This application is based on and claims priority to Chinese Patent Application No. 201610390839.X, filed on Jun. 6, 2016, the entire contents of which are incorporated herein by reference.
The present disclosure generally relates to a technical field of operation and control of a power system, and more particularly, to a method for regulating primary frequency of a power grid based on an air conditioning load cluster in a large building.
Primary frequency regulation capacity is one of main representations of capabilities of a power system to realize a balance between power generation and loads and to respond to an accident or a disturbance. Traditional primary frequency regulation is generally provided by hydropower generating units or large-scale thermal power generating units having a quickly regulating capability with a response time of seconds. With the connection of large-scale new energy power generation, moment of inertia of the power system is significantly reduced, and randomness and uncontrollability of the power generated in new energy generation may increase frequency regulation burden of the power system. Meanwhile, connection of high voltage direct current transmission replaces a local power source, which further reduces the primary frequency regulation capacity of the system. Therefore, how to develop potentials of the load side to involve in the primary frequency regulation of the system becomes a pressing issue.
Based on load side response mechanism, a viable idea is to organize and manage numerous controllable thermal loads with low monomer power to participate in the primary frequency regulation of power system. Via collecting and processing information and certain control means, cluster loads with thermal energy storage effect, such as air conditionings, may be able to participate in ancillary services, while ensuring comfort of an end user is not significantly affected. This is because that the controllable thermal loads are energy type loads, users care about the total thermal energy released by a power consumption equipment to a thermal environment during a period of time rather than the power at each moment. While an error signal of the primary frequency regulation is an impulse type signal with integration within a period of time approaching to zero, thus will not cause significant change in the final energy output. Meanwhile, the controllable thermal loads have occupied more and more proportions of the total loads and have great potentials. In America, the controllable thermal loads in buildings account for more than 35% of the total power consumption loads of the whole power grid. Air conditioning loads also grow fast in China, where the air conditioning loads may account for more than 20% of the maximum loads of the power grid in summer. Therefore an air conditioning cluster may have a great potential of being a reserve frequency regulation means.
In addition, autonomous temperature dead zone control set for ensuring comfort of users of an air conditioning may cause total power of the air conditioning cluster to change against a requirement of a power-frequency response at some time point, that is a so-called rebound effect. The rebound effect may greatly limit thermal energy storage loads to participate in a load side response and to provide ancillary services to the system.
The present disclosure aims to solve at least one of the problems existing in the related art to at least some extent.
Embodiments of the present disclosure provide a method for regulating primary frequency of a power grid based on an air conditioning load cluster in a large building. According embodiments of the present disclosure, a method for regulating primary frequency of a power grid based on an air conditioning load cluster in a large building is provided, in which, a two-layer control structure including a central coordinating layer and a local control layer is used in the air conditioning load cluster, the central coordinating layer includes a central controller, the local control layer includes N local controllers, N air conditionings, and temperature sensors and frequency sensors provided in rooms the air conditionings located in.
The method includes the following steps:
1) performing, by each local controller, a thermal model parameter identification and an air conditioning autonomous control to obtain local information corresponding to each of the air conditionings, and uploading the local information to the central controller at an end of each communication interval tgap, and broadcasting, by the central controller, coordinating information to each local controller;
2) when a communication between the central controller and each of the local controllers in step 1) is finished, based on the coordinating information sent from the central controller, determining, by each local controller, whether a power deviation in the air conditionings is beyond an action dead zone at a beginning of each action period tact, if yes, a frequency regulation control action is performed, else, no action is performed and operation states of all the air conditionings at a beginning of a next action period are estimated. if a current time reaches to a beginning of a next communication interval, step 1) is executed, else, step 2) is repeated.
A method for regulating primary frequency of a power grid based on an air conditioning load cluster in a large building provided in the present disclosure will be described in combination with embodiments and with reference to drawings as follows.
The present embodiment is shown as
In some embodiments, the central controller and the local controllers may communicate in both-way at every communication interval. The local controllers acquire data from the temperature sensors at each temperature sampling period. A communication among the central controller and each of the local controllers is in a way of wireless communication. A communication between each of the local controllers and each of the air conditionings, each of the temperature sensors or the frequency sensors may be in a way of wireless communication or wire communication. The local controllers regulate and control the local air conditionings once during each action period according to local information and coordinating information transmitted from the central controller.
