The present invention relates generally to electric power systems, and more particularly to controlling a micro-grid connected to a power distribution system.
A micro-grid is a localized grouping of power generation, storage, and loads that can be connected to the power distribution system (PDS) to provide an additional control layer integrating intermittent renewable energy resources to the power distribution system. From the point of view of a PDS, a connected micro-grid can be controlled as if it is one entity.
A PDS usually treats the micro-grid as a positive or negative load due to unstable voltage on the micro-grid caused by load or generation variations. Such instability reduces the quality of power supply to the PDS, and requires the PDS to control the variations of the voltage supplied by the micro-grid. However, maintaining the stable voltage supply to the PDS requires sophisticated measurements of the power flow on the entire PDS and the micro-grid, which complicates plugin capability of the micro-grid into the PDS.
For example, some PDSs control the micro-grids by adding compensation signal to voltage regulator and/or emulating a voltage source that requires complex power flow computations. For example, voltage regulation methods described in U.S. Pat. No. 8,710,815 and US 20110316518 regulate output voltage dynamic response by adding compensation to a fast inverter's feedback signal. Controlling the micro-grid with the feedback signal determined by PDS provides an extra burden for the PDS and reduces plug-and-play capabilities of the micro-grids.
In addition, providing voltage-control ancillary service by maintaining power quality is a challenging task for micro-grids, because these small-scale power systems are typically managed by droop controllers. Droop controllers help a micro-grid to maintain power sharing when system states deviate from their nominal values. System state changes make PDS operators unable to predict power quality in a power distribution network with micro-grids.
Accordingly, there is a need for a system and a method for local control of the voltage by the micro-grid resulting in substantially constant voltage supply to the PDS to enable plug and play capability of the micro-grids.
It is an object of some embodiments of the invention to provide a system and a method for controlling the generator of the micro-grid resulting in substantially constant voltage on a point of common coupling (PCC) of the micro-grid to the power distribution system (PDS). It is another object of some embodiments to provide such a method that controls the generator using local information available to the controller of the micro-grid. Such information can include results of power flow analysis based on the measurements on the micro-grid and/or a link connecting the PCC with the bus of PDS. Such a local control enables plug-and-play capability of the micro-grid connected to the PDS that allows connecting a micro-grid to the PDS without modification of the operation of the PDS beyond the connection link.
Some embodiments of the invention are based on a realization that such a voltage can be determined and/or regulated according to a model of dynamics of the micro-grid exponentially stable on a voltage set-point at the PCC. It was further realized that such a model can be determined, e.g., using a function of a reactive power injected into the PCC, a function of load variation in the micro-grid, and a function of voltage variation at the PCC. In such a manner, the parameters of such a model can be determined using measurement of the power flow on a link connecting the PCC with the PDS, which is local information available to the controller of the micro-grid.
For example, in one embodiment, the model includes a combination of a primary droop control determining the reactive power proportional to the voltage on the PCC and a secondary stabilization control component shifting the droop slope of the primary droop controller to ensure the exponential stability. This embodiment allows one to upgrade droop controllers widely used in the micro-grids. This secondary stabilization controller uses local information to determine a control input to the primary droop controller. The additional control enables maintaining a constant voltage at the PCC regardless of load or state changes in the rest of power system. Even when there is a constantly changing local load connected to the PCC, the secondary voltage controller is able to cancel impact of the load variation on voltage magnitude. With such a voltage regulation capability, a micro-grid can be used to improve power quality in a power distribution network hence provide voltage-regulation ancillary service.
The secondary stabilization controller guaranties exponential stability with respect to a set point without the need to modify control command from a distribution system operator. When measurements come with the disturbances, such as measurement noise, input-output finite-gain stability can also be ensured. Also, the secondary stabilization controller is compatible with existing voltage control devices. Because voltage of the PCC is regulated at a set point, operation cost is reduced by decreasing usage of existing voltage control devices in a power distribution network.
Accordingly, one embodiment of the invention discloses a method for controlling a micro-grid connected to a power distribution system. The method includes determining parameters of a model of dynamics of the micro-grid using measurements of power flow at a point of common coupling (PCC) of the micro-grid with the power distribution system, wherein the model is exponentially stable on a voltage set-point at the PCC; determining, using the parameters of the model, an amount of reactive power required to maintain the voltage at the PCC asymptotically stable on the voltage set-point; and controlling a generator of the micro-grid to produce the amount of reactive power. At least some steps of the method are performed using a processor.
