1. Introduction
The power system protection of micro-grids must have one main feature, which is the selectivity. For this purpose, the DOC relays are intensively incorporated in the protection of micro-grids since they measure both the magnitude and direction of the phase current to reassure that the fault is occurring within the intended protection zone [1,2]. However, the selectivity is guaranteed only if there is a total coordination between the main and back-up relays, as shown in Figure 1 [3]. This coordination becomes more complex in the presence of distributed generation because of the bidirectionality of the phase currents [4,5]. The coordination between primary and back-up relays is achieved by selecting suitable current tap setting (CTS) and time dial setting (TDS) to guarantee a coordination time interval (CTI) [3,6,7,8,9,10].
In the field of power systems protection, fast response of relays (and breakers) is very beneficial, as it assures the maximum safety of the equipment and personnel. In addition, reducing the tripping times in a given system increases its reliability and security, where a given system with faster tripping times will assure that bus bars, transmission lines, cables and all equipment will not be subjected to heavy current stresses which may damage the equipment and reduce its life time.
Also, reducing tripping time will ensure adequate time space for both main and backup protection systems, and this assures that in cases where main protection equipment fails to respond in case of a fault, the backup breaker will interrupt the fault as fast as possible.
If the overall tripping times increase, both main and backup protective devices will consequently take a longer time to interrupt the circuit in case of a fault, which may lead to extreme damage to equipment and risks to human safety.
Many researchers have been attracted to propose algorithms that solve the problem of the coordination of DOC relays. This problem was firstly solved by a trial and error approach; this is done by trying different settings randomly till achieving the proper coordination [11,12]. Although this method is very simple, it suffers from two drawbacks: The first is that it takes A very long time to reach the convergence, and the second is that this method may increase the overall operating time (OT) of the tripping [13]. This has directed the researchers to use the linear programming in solving the coordination problem by selecting the TDS only [14]. This method is very efficient in achieving the optimal coordination. However, this method depends mainly on the accurate selection of the initial condition of CTS, since if the selection is not accurate then the program will not converge [15].
Nonlinear programming has also been incorporated into the optimization of the coordination of DOC relays, which give better results when compared to linear programming. However, this method also depends on the proper selection of CTS which is also considered a drawback. Moreover, the computational burden of this method is very high [16].
In the recent years and after the advancement of metaheuristic optimization algorithms, these algorithms have attracted many researchers to solve the DOC relays coordination problem. One of the most popular bio-inspired optimization algorithms is the Particle Swarm Optimization (PSO) which is inspired from the biological behavior in the navigation of search space looking for food [17,18,19,20,21]. This method has been proposed by many research papers to solve the DOC relays coordination problem due to its robustness and familiarity [22].
However, this algorithm has a clear disadvantage, which is the dependability on the constructive cooperation rather than keeping track on each search member separately to find the fittest one [12]. Another important algorithm is the Genetic Algorithm which is inspired from the Darwinian evolution resembling the behavior of chromosomes till reaching a huge population [23,24,25,26,27]. Through this journey the variables of the objective function are updated, and the whole process is repeated till it reaches convergence. This method has the ability of supervising the position of each member to find the fittest one [28]. However, and unlike the PSO, it does not pay much attention to the cooperative behavior of all groups. Many other algorithms have also been incorporated in solving the DOC relays coordination problem, such as the Gravitational Search Algorithm [29], Biogeography-based optimization [8], Electromagnetic Field Optimization [30], Firefly algorithm [31] and the Whale Optimization Algorithm [32].
The Multi-Verse Optimization (MVO) has been recently proposed in [33]. The algorithm is based on the multi-verse theory, which proposes that there is more than one universe. It also describes the formation of these universes and how they are formed and allocated.
In this paper, the MVO is proposed for solving the DOC relay optimization problem through the selection of optimum CTS and TDS, so that the minimum OT is achieved. To test the performance of the proposed algorithm, it is applied to the IEEE 3 bus and IEEE 9 bus systems to show its advantages in terms of accuracy and efficiency. The obtained results from the MVO is compared with the PSO, which is very popular in solving the same problem.
