Stability analysis and optimal control strategy of DC microgrids

With the increasing demand for energy and environmental problems, renewable energy is receiving more and more attention. As an important form of energy transition, DC microgrids have great potential in energy supply and utilization.

A DC microgrid is a small-scale power system with DC as the main power transmission method, which usually consists of renewable energy generation devices, energy storage devices and power loads [1-2]. DC microgrids are characterized by three features: high efficiency, stability and reliability. Among them, stability is that DC microgrids have distributed power sources and energy storage devices, which can realize flexible scheduling and balancing of energy in the power grid and improve the stability of the power grid [3-5]. The combination of renewable energy and traditional energy sources is used to diversify the energy supply of DC microgrids and ensure the reliability and stability of energy supply. The goal of DC microgrid design is to realize the efficient use of energy and reliable operation of the power grid [6-7]. Several principles need to be considered when designing DC microgrids: appropriate scale, optimal layout, multi-source energy supply, and intelligent scheduling [8-11]. There are four aspects in the operation optimization content of DC microgrid. First, energy management, through the smart grid technology, to achieve the management and control of various energy sources, in order to achieve the efficient use of energy and the reliability of power supply [12-14]. Smart grid control technology can realize energy scheduling and optimal control of DC microgrid to maximize energy utilization efficiency and power supply availability. Secondly, load scheduling, according to the load demand and energy supply, rationally arranges the time of use of loads and optimal scheduling of loads, in order to reduce the dependence on the traditional power system [15-16]. Furthermore, the optimization of energy storage devices, energy demand is already prominent, and the energy storage of the devices is related to the high efficiency and stability of the DC microgrid. For the energy storage devices, they are optimized and controlled by reasonable charging and discharging strategies, so that they can play a maximum role in the power supply process [17-19]. Finally, grid protection, generation capacity, energy storage capacity and load demand affect the reliability of the grid. Therefore, DC microgrids need to be designed with appropriate protection measures to avoid the impact of faults on the grid and to ensure the reliability and safety of power supply [20-22].

Through further research and promotion of DC microgrid technology, renewable energy can be better utilized, energy utilization efficiency can be improved, the cost of energy production and consumption can be reduced, and the goal of sustainable development can be achieved.

In this paper, the large signal stability analysis method and anti-jamming optimization strategy in DC microgrids are studied. Firstly, the overall architecture of a DC microgrid and the energy storage model are modeled. Then, by analyzing the large-signal stability of the DC microgrid, the conditions under which the DC microgrid can operate stably under large disturbances are obtained, and the resonance spikes of the system bus voltage are effectively suppressed by adding a damping filter circuit. Secondly, considering that the distributed generation units and loads of the DC microgrid are inconsistent every day, the optimal operation model of the DC microgrid is established, and the optimal solution set of pareto is obtained by using the multi-objective gray wolf algorithm. Finally, the effectiveness of the proposed stability analysis method and anti-interference optimization strategy is verified by establishing a simulation model.

2

Basic control strategies for DC microgrids

2.1

DC Microgrid Architecture Components

The basic structure of the DC microgrid in islanding mode [23] includes components such as photovoltaic (PV) units, energy storage units, constant power loads, and power electronic converters. Among them, the PV unit is connected to the bus through a Boost converter as the microsource of the DC microgrid in this paper: the energy storage unit is connected to the bus through a Bi-DC/DC converter to realize the bidirectional flow of power in two states of charging and discharging, and the energy storage converter operates in the Buck mode when the DC microgrid is charging the energy storage unit, and in the Boost mode when the energy storage unit is discharging to the DC microgrid, which is used to balance the The difference between the power of the PV unit and the load unit. The load unit is connected to the bus through the Buck converter, and the output voltage is precisely and quickly controlled through the voltage closed-loop control, which can be regarded as a constant power load, and the load characteristics are expressed as a power load that obeys the law of electricity consumption and changes slowly. Figure 1 shows the DC microgrid in islanding mode, which is taken as the research object in this paper, and the rated bus voltage is set to 400V, and the allowable operating range is 380V~420V.

According to analyze the working principle of each component converter can get the average state equation of each unit converter, for the large signal stability analysis to establish the large signal average model of each converter to establish the basis for the subsequent establishment of the large signal model based on the analysis process in this section.

According to the working principle of Boost converter, the average state equation of PV interface converter can be obtained as: (1) ${\begin{array}{l} L_{p v} \frac{d i_{p v L}}{d t} = U_{p v} - (1 - d_{p v}) u_{d c} \\ C_{p v} \frac{d u_{d c}}{d t} = (1 - d_{p v}) i_{p v L} - i_{p v} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{L_{pv}}\frac{{d{i_{pvL}}}}{{dt}} = {U_{pv}} - (1 - {d_{pv}}){u_{dc}}} \\ {{C_{pv}}\frac{{d{u_{dc}}}}{{dt}} = (1 - {d_{pv}}){i_{pvL}} - {i_{pv}}} \end{array}} \right.$$

According to the Bi-DC/DC converter operating principle, the average state equation of the energy storage interface converter can be obtained as: (2) ${\begin{array}{l} L_{b} \frac{d i_{b L}}{d t} = U_{b} - (1 - d_{b}) u_{o} - r_{b} i_{b L} \\ C_{b} \frac{d u_{d c}}{d t} = (1 - d_{b}) i_{b L} - i_{b} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{L_b}\:\frac{{d{i_{bL}}}}{{dt}} = {U_b} - (1 - {d_b}){u_o} - {r_b}{i_{bL}}} \\ {{C_b}\:\frac{{d{u_{dc}}}}{{dt}} = (1 - {d_b}){i_{bL}} - {i_b}} \end{array}} \right.$$

According to the Buck converter operating principle, the average state equation of the load interface converter can be obtained as: (3) ${\begin{array}{l} L_{c p l} \frac{d i_{c p l L}}{d t} = d_{c p l} u_{d c} - u_{c p l} \\ C_{c p l} \frac{d u_{d c}}{d t} = i_{c p l L} - i_{c p l} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{L_{cpl}}\:\frac{{d{i_{cplL}}}}{{dt}} = {d_{cpl}}{u_{dc}} - {u_{cpl}}} \\ {{C_{cpl}}\:\frac{{d{u_{dc}}}}{{dt}} = {i_{cplL}} - {i_{cpl}}} \end{array}} \right.$$

2.2

DC microgrid control strategy based on bus voltage

In this paper, the DC bus voltage is used as the control signal to divide the DC microgrid into two working modes, in order to maximize the use of renewable energy, set the photovoltaic unit to give priority to the load power supply, when the load power required power and the photovoltaic unit power imbalance, the energy storage unit for charging and discharging power compensation, to achieve the balance of the system power, set the rated voltage of the DC bus to 400V, the bus voltage is lower than 400V when the load power is bigger, and the bus voltage is higher than 400V when the load power is smaller. The rated DC bus voltage is set to 400V, the bus voltage is lower than 400V when the load power is large, the bus voltage is higher than 400V when the load power is small, and the fluctuation range of the bus voltage is ±5%. According to the change in bus voltage, the isolated DC microgrid has two working modes.

Mode 1: The bus voltage is 380V~400V, at this time, the power required by the constant power load is larger, the bus voltage is lower than 400V, the Boost converter of the PV unit adopts the MPPT control strategy to send out the maximum power, and the power shortfall of the constant power load is compensated by the discharge of the storage unit, and the Bi-DC/DC converter of the storage unit adopts the P-U droop control strategy to stabilize the DC bus voltage. Mode 2: The DC bus voltage is at the same level as that of the storage unit.

