368–1644). Now only 8 ancient timber buildings are preserved. Liben hall is one of them. The hall was built in Kangxi period (1662–1722) of Qing Dynasty, which has been standing for hundred years. Long history and sophisticated structure made Liben hall become a famous heritage site in China. Liben hall is a 1 story building with 3 spans. Details are shown in Figures 24.

4.2. On-Site Damage Identification

Some damages are shown in Figure 5. Measuring tape was used to measure perimeters of columns, beams, purlins, and so on. Laser range finder was used to measure spacing and bending degree of columns, beams, Fang, and purlins. A stress wave testing instrument is used to detect the inner damage of components when damages cannot detect from appearance. Because of the imitate space, testing results of 2 columns (Z1, Z2) are shown in Figure 6. And testing results of beam , column , and Dougong are listed as examples shown in Table 10.

4.3. Calculation of Weights of Evaluation Indexes

AHP is used to calculate subjective weights, and EWM is used to calculate objected weights. Combinatorial weights are calculated via equation (7). Judgment matrixes [39] and weights of examples are shown in Tables 1113.

4.4. Calculation of Attribute Measure of Single Index

Based on the testing results and attribute measure functions, the calculation results of single index attribute measure are shown in Table 14.

4.5. Evaluation Results

Comprehensive attribute measures of evaluation indexes are calculated based on equation (7). Confidence criterion, , is used to evaluate the safety state of components. The evaluation results are consistent with the damage identification results [31], which are shown in Table 15.

No uneven settlement was detected. Based on Table 7 and testing results, the evaluation results show that the safety degree of foundation is . Evaluation results of all the components are shown in Figure 6. Reference [31] provides a damage identification method for ancient timber architecture based on seismic construction identification of entire building and damage identification of every component. In order to validate the correctness of this evaluation results, the damage identification method provided by reference [31] is used to evaluate the safety state of Liben hall. Most of the results are consistent with the damage identification results [31] (Figure 7).

4.6. Safety State Evaluation of the Whole Building

As mention above, in this evaluation system, Liben hall is divided into four units. The four units are wood frame, enclosing walls, plinths of columns, and foundation. Figure 6 shows the safety degree of the wood components, and joints are concentrated in and , and the proportion of several components are higher than 50%. Safety levels of units are determined by the distribution of components damage levels.(1)As mentioned above, foundation of the building is in good condition, and safety grade is .(2)Evaluation results show that 5.56% of the plinths’ safety state is , 33.33% is , 50% is and 11.11% is . Half of the plinths’ safety state is , so the safety state of plinth is .(3)Figure 6 shows that 72.73% of walls’ safety state is and 27.27% is . So, the safety state of unit wall is .(4)Unit wood frame consists of columns, Dougong, mortise and tenon joints, beams, and Fang. Most components of wood frame attribute to safety state. 12.5% of Dougong components attribute to , 56.25% attribute to , and 31.25% attribute to . 2.27% of beams, purlins, and Fang attribute to , 31.82% attribute to , 54.55% attribute to , and 31.25% attribute to . 26.14% of mortise and tenon joints attribute to , 51.13% attribute to , and 27.73% attribute to . Columns are vertical load-bearing components, which are very important for wood frame. Figure 6 shows 66.67% of columns attribute to safety state. So, the safety state of wood frame unit is .

Overall, the safety level of entire building is determined by the lowest safety grade of the units. So, the safety grade of Liben hall is .

5. Conclusion

(1)According to the structural characteristics of ancient timber building, seismic damage data, relevant Chinese codes, and researchers’ study results, appropriate evaluation indexes that may influence the safety state of ancient timber building were selected. A safety degree evaluation model for ancient timber building based on the attribute recognition theory was built. This is a new method to assess the safety state of ancient timber architecture.(2)To make sure the evaluation process and results are reasonable and reliable, both qualitative and quantitative indexes were selected to consider the negative effects caused by different components and joints of various damage degrees on the overall safety state of the building in this model. A combination of both subject weight and object weight was adopted in the model.(3)This evaluation model was applied to evaluate the safety state of the Liben hall, which is a famous ancient site in Zhejiang, China. The evaluation result is consistent with the damage identification result and actual situation of the architecture. This proved the correctness of this model.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This study was financially supported by the National Natural Science Foundation of China (Grant nos. 51678017 and 51678005), Beijing Natural Science Foundation (Grant no. 8182008), Beijing Municipal Education Commission Science and Technology General Project (Grant nos. KM201610005029 and KM201810005021), and National Key R&D Program of China (Grant no. 2018YFD1100902-1).