The rest of this paper is organized as follows: Section 2 shows the definition of the DOC relay coordination problem including the mathematical representation of the OF. Section 3 introduces the MVO algorithm and how it is utilized to solve the DOC relay coordination problem. Section 4 shows the simulation results of different case studies.
2. Problem Definition 2.1. Formulation of the Objective Function
Each DOC relay has a dedicated Current Transformer (CT), so that the current passing through the relay, Iik is a fraction from the primary fault current, If, ik as shown in (1):
Iik=If, ikCTratio,
where i is number of the relay, k is the index of the fault location and CTratio is the ratio between the primary current and secondary current. The OT of each relay can be calculated from (2):
Tik=α.TDSi(IikCTSi)n−1,
where α and n are constant numbers are selected based on the required characteristics.
The optimization of the DOC relays aims to minimize the OT of all relays. So, the OF that needs to be minimized is expressed as per (3):
minOF=∑i=1m(∑k=1n Tik),
where m is the number of the relays and n is the number of possible fault locations.
2.2. Constraints of the Optimization Problem
The DOC relay coordination OF is considered a highly constrained function, as there are many factors, boundaries and constraints that must be employed before starting the optimization process. Firstly, there are certain limits for the CTS and TDS of each relay as per (4) and (5):
CTSimin≤CTSi≤CTSimax,
TDSimin≤TDSi≤TDSimax,
where CTSimin and CTSimax are the minimum and maximum values for the CTS of relay i according to the relay manufacturer.
Also, there are boundaries for the OT of each relay according to (6):
Tikmin≤Tik≤Tikmax,
where Tikmin is the minimum OT of relay i at fault k and this value is decided by the relay manufacturer. Tikmax is the maximum OT of relay i at fault k and this value is selected based on two main factors: The first factor is the thermal damage curve of the protected equipment, while the second is the stability margin of the zone related to the relay [12]. Tikmax must be lower than the time required to damage the protected equipment and at the same time it should guarantee the stability of the protected power system [12].
The last important constraint is the Coordination Time Interval (CTI), which is the time required to discriminate between primary and back-up relays to guarantee the system selectivity as shown in Figure 2 [16]. According to (7), the CTI is the OT difference between the back-relay j and the primary relay i.
CTIk=Tjk−Tik,
It is important to be mentioned that the CTI must be higher than CTImin , which is the minimum coordination time interval.
3. Multi-Verse Optimization 3.1. Basic Idea and Inspiration of MVO
The multi-verse theory which forms the basic idea of the MVO depends on three fundamental elements. The first is the white hole which has never been observed, as it occurs only either when a universe is created, or two adjacent universes are collapsed with each other. The second element is the black hole, which has a total opposite behavior to that of the white hole. Black holes are frequently observed, also they have massive gravitational forces that make them able to attract all ambient objects. The third element is the wormhole, which is responsible for exchanging objects between different universes or even between different parts at the same universe [33].
Also, the multi-verse theory describes the process of universe expansion which depends mainly on the inflation rate of it. The rate controls the formation of universe elements. The MVO search process resembles the process of reaching a stable situation of two parallel universes through the interaction between black, white and wormholes.
This method has been utilized in important applications related to optimization and the management of processes related to renewable energy and power systems [34].
The philosophy of the MVO is illustrated in Figure 3, where n universes are present and each of them is considered a solution. A universe with high inflation rate will tend to send objects to other universes with a lower inflation rate through wormholes. The best universe/solution is the one having the lowest inflation rate to be able to receive objects from all other universes.