Mode 2: The bus voltage is 400V~420V, at this time, the power required by the constant power load is small, the bus voltage is higher than 400V, the Boost converter of the PV unit adopts the P-U sag control strategy to stabilize the DC bus voltage, and the excess power of the PV unit is absorbed by the charging of the storage unit, and the Bi-DC/DC converter of the energy storage unit adopts the constant current control strategy.

2.2.1

Mode 1 Basic Control Strategy

Mode 1 DC bus voltage is 380V~400V, the PV converter uses MPPT control strategy to emit maximum power density, and the energy storage converter uses P-J sag to control cage cheese discharge to stabilize the DC bus voltage.

PV unit MPPT control. PV unit in a fixed light intensity and temperature, by the characteristic curve graph can be seen that the output power of the PV unit there is a maximum power P_m, this point is the maximum power point, MPPT control goal that is in the light intensity and temperature changes in real-time tracking of the maximum power point, to maintain the maximum power output of the PV unit.

MPPT control of photovoltaic units is often used methods such as constant voltage method, conductivity increment method, power feedback method and perturbation observation method, etc., in which the perturbation observation method has the advantages of simple digging method, simple tracking process and fast response speed compared to other methods, so the perturbation observation method is chosen to realize the maximum power point tracking in this paper.

The working principle of the perturbation observation method is to repeatedly apply periodic voltage perturbation ΔU to the operating voltage of the PV array and observe the change of its output power, according to sampling the output voltage U(k) and output current I(k) of the PV array and calculating its output power P(k) until the output power starts to decrease, when the power starts to decrease, the perturbation voltage will be inverted immediately, and according to the size of the power, the PV output-side reference voltage will be adjusted U_{PV_ref}.

The MPPT control strategy is used to obtain the reference value of the output voltage of the PV array, and then the voltage loop is used to generate the PWM signals of the switching tubes, which ultimately realizes the maximum power point tracking control of the PV unit.

When the DC bus voltage is lower than 400V, the energy storage unit adopts P-U sag control to supplement the shortfall between the maximum PV power and the power required by the load on the one hand, and maintain the bus voltage stability on the other. The two switching tubes of the energy storage converter are driven by complementary PWM, and a sag control link is set up before the current and voltage double closed loop. The difference between the output power P_b of the sampled Bi-DC/DC converter and the rated power is multiplied by the sag coefficient k_b as the change in bus voltage, and the rated bus voltage U_N is subtracted to get the new bus voltage reference value, and the difference with the actual bus voltage is used as the input to the voltage PI loop, and the current PI loop is passed through the current PI loop, and the P-U control is used to maintain bus voltage stability. The difference with the actual bus voltage is used as the input to the voltage PI loop, and the current PI loop gets the PWM signals to the two switching tubes, so as to realize the sag control of the energy storage unit.

2.2.2

Mode 2 Basic Control Strategy

In mode 2, the DC bus voltage is 400V~420V, the Boost converter of the PV unit adopts the P-U sag control strategy to stabilize the DC bus voltage, and the Bi-DC/DC converter of the energy storage unit operates in the charging mode, and adopts a constant-current control strategy to prevent overcharging.

When the maximum power output from the PV is greater than the power required by the load, the DC bus voltage is higher than the rated value of 400V, the PV converter will switch from MPPT control to P-U sag control to reduce the output power of the PV unit to maintain the stability of the DC bus voltage. Sag control is set before the current and voltage double closed loop, the difference between the output power P_pv of the sampled Boost converter and the rated power P_{pv_N} is multiplied by the sag coefficient k_pv as the amount of bus voltage change, and the bus voltage reference U_N is subtracted from the change to get the new bus voltage reference, and the difference with the actual bus voltage is used as the input to the voltage loop, and after the current loop, it gets the PWM signal to the switching tubes to realize the P-U control of the power of the PV unit. P-U control of PV unit power.

When the DC bus voltage is higher than 400V, the energy storage unit adopts constant current control charging, which limits the current size, prevents overcharging, and absorbs the redundant power between the maximum power of PV and the power required by the load. The two switching tubes are driven by complementary PWM, at this time, the voltage outer ring is invalid, the actual inductor current and the inductor current limit value to do the difference between the current PI ring and get the PWM signal to the two switching tubes, so as to realize the constant-current control of the energy storage unit.

3

Large-signal stability analysis methods for DC microgrids

3.1

Stability theorem based on mixed potential function theory

The mixed potential function theory allows to establish the energy function of Liapunov type, to obtain the criterion that ensures the stable operation of the system under large perturbations, and to give the stability condition in analytical form. The steps of applying the mixed potential function theory to determine the stability of the system are as follows: 1)

Establish the mixed potential function model of the system.

2)

According to the established model, select the corresponding stability theorem to get the parameter conditions when the system satisfies the large-signal stability.

The hybrid potential function is denoted by P, which is modeled with respect to the circuit structure and is the sum of the current potential function and the voltage potential function.

With u_u, i_u representing the voltage and current of the non-storage element in the system, i₁, …, i_r representing the current through the rth inductor, and u_r+1, …, u_r+s representing the voltage across the sth capacitor, the energy potential function P is shown below: (4) $P = P (i, u) = \int \sum_{μ > r + s} u_{μ} d i_{μ} + \sum_{σ = r + 1}^{r + s} u_{σ} i_{σ}$ $$P = P(i,u) = \int {\sum\limits_{\mu > r + s} {{u_\mu }} } {\text{d}}{i_\mu } + \sum\limits_{\sigma = r + 1}^{r + s} {{u_\sigma }} {i_\sigma }$$

where Σ_σ = r + 1^{r + s}u_σi_σ represents the sum of the capacitive energies of the system; and $\int \sum_{μ} > r + s u_{μ} d i_{μ}$ $$\int {\sum\limits_\mu > } r + s{u_\mu }d{i_\mu }$$ represents the current potential function of the non-energy storage element.

Some non-energy storage elements cannot be constructed with their current potential functions, which can be represented in the form of a voltage potential function by the relation $\int u_{μ} d i_{μ} = u_{μ} i_{μ} + i_{μ} d u_{μ}$ $$\int {{u_\mu }} d{i_\mu } = {u_\mu }{i_\mu } + {i_\mu }d{u_\mu }$$.

The unified model of the hybrid potential function P is shown below: (5) $P = P (i, u) = - A (i) + B (u) + (i, γ - α u)$ $$P = P(i,u) = - A(i) + B(u) + (i,\gamma - \alpha u)$$

The correctness of P can be checked by whether Eq. (6) is satisfied between the steady-state model of the circuit and the model P of the established hybrid potential function. (6) ${\begin{array}{l} L_{ρ} \frac{d i_{ρ}}{d t} = \frac{\partial P}{\partial i_{ρ}}, ρ = 1, 2, \dots, r \\ - C_{σ} \frac{d u_{σ}}{d t} = \frac{\partial P}{\partial u_{σ}}, σ = r + 1, r + 2, \dots, r + s \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{L_\rho }\frac{{d{i_\rho }}}{{dt}} = \frac{{\partial P}}{{\partial {i_\rho }}},\rho = 1,2, \cdots ,r} \\ { - {C_\sigma }\frac{{d{u_\sigma }}}{{dt}} = \frac{{\partial P}}{{\partial {u_\sigma }}},\sigma = r + 1,r + 2, \cdots ,r + s} \end{array}} \right.$$

According to the hybrid potential function in model P of A(i), B(u) in the characterization, there exist three different stability criteria to describe the stability of the system: 1)

If A(i) is related to all parameters in i₁, ⋯, i_r, the range of values of the parameters for the system to maintain stable operation under large perturbations can be obtained by the first stability theorem of the mixed potential function theory;

2)

If A(i) is related to some parameters in i₁, ⋯, i_r, and B(u) is related to u_r+1, ⋯, u_r+5, the second stability theorem of mixed potential function theory can be used to analyze the parameter conditions for the system to maintain stable operation under large disturbances;

3)

If A(i) is related to some of the parameters in i₁, ⋯, i_r, and B(u) is related to some of the parameters in u_r + 1, ⋯, u_r+s, when analyzing the parameter conditions for the system to maintain stable operation under large perturbations, the third stability theorem of mixed potential function theory can be used, which describes the relationship between the stability of the system and the current potential function as well as the voltage potential function.