Another embodiment discloses a system for controlling the voltage of a micro-grid connected to a power distribution system including a generator producing a requested amount of reactive power; a processor determining an amount of reactive power using a model of dynamics of the micro-grid exponentially stable on a voltage setpoint at a point of common coupling (PCC) of the micro-grid and the power distribution network, wherein the model includes a function of a reactive power injected into the PCC, a function of load variation in the micro-grid, and a function of voltage variation at the PCC; a set of sensors for measuring state of power flow on a link connecting the PCC with a bus of the power distribution system to determine parameters of the model; and a reactive-power controller controlling the generator to produce the amount of reactive power.
Overview of Micro-Grid Connected to Power Distribution System
In some implementations, the taps of each transformer are used to regulate the voltage at a point of common coupling (PCC) of each micro-grid. Each tap change corresponds to a given amount, such as 1.25% of voltage magnitude variation, with a mechanical delay of several seconds. In some embodiments, the PCC voltage of each micro-grid is regulated by an automatic controller, such as a droop controller.
The phase angle at each PCC can also be regulated by a droop controller for a fast-inverter-based generator, whose dynamics are regulated by a swing equation for a rotational-machine-based generator. Depending on the generator installed at each micro-grid, the inertia of each micro-grid can be different. For example, Bus 110 is connected to micro-grid 1 that has rotational generators that have a large inertia. Bus 120 and Bus 130 are connected to micro-grids 2 and 3 that have fast-inverter based generations with small inertia values.
Similarly, reactive power-voltage droop controllers have different parameters that relate back to their reactive power capacity. As a result, voltage magnitude deviation is different for different micro-grids even while a same amount of reactive power is injected.
In the example of
Therefore, the method further includes determining 160, using the parameters 155 of the model, an amount of reactive power 165 required to maintain the voltage at the PCC asymptotically stable on the voltage set-point. After the amount of reactive power is determined, the method controls 170 a generator of the micro-grid to produce the amount of reactive power.
Power Flow Relationship
Some embodiments of the invention determine the asymptotically stable model using a function of a reactive power injected into the PCC, a function of load variation in the micro-grid, and a function of voltage variation at the PCC. In such a manner, the parameters of such a model can be determined using measurement of the power flow on a link connecting the PCC with the PDS, which is local information available to the controller of the micro-grid.
To model the power flow relationship between Bus i, 210 and Bus j, 220, only the connection link is considered. The impedance of this connection link is Zij, 250. With a little abuse of notation, symbol Yij is defined as
The symbol Yij is expressed in two forms:
Yij=Gij+jBij, and
Yij=|Yij|∠ϕij, (2)
where |Yij|=√{square root over (Gij2+Bij2)} and ϕij=tan−1(Bij/Gij).
At Bus i, Ei is voltage magnitude and δi is phase angle of the voltage, 260; Pi and Qi are injected powers. At Bus j, Ej is voltage magnitude and δj is phase angle of the voltage, 270. Using the expression of Yij, the real and reactive powers flowing into bus i, 280 are expressed as follows
Pi=TijEiEj|Yij| cos(δi−δj−ϕij)−Ei2|Yij| cos(ϕij), and (3)
Qi=Ei2|Yij| sin(ϕij)+TijEiEj|Yij| sin(δi−δj−ϕij). (4)
The real and reactive powers flowing from Bus j to Bus i, 290 are
Pji=TijEiEj|Yij| cos(δi−δj−ϕij)−Tij2Ej2|Yij| cos(ϕij), and (5)
Qji=Tij2Ej2|Yij| sin(ϕij)−TijEiEj|Yij| sin(δi−δj−ϕij). (6)
To define a single model for both generator bus and load bus, each bus connects a generator and a load. Pgen,i and Qgen,i denote generated power; Pload,i and Qload,i are real and reactive loads. Power flows at bus i, are then
Pi=Pgen,i−Pload,i, and (7)
Qi=Qgen,i−Qload,i. (8)
Without power generation whatsoever, a load bus j has Pj+Pload,j=0, and Qj+Qload,j=0.
These parameters are initially determined during configuration and planning for the power distribution system. The parameters can vary subsequently due to control activities.