3.2. Mathematical Model of MVO Algorithm
Assume that d is the number of variables and n is the number of candidate solutions. All universes can be tabulated randomly using the roulette wheel mechanisms shown in (8) [34]:
U=[x11x12…x21x22…⋮⋮⋮ x1dx2d⋮xn1xn2 …xnd]
where xij is the jth parameter of the ith universe. Each parameter can be calculated from (9):
xij={xkj,r1<NI(Ui)xij,r1≥NI(Ui)
where xkj is the jth parameter of the kth universe, r1 is a random binary number which can be either 0 or 1, and NI(Ui) is the inflation rate of the ith universe. As shown in (9), the roulette wheel mechanism forms white holes based on different inflation rates. Universes with lower inflation have a high probability of receiving objects through white/black holes. However, each universe intends to make local changes using wormholes to improve its inflation rate. This mechanism can be described as per (10):
xij={{Xj+TDR x ((ubj−lbj).r4+lbj,r3<0.5Xj−TDR x ((ubj−lbj).r4+lbj,r3≥0.5 r2<WEPxijr2≥WEP
where Xj is the jth element of the best solution (best universe created). lbj and ubj are the lower and upper bounds of this element. r2 , r3 and r4 are binary numbers. WEP is the wormhole existence probability while the TDR is traveling wave distance. The WEP is increased linearly against iterations to reassure the progress of the optimization algorithm and how it is far from finding the best solution. The WEP is updated based on adaptive equation as illustrated in (11):
WEP=min+l x (max−minL)
where min and max are the boundaries for the WEP coefficient. l is the order of the iteration while L is the maximum number of iterations.
TDR is also increased as the number of iterations increases to assure more accurate local search around the best solution. It is also updated according to adaptive formula as per (12):
TDR=1−l1pL1p
where p is coefficient that controls the accuracy and speed of algorithm convergence. Figure 4 shows the flow chart of the MVO algorithm.
4. The Proposed Optimal Coordination Algorithm of DOC Relays
The proposed optimization algorithm utilizes the MVO algorithm in optimizing the DOC relays and minimizing the overall tripping time without violating the constrains of the OF. Firstly, the algorithm starts with reading the short circuit currents near the relays, then it applies the proposed MVO algorithm to choose TDS and Ip for each relay. The operating time of each relay is calculated based on the short circuit current and the selected TDS and Ip settings for each relay. After this step, the CTI for all relay pairs to ensure that it does not exceed the CTImin . Figure 5 shows a flow chart for the general steps followed to reach the optimum settings of DOC relays.
In the proposed algorithm, the universes represent the different solutions to the optimization problem which here will refer to the summation of the OT of all relays as per (3). The position of each parameter in any universe reflects the value of time dial setting and pick-up current that must be set to achieve the desired OT.
5. Simulation Results
In this section, the proposed MVO algorithm is tested on two different standard power systems layouts to evaluate its effectiveness. The simulation is carried out on both MATLAB (MathWorks Natick, MA, USA) and ETAP (Operation Technology, Inc., Irvine, CA, USA). power stations software packages. The simulation is repeated using a PSO algorithm which is considered a very popular optimization algorithm to evaluate the performance of the proposed algorithm in terms of convergence speed, accuracy of solutions and computational burden.
5.1. Case Study 1: The IEEE 3-Bus System
Single line diagram of the IEEE 3-bus system under investigation is shown in Figure 6. First, a short circuit analysis for all branch currents is conducted to find out primary and secondary fault currents. Results of the short circuit analysis for the system is illustrated in Table 1.
Using MATLAB software, the system is simulated, and the coordination of the DOC relays is achieved using both the proposed MVO algorithm and the PSO algorithm. As shown in Table 2, the OT of all relays is considerably reduced by using the proposed algorithm as it has been decreased from 9.209 s to 4.964 s. Also, in terms of the convergence speed, the proposed algorithm has higher convergence speed when compared to the PSO algorithm as shown in Figure 7.
Moreover, to verify the results obtained in Table 2, results are used to set the six relays, and the newly coordinated system is simulated using ETAP power stations simulation software. It can be observed that the proposed algorithm has more accurate results as it reduces the OT of each relay pair without violating the CTImin or exceeding the boundaries of the CTS and TDS. This is clearly illustrated as shown in Figure 8, Figure 9, Figure 10 and Figure 11, where a comparison exists between results obtained from the proposed MVO algorithm and the PSO algorithm by showing the time-current curves for each relay pairs.