3.2

DC microgrid large signal modeling

In order to analyze in detail the influence of the line parameters of constant power loads on the stability of large signals in DC microgrids, the equivalent constant power load model shown in Fig. 2 is now taken as the object of study.

3.2.1

Modeling of mixed potential functions

According to the equivalent model of the constant power load, the third stability theorem of the mixed potential function theory is used to analyze the stability of the constant power load under large disturbances, which is:

Denote by L the diagonal matrix consisting of all inductors in the system, and by C the diagonal matrix consisting of all capacitors in the system, i.e., if the inductance of the system is L₁, L₂, …, L_n, then L = diag(L₁, L₂, …, L_n). Denote by A_ii(i) = ∂ A²/∂ i² the second-order derivation of the current potential function with respect to the current, by B_uu(u) = ∂ B²/∂ u² the second-order derivation of the voltage potential function with respect to the voltage, by P_u = ∂ P(i, u)/∂ u the derivation of the hybrid potential function P(i, u) with respect to the voltage, and by P_i = ∂ P(i, u)/∂ i the derivation of the current with respect to the current by P(i, u).

If in the circuit, all i and u are satisfied, then when the system is subjected to a large perturbation, it can eventually return to its original steady state operation or operate at a new stable equilibrium operating point. (7) $μ_{1} + μ_{2} > 0$ $${\mu _1} + {\mu _2} > 0$$

and when |i| + |u| → ∞: (8) $P^{*} (i, u) = (\frac{μ_{1} - μ_{2}}{2}) P (i, u) + \frac{1}{2} (P_{i}, L^{- 1} P_{i}) + \frac{1}{2} (P_{u}, C^{- 1} P_{u}) \to \infty$ $${P^*}(i,u) = (\frac{{{\mu _1} - {\mu _2}}}{2})P(i,u) + \frac{1}{2}({P_i},{L^{ - 1}}{P_i}) + \frac{1}{2}({P_u},{C^{ - 1}}{P_u}) \to \infty$$

Modeling with the hybrid potential function theory starts by dividing the components into three categories. The current potential functions of the equivalent DC voltage source and the equivalent resistor are shown below: (9) $\int_{0}^{i_{c p l}} u_{d c} d i_{c p l} + \int_{0}^{i_{c p l}} (- R_{1} i_{c p l}) d i_{c p l} = u_{d c} i_{c p l} - \frac{1}{2} R_{1} i_{c p l}^{2}$ $$\int_0^{{i_{cpl}}} {{u_{dc}}} d\:{i_{cpl}} + \int_0^{{i_{cpl}}} {( - {R_1}{i_{cpl}})} d{\text{ }}{i_{cpl}} = {u_{dc}}{i_{cpl}} - \frac{1}{2}{R_1}i_{cpl}^2$$

The current potential function of constant power load P_cpl can be expressed in the form of voltage potential function as: (10) $\int_{0}^{i_{0}} (- \frac{P_{c p l}}{i}) d i = - P_{c p l} + \int_{0}^{u_{C l}} (\frac{P_{c p l}}{u}) d u$ $$\int_0^{{i_0}} {( - \frac{{{P_{cpl}}}}{i})} d\:i = - \:{P_{cpl}} + \int_0^{{u_{Cl}}} {(\frac{{{P_{cpl}}}}{u})} d\:u$$

The energy of capacitor C₁ is one u_Cl(i_cpl − P_cpl/u_Cl) and hence the hybrid potential function of the whole circuit is modeled uniformly as shown below: (11) $P (i, u) = - \frac{1}{2} R_{1} i^{2}_{c p l} + u_{d c} i_{c p l} + \int_{0}^{u_{C l}} (\frac{P_{c p l}}{u}) d u - u_{C l} i_{c p l}$ $$P(i,u) = - \frac{1}{2}{R_1}{i^2}_{cpl} + {u_{dc}}{i_{cpl}} + \int_0^{{u_{Cl}}} {(\frac{{{P_{cpl}}}}{u})} du - {u_{Cl}}{i_{cpl}}$$

Examining the hybrid potential function model developed based on the circuit shown in the hybrid potential function model of the circuit yields: (12) ${\begin{array}{l} \frac{\partial P}{\partial i_{c p l}} = - R_{1} i_{c p l} + u_{d c} - u_{C l} = L_{1} \frac{d i_{c p l}}{d t} \\ \frac{\partial P}{\partial u_{C l}} = - i_{c p l} + P_{c p l} / u_{C l} = - C \frac{d u_{C l}}{d t} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {\frac{{\partial P}}{{\partial {i_{cpl}}}} = - \:{R_1}\:{i_{cpl}} + {u_{dc}} - {u_{Cl}} = {L_1}\:\frac{{d{i_{cpl}}}}{{dt}}} \\ {\frac{{\partial P}}{{\partial {u_{Cl}}}} = - \:{i_{cpl}} + {P_{cpl}}/{u_{Cl}} = - \:C\frac{{d{u_{Cl}}}}{{dt}}} \end{array}} \right.$$

Obviously, Eq. (12) satisfies Eq. (6), thus verifying that the hybrid potential function model for this circuit is correct. The hybrid potential function of this system can be rewritten as: (13) ${\begin{array}{l} A (i) = \frac{1}{2} R_{1} i_{c p l}^{2} \\ B (u) = \int_{0}^{u_{C l}} (\frac{P_{c p l}}{u}) d u \\ (i, γ - α u) = u_{d c} i_{c p l} - u_{C l} i_{c p l} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {A(i) = \frac{1}{2}{R_1}i_{cpl}^2} \\ {B(u) = \int_0^{{u_{Cl}}} {(\frac{{{P_{cpl}}}}{u})} d\:u} \\ {(i,\gamma - \alpha u) = {u_{dc}}{i_{cpl}} - {u_{Cl}}{i_{cpl}}} \end{array}} \right.$$

Solve for the value of A_ii(i), B_uu(u) as shown below: (14) ${\begin{array}{l} A_{i i} (i) = R_{1} \\ B_{u u} (u) = - P_{c p l} / u_{C l}^{2} = - \frac{1}{R_{c p l}} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{A_{ii}}(i) = {R_1}} \\ {{B_{uu}}(u) = - {P_{cpl}}/{u_{Cl}}^2 = - \frac{1}{{{R_{cpl}}}}} \end{array}} \right.$$

where R_cpl is the dynamic impedance of the constant power load.