Load Model
A power distribution network or a micro-grid can include various types of loads that can be generally represented using a ZIP load model as a polynomial load model. The ZIP model combines constant-impedance (Z), constant-current (I) and constant-power (P) components. Real and reactive loads at any bus i, are defined as functions of voltage magnitude Ei (in p.u.) as
Pload,i(Ei)=Ei2PZ-load,i+EiPI-load,i+PP-load,i, and (9)
Qload,i(Ei)=Ei2QZ-load,i+EiQI-load,i+QP-load,i, (10)
where PZ-load,i and QZ-load,i are nominal constant impedance loads, including shunt devices, PI-load,i and QI-load,i are nominal constant-current loads, denoting devices that are modeled as current sources; PP-load,i and QP-load,i are nominal constant-power loads, generally as a result of power control mechanism. As a result, the ZIP model represents a variety of loads and control devices.
Under nominal conditions, real and reactive power load values are functions of Ei
Pload,set,i(Ei)=Ei2PZ-load,set,i+EiPI-load,set,i+PP-load,set,i, (11)
Qload,set,i(Ei)=Ei2QZ-load,set,i+EiQI-load,set,i+QP-load,set,i. (12)
Combining load expressions in equations (9-12), load changes ΔPload,i(Ei) and ΔQload,i(Ei) are defined as
ΔPload,i(Ei)=Pload,i(Ei)Pload,set,i(Ei)=Ei2ΔPZ-load,i+EiΔPI-load,i+ΔPP-load,i, (13)
ΔQload,i(Ei)=Qload,i(Ei)−Qload,set,i(Ei)=Ei2ΔQZ-load,i+EiΔQI-load,i+ΔQP-load,i, (14)
where ΔPZ-load,i and ΔQZ-load,i are variations of constant-impedance load component; ΔPI-load,i and ΔQI-load,i are variations of constant-current load component; ΔPP-load,i and ΔQP-load,i are variations of constant-power load component.
Primary Droop Controllers
As small-scale power system, micro-grids are often managed by droop controllers. Droop controllers help a micro-grid to maintain power sharing when system states deviate from their nominal values.
A droop controller can be used to manage voltage magnitude at the PCC of the micro-grid with the following primary dynamics
where mQ,i is a droop slope of the Q-E droop controller; Eref,i denotes voltage control command; Qgen,i is reactive power generation from the micro-grid. With such a droop controller, the amount of injected reactive power from a micro-grid, i.e., Qgen,i, is proportional to the voltage difference between Eref,i and Ei. The varied reactive power injection prevents voltage magnitude Ei from further changing.
Similar to voltage regulation, phase angle at a micro-grid's PCC with fast inverter is controlled through a droop controller, whose dynamics are as follows
where mP,i is droop slope of the P-frequency droop controller; Pref,i denotes real power generation command; ω0 is the nominal angular frequency. With such a droop controller, the amount of injected real power from a micro-grid, i.e., Pgen,i, is proportional to the frequency deviation from the nominal ω0 at bus i. If the micro-grid is based on a rotational generator, then phase angle dynamics are usually depicted by a swing equation as
where Mi is the machine's inertia and Di is the damping ratio at bus i.
Additionally, the dynamics of a rotational generator is equivalent to a fast inverter (used at a micro-grid's PCC) with low-pass filters. As a result, the phase angle dynamics of both electronic and rotational generators can be expressed using the same swing equations, but parameters vary for different generators. A rotational generator has large inertia Mi but small damping ratio Di, while Mi and Di a fast inverter are both small.
Determination of Parameters of the Connection Link
To form a distributed secondary voltage control input, parameters of the connection link between a micro-grid at bus i and pure load bus j are determined. If a transmission line is used, parameters are |Yij| and ϕij; if the connection link is a transformer with tap changer, parameters include |Yij|, ϕij and Tij. The measurements available include real and reactive power injection at bus i, Pi and Qi, voltage magnitude at bus i, real and reactive power flow from bus j to bus i, Pji and Qji, and voltage magnitude at bus j, Ej.
For a transmission-line link, its parameters |Yij| and ϕij are determined as:
where bLi=Qji sin(ϕij)−Pji cos(ϕij) and cLi=Qi sin(ϕij)−Pi cos(ϕij).
For a transformer with tap changer that automatically regulates voltage magnitude, parameters |Yij|, ϕij and Tij are determined as:
where aTi=Pi sin(ϕij)+Qi cos(ϕij)=−Pji sin(ϕij)−Qji cos(ϕij), bTi=Qji sin(ϕij)−Pji cos(ϕij), and cTi=Qi sin(ϕij)−Pi cos(ϕij).