5.2. Case Study 2: The IEEE 9-Bus System
In this case, the IEEE 9 bus system is used for further verification of the proposed MVO algorithm where the single line diagram of the system in that case is shown in Figure 12. Similar to the previous case study, a short circuit analysis is carried out to obtain primary and back up fault currents and results are listed in Table 3. The coordination of the DOC relays is achieved using the proposed algorithm and the PSO algorithm.
Simulation results in this case are presented in Table 4. It can be observed that the OT of all relays is considerably reduced by using the proposed MVO algorithm in comparison with PSO algorithm, as it has been decreased from 24,381 s to 20,887 s. It is worth mentioning that the previous results are obtained by setting the MVO algorithm to run 400 iterations while the PSO algorithm is set to run 500 iterations. Proposed MVO converged faster in less iterations which means better performance and less computation burden.
6. Conclusions
In any given power system network at the occurrence of faults, it is required to isolate the fault as fast as possible to protect both the equipment from stress and the human from any risks. In this paper, a heuristic MVO optimization algorithm is presented as a solution to the directional over current relay coordination problem in micro-grids due to the bidirectional capabilities of system buses. The MVO algorithm is explained in detail, and the mathematical objective function is modeled with the aim of minimizing the overall tripping time of available protective relays in the system. The proposed MVO algorithm is tested on IEEE 3 bus and IEEE 9 bus systems, and results are compared with those obtained by the well-established PSO optimization algorithm. In both case studies the proposed MVO algorithm outperformed the PSO algorithm in all aspects. It can be concluded that OT, results convergence time and computation burden, have all been decreased significantly, which contributes to equipment and human safety, and increases overall system security.
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| Primary Relay | Backup Relay | Primary Fault Current (A) | Secondary Fault Current (A) |
|---|---|---|---|
| R1 | R5 | 9.46 | 14.08 |
| R3 | R6 | 8.81 | 12.07 |
| R5 | R4 | 17.93 | 25.9 |
| R6 | R2 | 14.35 | 19.2 |
| Relay Number | Pick Up Current (PSO) | Time Dial Setting (PSO) | Pick Up Current (MVO) | Time Dial Setting (MVO) |
|---|---|---|---|---|
| 1 | 1.4 | 0.065 | 1.4284 | 0.05 |
| 2 | 1.345 | 0.38 | 1.4969 | 0.2013 |
| 3 | 1.431 | 0.0591 | 1.336 | 0.05 |
| 4 | 1.365 | 0.6074 | 1.4433 | 0.2183 |
| 5 | 1.455 | 0.4367 | 1.4418 | 0.1912 |
| 6 | 1.38 | 0.2501 | 1.447 | 0.1876 |
| Overall Tripping Time | 9.209 s | 4.964 s | ||
| Location | Primary Relay | Backup Relay | Primary Fault Current (kA) | Secondary Fault Current (kA) | Location | Primary Relay | Backup Relay | Primary Fault Current (kA) | Secondary Fault Current (kA) |
|---|---|---|---|---|---|---|---|---|---|
| A | R1 | R15 | 24,779 | 9.150 | G | R13 | R11 | 16,087 | 3.088 |
| R1 | R17 | 24,779 | 15.632 | R13 | R21 | 16,087 | 13 | ||
| R2 | R4 | 8.327 | 8.327 | R14 | R16 | 18,213 | 6.285 | ||
| B | R3 | R1 | 16,390 | 16,930 | R14 | R19 | 18,213 | 11,934 | |
| R4 | R6 | 14,671 | 14,671 | H | R15 | R13 | 18,218 | 6.285 | |
| C | R5 | R3 | 9.454 | 9.454 | R15 | R19 | 18,218 | 11,935 | |