The values of μ₁ and μ₂ are solved as shown below: (15) ${\begin{array}{l} μ_{1} = R / L \\ μ_{2} = - 1 / (R_{c p l} C_{1}) \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{\mu _1} = R/L} \\ {{\mu _2} = - 1/({R_{cpl}}{C_1})} \end{array}} \right.$$

For the stable operation of the system, in order to ensure its large signal stability, the values of μ₁ and μ₂ need to meet the requirements, the solution is obtained: (16) $\frac{C_{1}}{L_{1}} > \frac{P_{c p l}}{R_{1} u_{C l}^{2}}$ $$\frac{{{C_1}}}{{{L_1}}} > \frac{{{P_{cpl}}}}{{{R_1}{u_{Cl}}^2}}$$

Eq. (16) is the large signal stability criterion of the system, which is combined with Eq. (3): (17) ${\begin{array}{l} P_{c p l} < \frac{u_{d c}^{2}}{4 R_{1}} \\ \frac{C_{1}}{L_{1}} > {\frac{P_{c p l}}{R_{1} u_{C l}}}^{2} = \frac{1}{R_{1} R_{c p l}} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{P_{cpl}} < \frac{{u_{dc}^2}}{{4{R_1}}}} \\ {\frac{{{C_1}}}{{{L_1}}} > {{\frac{{{P_{cpl}}}}{{{R_1}{u_{Cl}}}}}^2} = \frac{1}{{{R_1}{R_{cpl}}}}} \end{array}} \right.$$

The parameter design of the inductance L₁ and capacitance C₁ of the filter is only related to the line resistance R₁ and the dynamic impedance R_cpl of the constant power loads, indicating that the impedance characteristics of the constant power loads affect the system stability.

3.2.2

Mixed potential function model for constant power loads

A damping filter circuit needs to be added to the filtering link of the constant power load to suppress resonance spikes, with the objective of improving the power quality of the DC bus voltage. Three types of damping filter structures are usually used: shunt RC structure, shunt RL structure, and series RL structure. However, only the shunt RC structure can effectively stabilize the system. The study of the effect of damping filter parameters on the steady state performance of the system can provide a reference basis for parameter selection for the DC microgrid.

The equivalent circuit model of the constant power load after adding the series damping circuit is shown in Fig. 3.

The damping filter circuit does not affect the steady state characteristics of the constant power load, so the steady state equilibrium operating point criterion of the system remains unchanged.

For the circuit shown in Fig. 3, model its hybrid potential function. The current potential function of the equivalent supply voltage u_dc, line resistance R₁ and damping resistance R₂ is: (18) $u_{d c} i_{c p l} - \frac{1}{2} R_{1} i_{c p l}^{2} + \frac{{(u_{C l} - u_{C 2})}^{2}}{R_{2}}$ $${u_{dc}}{i_{cpl}} - \frac{1}{2}{R_1}i_{cpl}^2 + \frac{{{{({u_{Cl}} - {u_{C2}})}^2}}}{{{R_2}}}$$

The current potential function of constant power load P_cpl is constant and the energy of capacitor C₁, C₂ is: (19) $- u_{C 1} (i_{c p l} - \frac{(u_{C 1} - u_{C 2})}{R_{2}} - \frac{P_{c p l}}{u_{C 1}}) - u_{C 2} (u_{C 1} - u_{C 2}) / R_{2}$ $$ - {u_{C1}}({i_{cpl}} - \frac{{({u_{C1}} - {u_{C2}})}}{{{R_2}}} - \frac{{{P_{cpl}}}}{{{u_{C1}}}}) - {u_{C2}}({u_{C1}} - {u_{C2}})/{R_2}$$

The unified model of the hybrid energy potential function is shown below: (20) $P (i, u) = - \frac{1}{2} R_{1} i_{c p l}^{2} + u_{d c} i_{c p l} + \frac{{(u_{C 1} - u_{C 2})}^{2}}{2 R_{2}} + \int_{0}^{u_{C 1}} (\frac{P_{c p l}}{u}) d u - u_{C 1} i_{c p l}$ $$P(i,u) = - \frac{1}{2}{R_1}i_{\:cpl}^2 + {u_{dc}}{i_{cpl}} + \frac{{{{({u_{C1}} - {u_{C2}})}^2}}}{{2{R_2}}} + \int_0^{{u_{C1}}} {(\frac{{{P_{cpl}}}}{u})du - {u_{C1}}{i_{cpl}}}$$

Examination of the developed hybrid energy potential function model, based on the model parameters with the circuit shown in Fig. 3, can be obtained: (21) ${\begin{matrix} \frac{\partial P}{\partial i_{c p l}} = - R_{1} i_{c p l} + u_{d c} - u_{C l} = L_{1} \frac{d i_{c p l}}{d t} \\ \frac{\partial P}{\partial u_{C l}} = \frac{u_{C l} - u_{C 2}}{R_{2}} - i_{c p l} + P_{c p l} / u_{C l} = - C \frac{d u_{C l}}{d t} \\ \frac{\partial P}{\partial u_{C 2}} = - \frac{u_{C 1} - u_{C 2}}{R_{2}} = - C_{2} \frac{d u_{C 2}}{d t} \end{matrix}$ $$\left\{ {\begin{array}{*{20}{c}} {\frac{{\partial P}}{{\partial {i_{cpl}}}} = - \:{R_1}{i_{cpl}} + {u_{dc}} - {u_{Cl}} = {L_1}\:\frac{{d{i_{cpl}}}}{{dt}}} \\ {\frac{{\partial P}}{{\partial {u_{Cl}}}} = \frac{{{u_{Cl}} - {u_{C2}}}}{{{R_2}}} - {i_{cpl}} + {P_{cpl}}/{u_{Cl}} = - \:C\:\frac{{d{u_{Cl}}}}{{dt}}} \\ {\frac{{\partial P}}{{\partial {u_{C2}}}} = - \:\frac{{{u_{C1}} - {u_{C2}}}}{{{R_2}}} = - \:{C_2}\:\frac{{d{u_{C2}}}}{{dt}}} \end{array}} \right.$$

The hybrid potential function of this system can be rewritten as: (22) ${\begin{array}{l} A (i) = \frac{1}{2} R_{1} i_{c p l}^{2} \\ B (u) = \frac{{(u_{C l} - u_{C 2})}^{2}}{2 R_{2}} + \int_{0}^{u_{C l}} (P_{c p l} / u) d u \\ (i, γ - α u) = u_{d c} i_{c p l} - u_{C l} i_{c p l} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {A(i) = \frac{1}{2}{R_1}i_{cpl}^2} \\ {B(u) = \frac{{{{({u_{Cl}} - {u_{C2}})}^2}}}{{2{R_2}}} + \int_0^{{u_{Cl}}} {({P_{cpl}}/u)} du} \\ {(i,\gamma - \alpha u) = {u_{dc}}{i_{cpl}} - {u_{Cl}}{i_{cpl}}} \end{array}} \right.$$

Solve for the value of A_ii(i), B_uu(u) as shown in Eq: (23) ${\begin{array}{l} A_{i i} (i) = R_{1} \\ B_{u u} (u) = - \frac{P_{c p l}}{u_{C l}^{2}} + \frac{1}{R_{2}} = - \frac{1}{R_{c p l}} + \frac{1}{R_{2}} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {{A_{ii}}(i) = {R_1}} \\ {{B_{uu}}(u) = - \frac{{{P_{cpl}}}}{{{u_{Cl}}^2}} + \frac{1}{{{R_2}}} = - \frac{1}{{{R_{cpl}}}} + \frac{1}{{{R_2}}}} \end{array}} \right.$$

