Bayesian networks (BN) have the characteristics of bidirectional reasoning, that is, forward reasoning and reverse reasoning [28]. The inference used to judge the tendency and possibility of system failure in the system design stage is called positive reasoning, and positive reasoning is also called causal reasoning. The reasoning used to determine the main reasons for system failure after a system failure is called reverse reasoning. Reverse reasoning is also known as diagnostic reasoning, according to which reverse reasoning can find the system's weak links to provide a basis for safety management and system design improvement [29,30].

BN is a subjective view based on probability. Suppose X and Y are two random variables, the probability density function (PDF) is P(Y) (P(Y)>0). According to the Bayesian equation, the conditional probability of P(X|Y) can be defined:

(1) P(X|Y)=P(Y|X)P(X)P(Y)

where P(X) is the probability prior distribution. If P(X) has n failure states, i.e., x1,x2,⋯xn, According to the total probability formula the full probability formula, P(Y) can be given by:

(2) P(Y)=∑P(Y|X=xi)P(X=xi)

BN is a representation and reasoning model of uncertain knowledge based on probability analysis and graph theory [27]. When the probability distribution of node variables is known, the Bayesian network can realize qualitative and quantitative uncertainty representation [28]. The Directed acyclic graphs (DAG) and conditional probability tables (CPT) are two parts of the BN model. The DAG can explain the logic structure of BN, which is a part of qualitative analysis [29]. Nodes without parents are called root nodes, nodes without sub-nodes are called leaf nodes, and other nodes are called intermediate nodes. The CPT is used for conditional probabilities under different fault states. The CPT represents the strength of the relationship between nodes which is a part of the quantitative analysis of BN [30].

The BN is depicted in Fig. 1. Here, Xi, (i=1,2,3,4,5) is the root node, which has marginal prior probability. A1 and A2 are intermediate nodes. M1,M2 are leaf nodes. According to the conditional dependence between the events in the Bayesian network, the posterior probability can be easily derived from the prior probability to realize the system reliability evaluation [29]. Using the BN joint fault inference algorithm, the joint probability of all nodes in Fig. 1 could be expressed as Eq. (3):

(3) P(M1,M1,A1,A2,X1,X2,X3,X4,X5)=P(X1)⋅P(X2)⋅P(X3)P(X4)P(X5)⋅P(A1|X1,X2,X3,X4)⋅P(A2|X3,X4,X5)⋅P(M1|A1,A2)⋅P(M2|A2)

When the node state in a Bayesian network goes out of the two-state assumption, i.e., the node has several states, the traditional Bayesian network will be extended to a multi-state Bayesian network. In practical engineering, systems and components often have various fault modes and present different fault states. Reliability modelling of multi-state systems is often based on fault tree analysis using the extended multi-state fault tree analysis method [16]. The CPT of the Bayesian network is reconstructed by using expert knowledge and practical experience so that the logic relationship, uncertainty and multi-state component fault, which traditional Bayesian networks cannot express, are reflected [21]. Therefore, when the Bayesian network is used to deal with the polymorphism of variables, different state values can be selected to represent different fault states of nodes, and only the CPT of corresponding nodes needs to be adjusted [22].

In order to characterize the influence of subjective uncertainty on system reliability due to the lack of system cognition and limited information, some scholars proposed to further extend the continuous node variables of Bayesian networks to fuzzy node variables [31]. When the fault probability of a Bayesian network node is difficult to express with exact value, the fault probability of the node is expressed with a fuzzy subset. The definition of a fuzzy BN node is divided into two steps. The first step is to describe the failure state of the fuzzy node, and the second step is to describe the failure rate of the fuzzy node [32].