| R6 | R8 | 23,280 | 4.777 | R16 | R2 | 16,087 | 3.088 | ||
| R6 | R23 | 23,280 | 18,507 | R16 | R17 | 16,087 | 13 | ||
| D | R7 | R5 | 23,280 | 4.777 | I | R18 | R2 | 8.161 | 2.426 |
| R7 | R23 | 23,280 | 18,507 | R18 | R15 | 8.161 | 5.736 | ||
| R8 | R10 | 9.454 | 9.454 | J | R20 | R13 | 9.286 | 4.644 | |
| E | R9 | R7 | 15,304 | 15,304 | R20 | R16 | 9.286 | 4.644 | |
| R10 | R12 | 16,490 | 16,490 | K | R22 | R11 | 8.161 | 2.426 | |
| F | R11 | R9 | 8.326 | 8.327 | R22 | R14 | 8.161 | 5.736 | |
| R12 | R14 | 24,779 | 9.150 | L | R24 | R5 | 6.149 | 3.075 | |
| R12 | R21 | 24,779 | 15,631 | R24 | R8 | 6.149 | 3.075 |
| Relay Number | Pick Up Current (PSO) | Time Dial Setting (PSO) | Pick Up Current (MVO) | Time Dial Setting (MVO) |
|---|---|---|---|---|
| 1 | 1.624 | 0.5702 | 0.50014 | 0.89758 |
| 2 | 1.321 | 0.4080 | 1.0332 | 0.37397 |
| 3 | 2.181 | 0.4131 | 1.5055 | 0.52843 |
| 4 | 1.138 | 0.6361 | 1.6936 | 0.37582 |
| 5 | 1.194 | 0.4456 | 1.3227 | 0.47198 |
| 6 | 1.957 | 0.6661 | 1.1088 | 0.65426 |
| 7 | 1.324 | 0.6667 | 2.143 | 0.59678 |
| 8 | 1.987 | 0.4053 | 1.2832 | 0.43074 |
| 9 | 1.469 | 0.5547 | 0.52688 | 0.77392 |
| 10 | 1.345 | 0.5632 | 1.6283 | 0.47139 |
| 11 | 0.941 | 0.4641 | 1.1773 | 0.29103 |
| 12 | 1.37 | 0.7049 | 1.047 | 0.79271 |
| 13 | 1.623 | 0.6047 | 1.0435 | 0.5042 |
| 14 | 1.114 | 0.6607 | 0.73153 | 0.77677 |
| 15 | 1.662 | 0.5650 | 1.7964 | 0.51331 |
| 16 | 1.518 | 0.6180 | 0.5 | 0.7673 |
| 17 | 1.392 | 0.7944 | 1.9575 | 0.84834 |
| 18 | 1.53 | 0.3172 | 2.0172 | 0.085839 |
| 19 | 1.621 | 0.6589 | 1.9127 | 0.74232 |
| 20 | 1.332 | 0.6028 | 0.58571 | 0.0178 |
| 21 | 1.684 | 0.8715 | 1.9693 | 0.85226 |
| 22 | 1.937 | 0.4269 | 2.2307 | 0.30646 |
| 23 | 1.678 | 0.9313 | 2.2652 | 0.81034 |
| 24 | 0.621 | 0.3483 | 0.50413 | 0.57707 |
| Overall Tripping Time | 24,381 s | 20,887 s | ||
Author Contributions
M.A. contributed to the research framework, checked, and revised draft paper; H.Y.D. collected the data and wrote the draft manuscript, checked, and revised the paper; M.A. supervised the whole process. Both authors read and approved the final manuscript.
Funding
This research received no external funding.
Conflicts of Interest
The authors declare no conflict of interests.
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Electrical Energy Department, College of Engineering and Technology, Arab Academy for Science and Technology and Maritime Transport, Giza 12212, Egypt
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Abstract
[...]there are certain limits for the CTS and TDS of each relay as per (4) and (5): CTSimin≤CTSi≤CTSimax, TDSimin≤TDSi≤TDSimax, where CTSimin and CTSimax are the minimum and maximum values for the CTS of relay i according to the relay manufacturer. According to (7), the CTI is the OT difference between the back-relay j and the primary relay i. CTIk=Tjk−Tik, It is important to be mentioned that the CTI must be higher than CTImin , which is the minimum coordination time interval. 3. [...]the algorithm starts with reading the short circuit currents near the relays, then it applies the proposed MVO algorithm to choose TDS and Ip for each relay. [...]to verify the results obtained in Table 2, results are used to set the six relays, and the newly coordinated system is simulated using ETAP power stations simulation software.
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