The values of the minimum eigenvalues μ₁ and μ₂ can be obtained as shown below: (24) ${\begin{matrix} μ_{1} = R_{1} / L_{1} \\ μ_{2} = \min (\frac{1}{C_{1}} (\frac{1}{R_{1}} + \frac{1}{- R_{c p l}}), \frac{1}{C_{2}} (\frac{1}{R_{2}} + \frac{1}{- R_{c p l}})) \end{matrix}$ $$\left\{ {\begin{array}{*{20}{c}} {{\mu _1} = {R_1}/{L_1}} \\ {{\mu _2} = \min (\frac{1}{{{C_1}}}(\frac{1}{{{R_1}}} + \frac{1}{{ - {R_{cpl}}}}),\frac{1}{{{C_2}}}(\frac{1}{{{R_2}}} + \frac{1}{{ - {R_{cpl}}}}))} \end{array}} \right.$$

For the system working in the steady state equilibrium point, in order to make it can be restored to the stable operation state after being subjected to large perturbations, parameters μ₁ and μ₂ need to meet the requirements, and the solution is obtained: (25) ${\begin{array}{l} \frac{C_{1}}{L_{1}} > \frac{1}{R_{1}} (- \frac{1}{R_{2}} - \frac{1}{- R_{c p l}}) \\ \frac{C_{2}}{L_{1}} > \frac{1}{R_{1}} (- \frac{1}{R_{2}} - \frac{1}{- R_{c p l}}) \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {\frac{{{C_1}}}{{{L_1}}} > \frac{1}{{{R_1}}}( - \frac{1}{{{R_2}}} - \frac{1}{{ - {R_{cpl}}}})} \\ {\frac{{{C_2}}}{{{L_1}}} > \frac{1}{{{R_1}}}( - \frac{1}{{{R_2}}} - \frac{1}{{ - {R_{cpl}}}})} \end{array}} \right.$$

The large-signal stability criterion of the system after adding the damping filter link before the constant power load is shown in Eq. (26), which intuitively gives the design requirements of the damping filter circuit parameters. Combining the large-signal stability criterion formula with Eq. (3), it can be obtained: (26) ${\begin{array}{l} \frac{C_{1}}{L_{1}} > \frac{1}{R_{1}} (- \frac{1}{R_{2}} - \frac{1}{- R_{c p l}}) \\ \frac{C_{2}}{L_{1}} > \frac{1}{R_{1}} (- \frac{1}{R_{2}} - \frac{1}{- R_{c p l}}) \\ P_{c p l} < \frac{u_{d c}^{2}}{4 R_{1}} \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} {\frac{{{C_1}}}{{{L_1}}} > \frac{1}{{{R_1}}}( - \frac{1}{{{R_2}}} - \frac{1}{{ - {R_{cpl}}}})} \\ {\frac{{{C_2}}}{{{L_1}}} > \frac{1}{{{R_1}}}( - \frac{1}{{{R_2}}} - \frac{1}{{ - {R_{cpl}}}})} \\ {{P_{cpl}} < \frac{{u_{dc}^2}}{{4{R_1}}}} \end{array}} \right.$$

If the values of the filtering parameters and the constant power load are satisfied, the system can maintain good steady state performance under large disturbances.

4

Multi-objective gray wolf algorithm-based modeling for optimal system operation

Based on the analysis of the composition of the low-voltage DC microgrid, an optimized operation structural framework containing distributed PV, energy storage batteries, control system, grid-connected converter, and user loads is constructed as shown in Fig. 4. The system consists of three parts: the generation side, the central distribution control and the user load, and the generation side includes the PV generation [24], the grid connected through the grid-connected converter, and the energy storage device. The central distribution system consists of a DC bus and a central control system, where the DC bus is responsible for the flow of energy and the control system is responsible for collecting signals and executing control commands; the user loads include smart meters and household loads, and DC loads of the Schengen vehicle. The smart meter collects, measures, and transmits energy data from user loads, and has intelligent functions such as two-way multi-rate measurement and user control.

4.1

Battery life estimation by equivalent power weight method

The equivalent power weight method considers the equivalent discharge amount of the battery during the charging and discharging cycles, and in the optimized operation of low-voltage DC microgrids, the battery has different charging and discharging powers and discharge depths at different moments, and the use of the equivalent power weight method can be used to effectively evaluate the battery life, and the battery life loss is calculated by the equivalent cumulative discharge amount: (27) $L_{l o s s} = \frac{A_{c}}{A_{t o t a l}}$ $${L_{loss}} = \frac{{{A_c}}}{{{A_{total}}}}$$

The equivalent cumulative discharge is expressed as: (28) $A_{c} = λ_{s o c} \cdot A_{s}$ $${A_c} = {\lambda _{soc}} \cdot {A_s}$$

Where, λ_soc is the weighting factor; A_s is the actual discharge (kW-h).

Weighting factor λ_soc is obtained from the following equation: (29) $λ_{s o c} = {\begin{array}{l} d_{1} & 0 < S O C (t) \leq 0.5 \\ d_{2} \cdot S O C (t) + d_{3} & 0.5 < S O C (t) \leq 1 \end{array}$ $${\lambda _{soc}} = \left\{ {\begin{array}{*{20}{l}} {{d_1}}&{0 < SOC(t) \le 0.5} \\ {{d_2} \cdot SOC(t) + {d_3}}&{0.5 < SOC(t) \le 1} \end{array}} \right.$$

When 0 < SOC(t) ≤ 0.5, the weighting factor is related to the value of d₁ only. When 0.5 < SOC(t) ≤ 1, the weighting factor is related to the values of d₂ and d₃. In operation, the life loss of the battery is accumulated to get the battery life after t moments as: (30) $U_{s} = \frac{1}{\int_{0}^{1} \frac{λ_{s o c} \cdot A_{s} (t)}{A_{total}} d t}$ $${U_s} = \frac{1}{{\int\limits_0^1 {\frac{{{\lambda _{soc}} \cdot {A_s}(t)}}{{{A_{{\text{total}}}}}}dt} }}$$

4.2

Objective function

Objective function: the objective function is to maximize the daily net gain, minimize the total equivalent battery charge/discharge, and minimize CO₂ emissions. The overall objective function expression is as follows: (31) ${\begin{matrix} f_{1} = \max \sum_{t = 1}^{T} (F (t) - C_{c o n} (t) - C_{q} (t)) \\ f_{2} = \min \sum_{t = 1}^{T} | P_{B d} (t) | \cdot Δ t \\ f_{3} = \min \sum_{t = 1}^{N} [\frac{(P_{c o n} (t)) + \sqrt{{(P_{c o n} (t))}^{2}}}{2} Δ t \cdot e^{ω_{2}}] \end{matrix}$ $$\left\{ {\begin{array}{*{20}{c}} {{f_1} = \max \sum\limits_{t = 1}^T {(F(} t) - {C_{con}}(t) - {C_q}(t))} \\ {{f_2} = \min \sum\limits_{t = 1}^T {\left| {{P_{Bd}}(t)} \right|} \cdot \Delta t} \\ {{f_3} = \min \sum\limits_{t = 1}^N {\left[ {\frac{{\left( {{P_{con}}(t)} \right) + \sqrt {{{\left( {{P_{con}}(t)} \right)}^2}} }}{2}\Delta t \cdot {e^{{\omega _2}}}} \right]} } \end{array}} \right.$$ 1)