In a multi-state BN system, which have n root nodes Xi={X1,X2,⋯Xi,⋯,Xn}(i=1,2,⋯,n). The intermediate node is Yj={Y1,Y2,⋯Yj,⋯,Ym}(j=1,2,⋯,m). The leaf node is Tv={v=1,2,⋯l}. The fuzzy numbers xiki, yjkj and Tv are used to describe the fault states of corresponding nodes at time t. When dynamic fuzzy set of the root node is P˜(xiki) at time t, the dynamic fuzzy possibility of the leaf node T at state Tv can be computed by:

(7) P˜T=TV(t)=∑X1,…Xn,Y1,…YmP˜(X1,…Xn,Y1,…Ym,TV)=∑π(T)P˜(T=TV|π(T))∏j=1m∑π(Yj)P˜(Yj|π(Yj))∏i=1nP˜(xiki)=∑π(T)P˜(T=TV|π(T))∑π(Y1)P˜(Y1|π(Y1))×⋯×∑π(Ym)P˜(Ym|π(Ym))×P˜(x1k1)×⋯P˜(xnkn)

in which π(T) is the set of parents of leaf node T. π(Yj) is the set of parents of intermediate node Yj. If the state of Xi is xiki, the fuzzy conditional probability of leaf node T at state Tv is given by equation:

(8) P˜(T=Tv|Xi=xiki)(t)=P˜(T=Tv,Xi=xiki)P˜(Xi=xiki)

where P˜(T=T,Xi=xiki) is the fuzzy joint distribution when the state of Xi is xiki and T is Tv. Bayesian network is used to calculate the posterior probability of the failure of the parent node when the failure of the child node is known. While T=Tv, the posterior probability of root Xi=xiki could be concluded as follows:

(9) P˜(Xi=xiki|T=Tv)(t)=P˜(T=Tv,Xi=xiki)P˜(T=Tv)

The fuzzy importance degree of BN describes the evaluation of the importance degree when the leaf node is in a certain fault state, and the root node is in different fuzzy states in the multi-state system. The importance of the root node is an important part of quantitative analysis in system reliability analysis [24,27]. It represents the importance of components in the system and aims to quantify the contribution of the component failure to system failure [28]. The importance degree of the root node in the Bayesian network can be obtained by using the inference algorithms, such as graph reduction method, clique tree propagation and bucket elimination inference method [33–35]. In this paper, the clique tree reasoning method is used for calculation, and the clique tree is constructed according to the variable elimination method. According to the calculation process of variable elimination, the information is transferred to the root node for calculation [16].

If the failure state of Xi is xiki(i=1,2,⋯,n) at time t, the probability of failure of the dynamic fuzzy subset is P˜xiki(t), the membership function is μ˜P˜xiki(t). When T=Tv, the fuzzy importance of failure state xiki is given by equation:

(10) IxikiPr(t)=E[P˜(T=Tv|Xi=xiki)−P˜(T=Tv|Xi=0)]32pt=E[P˜(T=Tv,Xi=xiki)P˜(Xi=xiki)−P˜(T=Tv,Xi=0)P˜(Xi=0)]

in which P˜(T=Tv,Xi=xiki) is the fuzzy posterior probability of the leaf nodes T on the state Tv, and the state of Xi is xiki.

According to the definition of a triangular fuzzy number, each triangular fuzzy number has a non-fuzzy number corresponding to it. The process of finding a value that can best characterize this fuzzy number is called deblurring, which is also commonly called deblurring. At present, there are many methods to remove ambiguity, including the mean area method, gravity center method, integration value method, etc. In this paper, we use the center of gravity method to de-fuzzily, so the fuzzy importance IxikiPr(t) can be gotten by Li et al. [28]:

(11) IxikiPr(t)=∫01xμ˜P˜xiki,Tv(t)dx∫01μ˜P˜xiki,Tv(t)dx−∫01xμ˜P˜xiki,0(t)dx∫01μ˜P˜xiki,0(t)dx

when failure state of T is Tv, The fuzzy importance of Xi can be calculated by Eq. (12).

(12) ITvPr(t)=∑ki=1λIxikiPr(t)λ=∫01xμ˜P˜xiki,Tv(t)dx∫01μ˜P˜xiki,Tv(t)dx−∫01xμ˜P˜xiki,0(t)dx∫01μ˜P˜xiki,0(t)dxλ

where λ is the amount of state Xi excluding state 0. When state of T is TV, the node fuzzy importance of BN ITvPr(t) reflects the average importance of the node Xi, the state varies from 0 to 1 [30,32,33,35]. Importance refers to the contribution of basic events to the occurrence of the system, which reflects the important measure of basic events in the system and provides the basis for improving the reliability of the system.