Reactive Power Function of Voltage Error
Based on the power flow relationship in equation (3) and (4), a set point is defined as (Eset, δset, Pset, Qset, ωset). Based on nominal parameters, a set point is usually determined by solving an optimal power flow (OPF) problem such that a cost function is minimized. As system parameters change during power network operation, actual system states deviate from this set point. With respect to a set point under nominal conditions, error states at bus i are defined as {tilde over (E)}i=Ei−Eset,i and {tilde over (Q)}i=Qset,i−Qi.
Using the simplified expression in equation (4), the reactive power error {tilde over (Q)}i is defined as a function of voltage error {tilde over (E)}i as follows
where Tset,ij is the nominal tap value used to determine the set point. Similarly, load variation with respect to nominal conditions is expressed as a function of {tilde over (E)}i as
Secondary Voltage Controller
The distributed secondary voltage controller only uses local measurement to form a control input to a primary droop controller. A constant voltage is maintained at the micro-grid's PCC, because this control input cancels the impact of changes in the power distribution network, such as load variations.
The required local measurement is available at a micro-grid's PCC. The set of measurements includes: the voltages at the micro-grid's PCC and the connected bus, the power injections from the micro-grid's PCC, and the powers flowing from the connection bus towards the micro-grid's PCC. These measurements are states at both sides of the step-up transformer of a micro-grid. Other than these local measurements, there is no global communication required for the power distribution network.
Using the distributed secondary voltage controller, a distribution system operator only regularly designates a control command based on a set point. Between any two consecutive control command updates, the micro-grid's PCC maintains voltage at the set point. Moreover, because the secondary voltage controller only uses local measurements, it enables a micro-grid to have plug-and-play capability.
Based on conventional reactive power-voltage droop controller in equation (15), the distributed secondary voltage controller adds a control input ui to the dynamic equation as follows
where the secondary voltage control input is
ui=(Qi−Qset,i)−(Ei2−Eset,i2)Bij+ΔQload,i(Ei). (27)
Similar to equations of reactive power error and load variation, this voltage control input is rewritten in a second-order polynomial as
where coefficients of the second-order polynomial are
ua,i=0
ub,i=−TijEj|Yij| sin(δi−δj−ϕij)
uc,i=Tset,ijEset,iEset,j|Yij| sin(δset,i−δset,j−ϕij)−TijEset,iEj|Yij| sin(δi−δj−ϕij)−ΔQload,i(Ei)
The secondary voltage control input ui is only a function of local states so that no global communication is required. Parameters such as |Yij|, ϕij and Tij are determined in real-time based on local measurements available at bus i.
Putting together reactive power expressions of voltage error, voltage error dynamics are obtained as
where coefficients are
Distribution system operators only update voltage control commands Eref,i when there is a significant change to the power system. Between any two updates, the secondary voltage controller is able to maintain a constant voltage at the micro-grid's PCC regardless of changes happened in the rest of power system.
Asymptotic Stability of Secondary Voltage Controller
For a micro-grid at bus i and its connected load bus j, define ai=QZ-load,set,i+Bij and
at a set point, if bi>0, there exists a secondary voltage control input
ui=(Qi−Qset,i)−(Ei2−Eset,i2)Bij+ΔQload,i(Ei),
such that voltage at bus Ei, i.e. Et, always converges to set point Eset,i with a region of attraction defined as
The equilibrium point is {tilde over (E)}i=0, i.e. Ei=Eset,i. With respect to this equilibrium point, a candidate local Lyapunov function is defined as
whose derivative is
Regardless of the rest of power system, as long as ai{tilde over (E)}i+bi>0 at bus i, voltage magnitude Ei asymptotically converges to the set point Eset,i. When ai>0, there is
when ai<0, there is
A region of attraction is then defined by a maximum voltage error
Using equation {tilde over (E)}i=Ei−Eset,i, the region of attraction of voltage magnitude is the same as shown above.
Exponential Stability of Secondary Voltage Controller
Besides asymptotic stability, the secondary voltage controller leads to exponential stability with respect to the set point Eset,i with a lower bound of converging speed. The exponential stability result of voltage Ei at bus i is as follows.