Maximum daily net gain f₁

After determining the capacity configuration of each unit, the cost of purchasing PV panels and batteries in the investment has been fixed, and in actual operation, the load, PV output and real-time electricity price are different every day, resulting in the purchase and sale of electricity and the amount of discarded light are different every day. Therefore, the daily net revenue is mainly related to the daily revenue from selling electricity to the customer load and the cost of purchasing and selling electricity from the grid through the grid converter and the cost of discarding light, and the objective function is: (32) $f_{1} = \max \sum_{t = 1}^{r} (F (t) - C_{c o n} (t) - C_{q} (t))$ $${f_1} = \max \sum\limits_{t = 1}^r {(F(} t) - {C_{con}}(t) - {C_q}(t))$$ (33) $F (t) = P_{l o a d} (t) \cdot Δ t \cdot R_{p r i c c} (t)$ $$F(t) = {P_{load}}(t) \cdot \Delta t \cdot {R_{pricc}}(t)$$ (34) $C_{c o n} (t) = {\begin{array}{l} C_{b u y} (t) \cdot P_{c o n} (t) \cdot Δ t, P_{c o n} (t) \geq 0 \\ C_{s a l e} (t) \cdot P_{c o n} (t) \cdot Δ t, P_{c o n} (t) < 0 \end{array}$ $${C_{con}}(t) = \left\{ {\begin{array}{*{20}{l}} {{C_{buy}}(t) \cdot {P_{con}}(t) \cdot \Delta t,\quad {P_{con}}(t) \ge 0} \\ {{C_{sale}}(t) \cdot {P_{con}}(t) \cdot \Delta t,\quad {P_{con}}(t) < 0} \end{array}} \right.$$ (35) $C_{q} (t) = c \cdot P_{q} (t) \cdot Δ t$ $${C_q}(t) = c \cdot {P_q}(t) \cdot \Delta t$$

2)

Battery equivalent total charge and discharge minimization f₂

The use of equivalent power weight method can be a good assessment of the battery life, the total equivalent discharge in the battery is at different depth of discharge equivalent out of the total discharge under the battery charging and discharging cycle. Because in operation, but also consider the state of charge of the battery to store excess power to dissipate photovoltaic, so the objective function for the battery equivalent charging and discharging amount to minimize the equivalent power weight method, which is also linearly correlated with the battery service life.

(36)

f_{2} = \min \sum_{t = 1}^{r} | P_{B d} (t) | \cdot Δ t

$${f_2} = \min \sum\limits_{t = 1}^r | {P_{Bd}}(t)| \cdot \Delta t$$

(37)

P_{B d} (t) = {\begin{array}{l} λ_{s o c} \cdot P_{B} (t) & P_{B} (t) \geq 0 \\ P_{B} (t) & P_{B} (t) < 0 \end{array}

$${P_{Bd}}(t) = \left\{ {\begin{array}{*{20}{l}} {{\lambda _{soc}} \cdot {P_B}(t)}&{{P_B}(t) \ge 0} \\ {{P_B}(t)}&{{P_B}(t) < 0} \end{array}} \right.$$

(38)

λ_{s o c} = {\begin{array}{l} 1.32 & 0 < S O C (t) \leq 0.5 \\ - 1.8 \cdot S O C (t) + 2.22 & 0.5 < S O C (t) \leq 1 \end{array}

$${\lambda _{soc}} = \left\{ {\begin{array}{*{20}{l}} {1.32}&{0 < SOC(t) \le 0.5} \\ { - 1.8 \cdot SOC(t) + 2.22}&{0.5 < SOC(t) \le 1} \end{array}} \right.$$

3)

Minimization of CO₂ emissions f₃

Based on the dual-carbon target background, the CO₂ emissions are minimized in operation and CO₂ emissions are minimized by adding them to the objective function. In the system operation model, there are no units such as diesel generators, gas turbines, etc., and the load is met by photovoltaics, energy storage, and power purchased from the grid to meet the demand, and there is carbon emission only when power is purchased from the grid through the grid-connected converter, and therefore the objective function is: (39) $f_{3} = \min \sum_{t = 1}^{N} [\frac{(P_{c o n} (t)) + \sqrt{{(P_{c o n} (t))}^{2}}}{2} Δ t \cdot e^{c v_{2}}]$ $${f_3} = \min \sum\limits_{t = 1}^N {\left[ {\frac{{\left( {{P_{con}}(t)} \right) + \sqrt {{{\left( {{P_{con}}(t)} \right)}^2}} }}{2}\Delta t \cdot {e^{c{v_2}}}} \right]}$$

4.3

Constraints

1)

Power balance constraints: (40) $P_{l o a d} (t) = P_{p v} (t) + P_{c o n} (t) + P_{B} (t)$ $${P_{load}}(t) = {P_{pv}}(t) + {P_{con}}(t) + {P_B}(t)$$

At t moment the load power is equal to the sum of the energy storage charging and discharging power, the PV output power and the power purchased and sold from the grid through the grid-connected converter.

2)

Battery charging and discharging current limit constraints

The charging and discharging current of lithium iron phosphate battery during operation should not be too high, otherwise it will cause irreversible loss to the battery and even cause the battery to catch fire. The battery current should not exceed 0.3I_in when charging and 0.5I_in when discharging. (41) ${\begin{array}{l} - 0.3 I_{i n} \leq I_{c} \leq 0 \\ 0 \leq I_{d} \leq 0.5 I_{i n} \\ I_{i n} = E_{b} / (U_{E V} \cdot 1 h) \end{array}$ $$\left\{ {\begin{array}{*{20}{l}} { - 0.3{I_{in}} \le {I_c} \le 0} \\ {0 \le {I_d} \le 0.5{I_{in}}} \\ {{I_{in}} = {E_b}/({U_{EV}} \cdot 1h)} \end{array}} \right.$$

Where I_c is the charging current of the battery (A); I_d is the discharge current of the battery (A); U_EV is the voltage of the battery during discharge (A); E_b is the rated capacity of the battery (kW-h). 3)

Battery charging and discharging power limit constraints

The charging and discharging power of the battery should be less than the rated power of the energy storage in the configuration results in Chapter 2, and charging and discharging power higher than the rated power will lead to high temperature of the battery and even explosion, which will have an impact on the safety and stability of operation.

(42)

- P_{r a t e} \leq P_{B} (t) \leq P_{r a t e}

$$ - {P_{rate}} \le {P_B}(t) \le {P_{rate}}$$

where P_ratc is the power rating of the storage battery (kW). 4)

SOC constraints of the battery

(43)

S O C_{\min} \leq S O C (t) \leq S O C_{\max}

$$SO{C_{\min }} \le SOC(t) \le SO{C_{\max }}$$

(44)

S O C (t) = S O C (t - 1) - {\begin{array}{l} \frac{P_{B} (t) \cdot Δ t}{E_{r a t e} η_{d c}}, P_{B} (t) > 0 \\ \frac{P_{B} (t) \cdot Δ t \cdot η_{c h}}{E_{r a t e}}, P_{B} (t) < 0 \end{array}

$$SOC(t) = SOC(t - 1) - \left\{ {\begin{array}{*{20}{l}} {\frac{{{P_B}(t) \cdot \Delta t}}{{{E_{rate}}{\eta _{dc}}}},{P_B}(t) > 0} \\ {\frac{{{P_B}(t) \cdot \Delta t \cdot {\eta _{ch}}}}{{{E_{rate}}}},{P_B}(t) < 0} \end{array}} \right.$$

where SOC_min, SOC_max is the upper and lower limits of the storage battery charge state, respectively; η_de is the energy conversion efficiency when the storage battery is discharged; η_ch is the energy conversion efficiency when the storage battery is charged. 5)

Grid-connected converter constraints

The grid-connected converter regulates the size of its transmission power based on the power command, and operates at the rated power when its power limit is reached.