Through the reliability distribution and FMECA analysis of a heavy CNC machine, it can be seen that there are serious reliability problems in the hydraulic system of the beam moving gantry machining center. In the hydraulic system, the valve core of the one-way valve is stuck. Usually, it is not completely stuck, and there is still fluid flow. The piston of the hydraulic cylinder does not fail, and it is not that the piston cannot act completely, but that the action is often incomplete; For the system as a whole, the failure of insufficient pressure is fuzzy. Therefore, it is necessary to introduce the method of fuzzy theory when doing fault tree analysis for the system. Moreover, the faults cannot be described by two states: normal and fault, and use fuzzy probability to describe the probability of component fault (occurrence of the bottom event) and system fault (occurrence of the top event) [32–36].

The balance circuit is composed of filter (j1), motor (r), hydraulic pump (p), filter (j2), pressure indicator (n1), cut-off valve (k1), pressure reducing valve (f1), one-way valve (a1), pressure indicator (n2), pressure relay (b2), cut-off valve (k2) and (k3), relief valve (i1), accumulator group (m1) and balance cylinder (h1). Any component failure can result in a system failure.

After the system starts, the hydraulic pump (p) provides oil and pressure to the whole system. During the operation of the hydraulic pump, the system presses the accumulator group. When the pressure reaches the range set by the pressure relay (b2), the hydraulic pump stops supplying pressure. During the operation of the balancing cylinder, when the pressure decreases, the accumulator group (m1) will make up the pressure and maintain the pressure of the whole system. Here, the accumulator group is regarded as series of components for fault tree modelling analysis.

According to the FMEA analysis results of the whole machine tool and hydraulic system, “no pressure or low pressure lift in the balance circuit” has been chosen as the top event. On the basis of the modelling rules of the fault tree, the fault mode of the system is analyzed from top to bottom. Causes leading to no pressure or low pressure lift in the top event balance loop include insufficient oil supply pressure, oil filter (j2) blocking, oil branch 1 fault, hydraulic cylinder (h1) fault and energy storage system failing to store energy. Secondly, the failure mode of each hydraulic component and the failure state of the components in the hydraulic component is analyzed. The fault mode and codes of the entire balance loop are shown in Tab. 1. The fault tree is presented in Fig. 5.

Based on the characteristics of the BN, the FTA is transformed into the BN model. Fig. 6 depicts the BN model of hydraulic system balance circuit fault accident. Here T′ is the leaf node, X1∼X15 are the root nodes, M1∼M4 are the intermediate nodes.

Due to the different structure and function of each root node itself, different root nodes have different influences on the system even under the same failure state. Therefore, this paper considers nodes X1∼X15, M1∼M4 and T have three failure states, respectively, normal operation, partial failure and failure. State 0, 0.5, and 1 represent normal operation, partial failure, and failure, respectively. Comprehensive historical data and expert experience, the CPT are listed in Tabs. 2–6 [22–37].

Due to components in the hydraulic loop system having different performance and different working environments, the failure probability of each component varies with time. The dynamic fuzzy subset of failure probability of root node is obtained when the failure state of root node is 1 and 0.5 by analyzing the historical data and expertise, as shown in Tabs. 7 and 8.

According to Tabs. 2–6 and Eq. (7), when T=1, the dynamic fuzzy possibility is calculated as shown below:

(13) P˜T=1(t)=∑X1,…X14M1,…M4P˜(X1,X2,X3…X14,M1,M2,M3,M4,T=1)=∑X1,X2M1,M2,M3P˜(T=1|X1,X2,M1,M2,M3)×P˜(X1)×P˜(X2)×∑X3,X4…X8,M4P˜(M1|X3,X4,⋯X8,M4)×P˜(X3)×P˜(X4)×⋯P˜(X8)×∑X6,X15P˜(M4|X6,X15)P˜(X6)×P˜(X15)∑X9…X12P˜(M2|X9…X12)×P˜(X9)×⋯P˜(X12)×∑X13,X14P˜(M3|X13,X14)×P˜(X13)×P˜(X14)

when T=0.5, the dynamic fuzzy subset of failure probability of root node is listed in Tab. 8. The dynamic fuzzy possibility is given as follows:

(14) P˜T=1(t)=∑X1,…X14M1,…M4P˜(X1,X2,X3…X14,M1,M2,M3,M4,T=0.5)=∑X1,X2M1,M2,M3P˜(T=0.5|X1,X2,M1,M2,M3)×P˜(X1)×P˜(X2)×∑X3,X4…X8,M4P˜(M1|X3,X4,⋯X8,M4)×P˜(X3)×P˜(X4)×⋯P˜(X8)×∑X6,X15P˜(M4|X6,X15)P˜(X6)×P˜(X15)∑X9…X12P˜(M2|X9…X12)×P˜(X9)×⋯P˜(X12)×∑X13,X14P˜(M3|X13,X14)×P˜(X13)×P(X14)

The comparison between the results of the method presented in this paper and the results of the fault tree analysis method is obtained by using MATLAB software simulation, as depicted in Figs. 7 and 8.

Based on the above system possibility analysis, it can be concluded that: the dynamical fuzzy possibility analysis results of leaf nodes include the dynamical fuzzy subsets of upper variable, center variable and lower variable. The central variable is almost the same as the one obtained by the traditional fault tree method. For a simple system with sufficient information and a clear fault logic relationship, the fault tree analysis method can be used; for the complex system with a lack of fault information and uncertain fault logic relationship, this method can clearly quantify and express the impact of cognitive uncertainty on system reliability. It does not need fault tree analysis and minimum cut set calculation, and it does not need to determine the complex algebraic expression of system reliability. It can be found that the method proposed in this paper can effectively deal with the fuzziness caused by the lack of data or cognition in the engineering system.

According to Eq. (10), when T is 1, the fuzzy importance of failure state xiki=1 is expressed by equation:

(15) I11Pr(t)=E[P˜(T=1|Xi=1)−P˜(T=1|Xi=0)]=∫01xμ˜P˜11,1(t)dx∫01μ˜P˜11,0(t)dx−∫01xμ˜P˜11,0(t)dx∫01μ˜P˜11,0(t)dx

Similarly, when T is 1, the fuzzy importance of failure state xiki=0.5 could be expressed as:

(16) I11Pr(t)=E[P˜(T=0.5|Xi=1)−P˜(T=0.5|Xi=0)]=∫01xμ˜P˜11,0.5(t)dx∫01μ˜P˜11,0.5(t)dx−∫01xμ˜P˜11,0(t)dx∫01μ˜P˜11,0(t)dx

According to Eqs. (10)–(12), when T is 1, the probability importance of Xi can be expressed as Eq. (17):

(17) I1Pr(t)=∑ki=12I1,kiPr(t)2

Similarly, when leaf node T is 0.5, the probability importance of Xi could be concluded as Eq. (18):

(18) I0.5Pr(t)=∑ki=12I0.5,kiPr(t)2

According to Eqs. (17) and (18), the fuzzy importance of root nodes at t = 3000 h are calculated and also listed in Tab. 9.

According to the fuzzy importance of nodes, the system fault diagnosis and maintenance detection can be effectively carried out. Firstly, the most important components are inspected and maintained. The qualitative and quantitative evaluation methods proposed in this paper can also provide a theoretical basis for system fault diagnosis and maintenance strategy formulation.

According to Eqs. (17) and (18), The importance of X1 presented in Fig. 9, while the leaf node is in state 0.5 and 1.

It can be concluded that the system dynamic fuzzy importance analysis method is based on BN proposed in this paper. When the leaf nodeT is in different fault states, the importance of the root node Xi is a curve changing with time. As shown in Fig. 9, when the leaf nodes are in different fault states of 1 and 0, the importance curves of the root nodes are different. The importance of T-S analysis is used to analyze the importance of the system, and the fixed value independent of time is obtained. When the importance of the components changes little with time, the difference between the result and the result of fault tree analysis is very small. For those with a large variation over time, if the T-S fuzzy importance analysis method is used to approximate the calculation, the results would have a large error, or even errors. Compared with the traditional reliability methods, the proposed method can make better use of the existing information and effectively deal with the fuzziness caused by a lack of data or insufficient cognition. Moreover, it can analyze the reliability of the multi-state system with dynamic problems, and the results are closer to the objective reality.