At bus i, the set point Ei=Eset,i or {tilde over (E)}i=0 is an isolated equilibrium point. When ai>0, the range of voltage stability is
when ai<0, the range of voltage stability is
Over an even smaller range, converging speed of voltage error {tilde over (E)}i is further bounded by a first-order dynamic system. When ai>0, the inequality of voltage error derivative and range of voltage error is
Similarly, when ai<0, the voltage error derivative's inequality and voltage error range is
A special case is when ai=0, where the voltage error range is (−∞, +∞) and the dynamic equation is simply {acute over (Ė)}i=bimQ,i{tilde over (E)}i. Obviously, converging speed in this situation is always faster than
Combining all voltage error ranges above leads to
As a result, the range of voltage magnitude Ei is
Within this voltage range, the local Lyapunov function
can be bounded from above and below as
k1{tilde over (E)}i2≤Vi≤k2{tilde over (E)}i2, (37)
where
Taking derivative of Vi with respect to time leads to
where
Based on exponential stability theorems, the equilibrium point Ei=Eset,i is exponentially stable over the domain
Input-Output Stability of Secondary Voltage Controller
The secondary voltage controller cancels impact of local load variations using the element ΔQload,i(Ei) in control input ui. However, this element is a function of local measurement and the nominal load values. If measurements come with any form of disturbance, such as measurement noise, there will be an error in voltage magnitude at the micro-grid's PCC. Small-signal input-output stability result is demonstrated for this voltage controller.
Using the secondary voltage controller satisfying conditions of asymptotic and exponential stability, voltage error dynamics are as follows
{tilde over ({dot over (E)})}i=−mQ,i(ai{tilde over (E)}i+bi){tilde over (E)}i−mQ,iwi. (39)
According to exponential stability results, the system without disturbance wi is exponentially stable with respect to {tilde over (E)}i=0. Adding the disturbance term leads to
|mQ,iwi|≤mQ,i|wi|, and
|Ei|≤1·|Ei|+0·|wi|.
If
and |wi|<rw, according to input-output stability theorems, for each {tilde over (E)}i(t0) with
the system with disturbance wi is small-signal finite-gain Lp stable for each p∈[1,∞]. For each wi∈Lpe with
the voltage error {tilde over (E)}i(t) satisfies
As a result of input-output stability, performance of the distributed secondary voltage controller is satisfactory to provide ancillary services by maintaining high power quality in a power distribution network.
The system 500 includes a processor 510 determining an amount of reactive power using a model 145 of dynamics of the micro-grid exponentially stable on a voltage setpoint at a point of common coupling (PCC) of the micro-grid and the power distribution network. The model includes a function of a reactive power injected into the PCC, a function of load variation in the micro-grid, and a function of voltage variation at the PCC. The set of sensors 520 is used for measuring state of power flow on a link connecting the PCC with a bus of the power distribution system to determine parameters of the model.
The above-described embodiments of the present invention can be implemented in any of numerous ways. For example, the embodiments may be implemented using hardware, software or a combination thereof. When implemented in software, the software code can be executed on any suitable processor or collection of processors, whether provided in a single computer or distributed among multiple computers. Such processors may be implemented as integrated circuits, with one or more processors in an integrated circuit component. Though, a processor may be implemented using circuitry in any suitable format.
The terms “program” or “software” are used herein in a generic sense to refer to any type of computer code or set of computer-executable instructions that can be employed to program a computer or other processor to implement various aspects of the present invention as discussed above.
Computer-executable instructions may be in many forms, such as program modules, executed by one or more computers or other devices. Generally, program modules include routines, programs, objects, components, and data structures that perform particular tasks or implement particular abstract data types. Typically the functionality of the program modules may be combined or distributed as desired in various embodiments. A processor for performing a function, performing a function or configured to perform a function can be implemented using circuitry in any suitable format that is programmed or otherwise configured to perform the function without additional modifications.
Also, the embodiments of the invention may be embodied as a method, of which an example has been provided. The acts performed as part of the method may be ordered in any suitable way. Accordingly, embodiments may be constructed in which acts are performed in an order different than illustrated, which may include performing some acts simultaneously, even though shown as sequential acts in illustrative embodiments.
Use of ordinal terms such as “first,” “second,” in the claims to modify a claim element does not by itself connote any priority, precedence, or order of one claim element over another or the temporal order in which acts of a method are performed, but are used merely as labels to distinguish one claim element having a certain name from another element having a same name (but for use of the ordinal term) to distinguish the claim elements.
Although the invention has been described by way of examples of preferred embodiments, it is to be understood that various other adaptations and modifications can be made within the spirit and scope of the invention. Therefore, it is the object of the appended claims to cover all such variations and modifications as come within the true spirit and scope of the invention.
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