As shown in
In block 1, each local controller performs a thermal model parameter identification and an air conditioning autonomous control to obtain local information corresponding to each of the air conditionings, and uploads the local information to the central controller at an end of each communication interval tgap, the central controller broadcasts coordinating information to each local controller.
In an embodiment of the present disclosure, the communication interval tgap may be a period between 15 seconds to 1 minute.
In block 2, when a communication between the central controller and each of the local controllers in block 1 is finished, based on the coordinating information sent from the central controller, each local controller begins to determine whether a power deviation in the air conditionings is beyond an action dead zone at a beginning of each action period tact, if yes, a frequency regulation control action is performed, else, no action is performed and operation states of all the air conditionings at a beginning of a next action period are estimated.
If a current time reaches to a beginning of a next communication interval, block 1 is executed, else, block 2 is repeated.
In an embodiment of the present disclosure, the action period tact may be 1 second or other preset times.
In an embodiment of the present disclosure, the next action period is an action period tact interval from current moment, i.e. there is one action period tact between the beginning of the next action period and the current moment.
In some embodiments, block 1 includes following sub-acts.
In block 11, each local controller i, i=1.2 . . . N, performs the room thermal model parameter identification according to air temperature data recorded at each temperature acquisition period to obtain thermal model parameters corresponding to each room. N is a number of the local controllers.
In some embodiments, a precision degree of the thermal model parameters is determined according to a hardware storage capability of the local controller and an error requirement between a thermal model identification curve and an actual temperature curve.
In some embodiments, for each air conditioning room i, i=1.2 . . . N, three precision degrees of thermal model may be determined. The three precision degrees of thermal model include a zero-order thermal model, a first-order thermal model, and a second-order thermal model represented by equations (1)-(3) respectively.
ΔTi=αiΔti (1)
ΔTi=αieγ
ΔTi=αi1eγ
where, numbers of parameters to be identified in the three precision degrees of thermal models are 1, 2, and 4 respectively, i.e. αi in equation (1) is a thermal model parameter to be identified in the zero-order thermal model, αi,γi in equation (2) are thermal model parameters to be identified in the first-order thermal model, αi1,γi1,αi2,γi2 in equation (3) are thermal model parameters to be identified in the second-order thermal model, ΔTi (an initial value of switching temperature for short) is a difference between a current temperature Tai and an indoor temperature Taitog when an on-off state of the air conditioning is last switched, and Δti (an initial value of switching time for short) is a difference between a current time and a time titog when an on-off state of the air conditioning is last switched, and,
ΔTi=Tai−Taitog (4)
Δti=ti−t−tog (5)
The initial value of switching temperature Taitog and the initial value of switching time titog are taken as parameters of the thermal model as well as αi in equation (1), αi,γi in equation (2), or αi1,γi1,αi2,γi2 in equation (3).
In block 12, the local controller i identifies parameters of the thermal model corresponding to room i according to air temperature data recorded at each temperature acquisition period ttemp (a period between 1 to 4 seconds) in a communication interval tgap to obtain thermal model parameters corresponding to each room.
In some embodiments, k is denoted as a number of times that the temperature is recorded, and the on-off state statei (where statei=1 corresponding to state ON, statei=0 corresponding to state OFF) of the air conditioning i is recorded at each time a temperature is recorded. When a zero-order (linear) thermal model is selected, a corresponding parameter identification model is
when an on-off state of the air conditioning i is statei=1, state parameter αiON corresponding to the ON state is identified according to currently recorded k sets of switching temperature and switching time, when the on-off state of the air conditioning i is statei=0, state parameter αiOFF corresponding to the OFF state is identified according to currently recorded k sets of switching temperature and switching time. When a first-order model is selected, a corresponding parameter identification model is
similarly, two sets of parameters αiON,γiON and αiOFF,γiOFF are identified in different states ON and OFF respectively. When a two-order model is selected, a corresponding parameter identification model is
similarly, two sets of parameters αi1ON,γi1ON,αi2ON,γi2ON and αi1OFF,γi1OFF,αi2OFF,γi2OFF are identified in different states ON and OFF respectively.
In some embodiments of the present disclosure, a same thermal model is selected to use for all the local controllers. In an embodiment, a first-order model is selected to use for all the local controllers, the identified parameters of the i th room are αiON,γiON and αiOFF,γiOFF via common algorithms.