(45)

- P_{r c o n} \leq P_{c o n} (t) \leq P_{r c o n}

$$ - {P_{rcon}} \le {P_{con}}(t) \le {P_{rcon}}$$

Where P_con(t) is the power of the grid-connected converter at the moment of t (kW); P_reon is the rated power of the grid-connected converter (kW).

4.4

Multi-objective gray wolf algorithm solution modeling

Multi-objective’s Gray Wolf Algorithm (MOGWO) [25] Compared with most of the traditional multi-objective algorithms, MOGWO has the advantages of fast convergence, high accuracy, easy to implement, etc., and it can solve the high-dimensional multi-objective optimization problems better. The flow of the multi-objective gray wolf algorithm is shown in Fig. 5.

The specific process of MOGWO algorithm is as follows 1)

Set the control parameters, initialize the position of the wolves, and calculate the fitness.

2)

Find the optimal solution according to the grid density by calculating the objective value.

3)

In the search space, α wolf, β wolves and σ wolves determine the potential position of the prey, and their positions guide the whole wolf pack to optimize, and the grey wolf packs update their positions during the predation process.

(46)

D_{p} = | \vec{C} \cdot \vec{X_{p}} (t) - \vec{X} (t) |

$${D_p} = \left| {\vec C \cdot \overrightarrow {{X_p}} (t) - \vec X(t)} \right|$$

(47)

\vec{X} (t + 1) = \frac{1}{3} \sum_{p = a, β, σ} (\vec{X_{p}} (t) - \bar{A} \cdot D_{p})

$$\vec X(t + 1) = \frac{1}{3}\sum\limits_{p = a,\beta ,\sigma } {(\overrightarrow {{X_p}} (t) - \bar A \cdot {D_p})}$$

(48)

\vec{A} = 2 θ \cdot {\vec{r}}_{1} - θ

$$\vec A = 2\theta \cdot {\vec r_1} - \theta$$

(49)

\bar{C} = 2 θ \cdot {\bar{r}}_{2}

$$\bar C = 2\theta \cdot {\bar r_2}$$

(50)

θ = 2 - \frac{2 t}{t_{\max}}

$$\theta = 2 - \frac{{2t}}{{{t_{\max }}}}$$

(4) Update the iterative selection of wolf leaders (optimal, second and third), select the wolf with greater crowding distance by calculating the crowding distance, and perform the fitness calculation again to obtain the Pareto optimal solution set until the number of cycles is reached and the output is terminated.

The Pareto optimal solution set for multi-objective planning can be obtained by the multi-objective gray wolf algorithm, but the optimal solution cannot be obtained directly, and the optimal solution needs to be obtained by using the TOPSIS method, which is an objective weight assignment method that determines the size of the weights in accordance with the correlation between the objective values or the degree of change in the objective values when processing the data. The optimal solution is selected by evaluating the positive and negative ideal solutions of the problem and calculating the relative proximity of each solution to the positive or negative ideal solution. The specific steps are as follows: 1)

Form a normalized decision matrix based on the objective values of the Pareto optimal solution set generated by multi-objective optimization.

2)

Determine the objective weight vector of each objective according to the variance maximization decision-making method; and form the weighted specification matrix;

3)

Determine the positive ideal solution and negative ideal solution corresponding to each objective by comparing with each other. Then the distance between the objective value of each solution and the positive ideal solution and negative ideal solution of the corresponding objective is obtained by calculation

4)

Calculate the comprehensive evaluation index of each solution, and then determine the optimal solution recommendation scheme based on the ranking.

5

Analysis of stability simulation results

5.1

Experimental validation of large signal stability criterion

Substituting the relevant parameters into the large-signal stability criterion, the CPL values Re₁ and Re₂ of the two sub-microgrids are calculated to be limited to a minimum value of 7 Ω. Four DC microgrid large-signal perturbation scenarios are simulated in the experimental simulation, and the four perturbation scenarios are shown in Table 1.

Table 1.

Four disturbance conditions

	Re₁	Re₂	Whether to meet the high signal stability criterion(Re₁)	Whether to meet the high signal stability criterion(Re₂)
Case1	14Ω	8Ω	contented	contented
Case2	14Ω	0.5Ω	contented	dissatisfied
Case3	0.5Ω	14Ω	dissatisfied	contented
Case4	0.5Ω	0.5Ω	dissatisfied	dissatisfied

Next, simulation experiments are carried out to validate the four cases according to Table 1, in which constant power loads CPL₁ and CPL₂ are connected at 1.5s and the two sub-microgrid bus voltages are observed to see if they can return to the equilibrium point after the perturbation. Figures 6 to 9 show the bus voltages for cases 1 to 4.

In Case 1, after the system is connected to the constant power loads CPL₁ and CPL₂ for 1.5 s, both sub-microgrid 1 and sub-microgrid 2 satisfy the large-signal stability criterion, and the bus voltage of sub-microgrid 1 decreases to 490 V and then rises to recover to 500 V. The bus voltage of sub-microgrid 2 decreases to 638 V and then rises to recover to 650 V.

After the system in Case 2 is connected to the constant power loads CPL₁ and CPL₂ at 1.5 s, sub-microgrid 1 satisfies the large-signal stability criterion, sub-microgrid 2 does not, and the bus voltage of sub-microgrid 1 hardly fluctuates and remains at 500 V. The bus voltage of sub-microgrid 2 plummeted to 150 V and did not recover to 650 V even after fluctuations. In case 3, after the system is connected to the constant power loads CPL₁ and CPL₂ for 1.5 s, sub-microgrid 1 does not satisfy the large-signal stability criterion, and sub-microgrid 2 does, and the bus voltage of sub-microgrid 1 drops to 170 V, and it does not recover to 500 V after fluctuations. The bus voltage of sub-microgrid 2 fluctuated slightly, but still remained at 650V overall. In case 4, after the system is connected to the constant power loads CPL₁ and CPL₂ at 1.5 s, both sub-microgrid 1 and sub-microgrid 2 do not satisfy the large-signal stability criterion, and the bus voltage of sub-microgrid 1 drops to about 160 V and does not recover to 500 V. The bus voltage of sub-microgrid 2 dropped to about 160V and did not recover to 650V.

Based on the above analysis, it can be seen that when the equivalent load in the sub-microgrid satisfies the large-signal stability criterion of the sub-microgrid, the bus voltage of the sub-microgrid returns to the equilibrium point after fluctuation and the system is stable. When the equivalent load in the sub-microgrid is less than the minimum allowable value, the bus voltage of the sub-microgrid will not return to the equilibrium point after fluctuation, and the system is in a collapsed state. Therefore, the calculated minimum allowable value of equivalent load R is correct, thus verifying the correctness of this stability criterion.

5.2

Improve system large signal stability

According to the obtained large-signal stability criterion formula, it can be seen that the improvement of the system large-signal stability can be realized by increasing the capacitance value or reducing the inductance value, and this conclusion is verified next. Firstly, to verify the effect of capacitance value on the system large-signal stability, set the system constant power load Re₁=5Ω, Re₂=21Ω, and on the basis of the experiments designed in the previous chapter, set the capacitance Cb₂ to 0.1F, 0.3F, 0.4F, 0.5F in turn, and other parameters remain unchanged, and the corresponding sub-microgrid 1 bus voltages in the four cases and the sub-microgrid 2 bus voltages in the four cases are shown in Figures 10 and Fig. 11.