In block 13, each local controller performs the air conditioning autonomous control, according to following equations.
In the above equations, i=1.2 . . . N, Tai is an air temperature in the i th room, Δi is a temperature control dead zone corresponding to the i th air conditioning,
Denoting an i th local controller, an i th air conditioning and an i th room with mark i, i=1.2 . . . N. An air temperature in the i th room is Tai. An on-off state of the i th air conditioning is statei (where statei=1 corresponding to state ON, statei=0 corresponding to state OFF). In some embodiments, it is assumed that the i th air conditioning is a constant power air conditioning with an operation power Pi and with on-off state controlled only.
Each temperature sensor acquires an indoor air temperature of a corresponding room in real-time. Each local controller acquires the temperature data from a corresponding temperature sensor every temperature acquisition period ttemp (for example, a period between 1 to 4 seconds).
A required temperature Tsi of each air conditioning i is set directly by the user, and each air conditioning i has a temperature control dead zone Δi, which is a factory setting attribute, and in an embodiment, Δi is assumed to be 1° C. Equation (6) shows that if statei=0, i.e. the air conditioning is in an OFF state, when the room air temperature Tai rises to the upper bound
In block 14, at an end moment (i.e. a communication moment) of the communication interval tgap between the local controller and the central controller, each local controller uploads the local information to the central controller.
The local information includes the indoor air temperature acquired most recently Tai of the room, the on-off state statei of the air conditioning, the operation power Pi, the required temperature Tsi, the temperature control dead zone Δi, and the thermal model parameters αiON,γiON, αiOFF,γiOFF, Taitog, and titog.
In block 15, the central controller collects all the local information from the local controllers and broadcasts all collected information to each local controller as the coordinating information, and the central controller obtains a reference power P0i of each air conditioning after the thermal model parameters corresponding to each local controller are collected, a sum of reference powers of all the air conditionings is obtained as a reference power P0 of all the air conditionings, and the reference power of all the air conditionings P0 is broadcasted to each local controller.
The coordinating information includes the indoor air temperature Tai, the on-off state statei, the operation power Pi, the required temperature Tsi, the temperature control dead zone Δi, and the thermal model parameters αiON,γiON, αiOFF,γiOFF, Taitog, and titog.
In some embodiments, the reference power P0i corresponds to an average power of the i th air conditioning during an on-off period Ti (referring to a time period during which the i th air conditioning switches its on-off state in one cycle according to a local autonomous control logic) in a communication interval tgap.
Block 15 may include following acts.
The central controller calculates a first time ti(1), a second time t1(1), a third time ti(1), and a forth time ti(1) by solving the following equations respectively according to the upper
T
i
T
i
−Taitog=αiONeγ
T
i
T
i
−Taitog=αiOFFeγ
In above equations, ti(1) is a moment when the indoor temperature is equal to the upper bound temperature
A total time period Toni when the ith air conditioning is in an “ON” state in an on-off period Ti, and a total time period Toffi when the ith air conditioning is in an “OFF” state in an on-off period Ti are obtained according to following equations.
Ton
i
=t
i
(1)
−t
i
(2) (8)
Toff
i
=t
i
(4)
−t
i
(3) (9)
The reference power P0i of each air conditioning is calculated as:
In which, P0i is an reference power of the ith air conditioning, Toni is the total time period when the ith air conditioning is in an “ON” state in an on-off period Ti, Toffi is the total time period when the ith air conditioning is in an “OFF” state in an on-off period Ti, Pi is an operation power of the ith air conditioning.
The reference power of all the air conditionings P0 is obtained by summing all the reference powers P0i of the air conditionings according to following equation.
The central controller broadcasts the reference power P0 of all the air conditionings to each local controller.
In some embodiments, a control objective of primary frequency regulation response of the air conditioning cluster is set as making a difference ΔP between a real-time total power P(t) of all the air conditionings and the reference power P0 of all the air conditionings to be directly proportional to a real-time frequency deviation Δf, satisfying following equation.