When Cb₂=0.1F, the bus voltage of sub-microgrid 1 keeps dropping and is collapsed. When Cb₂=0.3F, the bus voltage drops up to 480 V and then returns to the equilibrium point of 500 V. When Cb₂=0.5F, the bus voltage drops up to 480 V and then returns to the equilibrium point of 500 V. It can be seen that, as the value of system capacitance increases, the system’s large signal stability increases. The bus voltage of sub-microgrid 2 in all four cases is stable because the CPL value of sub-microgrid 2 is 21Ω, which satisfies the stability criterion of sub-microgrid 2.

Then, to verify the effect of inductance value on the stability of large signal of the system, set the system constant power load Re₁=16Ω, Re₂=9Ω, and set the value of inductance L_t4 to 3mH, 2.9mH, 2.8mH, and 2.7mH in turn on the basis of the original experiments, other parameters remain unchanged, and the corresponding sub-microweb 1 bus voltage and sub-microweb 2 bus voltage of the four cases are shown in Fig. 12 and Fig. 13 shown.

The bus voltage of sub-microgrid 1 in all four cases is stable because the CPL value of sub-microgrid 1 is 16Ω, which satisfies the stability criterion of sub-microgrid 1. When L_t4=3mH, the bus voltage drops up to 632.5 V and then returns to the equilibrium point of 650 V. When L_t4 is reduced to 2.9 mH, the bus voltage drops to 634 V and still manages to return to the equilibrium point. When L_t4 is reduced to 2.8 mH and 2.7 mH, respectively, the bus voltage returns to the equilibrium point of 650 V after a slight drop. It can be seen that decreasing the value of the inductance of the system, can lead to an increase in the large signal stability of the system. This shows that it is effective to improve the system’s large-signal stability according to the obtained criteria, and indirectly proves the correctness of the criterion.

Based on the above analysis, it can be seen that the system can be improved based on the derived criterion of large signal stability, i.e., the large signal stability of the system can be improved by increasing the capacitance value of the system or decreasing the inductance value of the system.

6

Optimized control simulation results

To simulate the control effect when the PV device fluctuates, the wind speed of the PM wind turbine is set to be fixed at 9m/s in the simulation process, and the simulation length is 10s. And several fluctuation phases are designed in the operation process, and the light illumination per square meter is set as follows: initially 1kW, increased to 1.2kW in 2s, reduced to 0.7kW in 6s, and then reduced to 0.5kW in 8s. Meanwhile, the ambient temperature is set as follows settings were: 25°C for 0 to 4s, 40°C for 4 to 6s, and 25°C for 6 to 10s.

The simulation results of load power, fan output power, PV output power, and battery supplemental power are shown in Fig. 14. The wind turbine output power basically reaches close to the set value at 0.35s and stays at about 8.7kW, and the load power stays at 11.5kW. The PV output power changes continuously, while the battery supplemental power changes correspondingly to maintain the system balance. Within 0 to 2s, the PV output power is 4.2kW, while the battery absorbs 1.8kW of power inversely. In 2 to 4s, the PV output power is 5.2kW and the battery absorbs 2.8kW. In 6 to 8s, the system power is in equilibrium, so the battery is not involved in power regulation. In 8 to 10s, the PV output power is 1.5kW and the battery also needs to output 0.5kW to maintain the power balance.

Figure 15 shows the simulation results of DC bus voltage. The bus voltage only produces nearly 20V overshoot in the start-up phase, and the maximum fluctuation in the rest of the phase is only 1.5%, which shows that when the PV output power fluctuation, the battery under the optimized control strategy in this paper can effectively inhibit the bus voltage fluctuation and guarantee the stable operation of the system.

Comparison effect of different control strategies. In order to further verify the optimal control effect of this paper’s optimized control strategy for energy storage optimization, the double closed-loop voltage-current PI control method is selected for comparison. The simulation time is set to 6s, and the wind speed of the fan changes:9m/s for the 0~1s stage, 8m/s for the 1~5s stage.The light per square meter of the PV is set to:1kW for the 0~2s stage, 1.1kW for the 2~5s stage, and 0.9kW for the 5~6s stage.The change of the load power is set to:7kW for the 0~3s stage,11kW for the 3~4s stage, and 9kW for the 4~6s stage.The results of each part of the power simulation, DC power simulation result, and the DC current PI control method are shown in the following table. The simulation results for power, DC bus voltage, and battery output current are depicted in Fig. 16-Fig. 18, respectively.

With the change of wind speed and light, the wind output power and photovoltaic output power also change constantly, in order to guarantee the balance of the output power of each part, the battery starts power supplementation based on the power difference of each stage.

In the initial stage of the system, the overshoot of DC bus voltage under the optimized control strategy of this paper is only 35 V, while it reaches 89 V under the double-closed-loop PI control. In the operation stage, affected by the output power of each part, the fluctuation of DC bus voltage under the optimized control strategy of this paper is not more than 5 V at most, and it takes only about 0.18 s to restore the smoothness. The maximum DC bus voltage fluctuation under voltage-current double-loop PI control reaches 27V, and it takes nearly 0.42s to restore stability, which is a longer fluctuation time.

When the system is disturbed, the output current of the battery under the optimized control strategy of this paper reaches a stable level in a very short time, and the fluctuation amplitude is small. And the battery output current under voltage-current double-loop PI control takes longer to recover, approximately 0.1 s. In summary, the results show that the optimized control strategy in this paper can effectively suppress the fluctuation of dc bus voltage when the power changes, recover the equilibrium state faster, effectively optimize the control characteristics of the battery energy storage, and enhance the smoothness of the system.

7

Conclusion

In this paper, the stability of DC microgrid is explored using a double damping control method, and an optimal DC microgrid operation control model based on the multi-objective gray wolf algorithm is established.

The correctness of the large-signal stability criterion is verified by simulation experiments conducted with four different perturbation cases. The stability of the system with large signals increases gradually as its capacitance value increases from 0.1F to 0.5F. When the inductance value of the system is reduced from 3mH to 2.7mH, the large-signal stability of the system can be gradually enhanced. It has been proven that the stability of the DC microgrid can be improved by increasing the capacitance value and decreasing the inductance value.

The bus voltage produces an overshoot of nearly 20V in the initial stage of startup, in addition to the maximum fluctuation of only 1.5% in the rest of the fluctuation stage, which shows that the battery can play a role in suppressing the bus voltage fluctuation when the PV output power fluctuates under the optimal control strategy in this paper.

The battery output current under the optimized control strategy of this paper reaches a smoother time than that under the voltage-current double-loop PI control, and the jitter amplitude is smaller. It shows that the DC microgrid optimization operation model based on the multi-objective gray wolf algorithm designed in this paper can effectively suppress the fluctuation of the DC bus voltage when the power changes, play the role of optimizing the battery storage control, and strengthen the anti-interference characteristics of the DC microgrid.

Idioma:: Inglés

Calendario de la edición:: 1 veces al año
Temas de la revista:: Ciencias de la vida, Ciencias de la vida, otros, Matemáticas, Matemáticas aplicadas, Matemáticas generales, Física, Física, otros

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Stability analysis and optimal control strategy of DC microgrids

Likui Yi

Fanhua Meng

Rui Feng

Dongge Liu

Publicado en línea: 21 mar 2025

Recibido: 28 oct 2024

Aceptado: 09 feb 2025

DOI: https://doi.org/10.2478/amns-2025-0587

Palabras claveDC microgrid, Damping filter circuit, Large signal stability, Multi-objective gray wolf algorithm

© 2025 Likui Yi et al., published by Sciendo

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Palabras clave
DC microgrid, Damping filter circuit, Large signal stability, Multi-objective gray wolf algorithm