ΔP=P(t)−P0=K(f(t)−f0)=KΔf (12)
In which, f0 is a reference frequency, being 50 Hz for Chinese mainland, f(t) is a real-time frequency obtained by the frequency sensor, K is a power-frequency response coefficient and set to a same value for all the local controllers. K may be determined according to a ratio of a total power of the air conditioning cluster to a maximum frequency fluctuation in history. The greater K is, the more the air conditioning involves in the frequency regulation, and the smaller K is, the less the air conditioning involves in the frequency regulation.
Block 2) includes the following actions.
In block 21, a frequency of the power grid is acquired by a frequency sensor every action period tact, and each local controller calculates a power deviation δ of all the air conditionings according to the acquired frequency of the power grid at the beginning of each action period tact.
In some embodiments, each local controller calculates the real-time total power P(t) of all the air conditionings according to the received coordinating information (air temperature Tai, on-off state statei and power Pi of the air conditionings in all the rooms) broadcasted by the central controller via following equation:
where. i=1.2 . . . N, Pi is the operation power of the ith air conditioning, statei is an on-off state of the ith air conditioning.
Then, the power deviation δ of all the air conditionings is calculated according to following equation.
δ=P(t)−P0−KΔf,
where, P(t) is the real-time total power of all the air conditionings, P0 is the reference power of all the air conditionings, K is a power-frequency response coefficient set for all the local controllers, Δf is a real-time frequency deviation.
In block 22, each local controller determines whether the power deviation δ is in the action dead zone ξ, when the power deviation δ is in the action dead zone ξ, the air conditioning does not participate in the frequency regulation control, when the power deviation δ is not in the action dead zone ξ, the air conditioning participates in the frequency regulation control action in the present action period.
In some embodiments, ξ may be set according to accuracy requirement, for example, in an embodiment, ξ is 1 KW.
In some embodiments, if|ξ|≧ξ, the power deviation δ is determined to be in the action dead zone ξ.
In some embodiments, block 22 includes following actions.
In block 221, a temperature priority Tprii of each local controller is obtained according to following equation.
In which, Tprii is a temperature priority of ith local controller, Tai is the indoor air temperature, Zsi the required temperature corresponding to the ith air conditioning set by a user, Δi s the temperature control dead zone, statei is the on-off state of the i th air conditioning (ON corresponds 1, OFF corresponds to 0).
Equation (14) means that the air conditioning in a room where the air temperature is closer to a boundary of the temperature control dead zone corresponds a higher priority. When statei=1, i.e. the air conditioning is in an “ON” state, the lower the air temperature Tai is, the higher the priority Tprii is, and the air conditioning will be turned off more preferentially in a local frequency regulation process; When statei=0, i.e. the air conditioning is in an “OFF” state, the higher the air temperature Tai is, the higher the priority Tprii is, and the air conditioning will be turned on more preferentially in the local frequency regulation process.
In block 222, when δ>ξ, temperature priorities Tprii of air conditionings whose statei=1 are selected, and an array quON is generated accordingly with its rows arranged according to values of the temperature priorities Tprii in a descending order, the first column of the array is Tprii, the second column is Pi, the third column is i, and the number of rows in the array quON is denoted as r, a minimum control set which can regulate the power deviation into the dead zone is selected according to r*=min{r|Σd=1rquON(d,2)≧δ−ξ}, a set ION of numbers of the air conditionings to be regulated in the present operation is extracted from the minimum regulation control set according to ION=quON(j,3), j=1, 2, . . . , r*, and ION′={iεION|Tai<Tgoni} is calculated (in which, as a parameter represents a participating degree of the air conditioning in the frequency regulation, Tgoni may be preset by users of the air conditionings and people who controls the frequency regulation system, for example, Tgoni may be set as Ti+0.8Δi), if a number of an air conditioning controller ilocalεION′, an air conditioning corresponding to the an air conditioning controller ilocal is controlled to participate in the present frequency regulation control, i.e. a state of the air conditioning corresponding to the an air conditioning controller ilocal is switched (turn off the local air conditioning), else, no action is performed.
In block 223, when δ<−ξ, temperature priorities Tprii of air conditionings whose statei0 are selected, and an array quOFF is generated accordingly with its rows arranged according to values of the temperature priorities Tprii in a descending order, the first column of the array is Tprii, the second column is Pi, the third column is i, and the number of rows in the array quOFF is denoted as r, a minimum control set which can regulate the power deviation into the dead zone is selected according to r*=min{r|Σd=1rquOFF(d,2)≧−δ−ξ}, a set IOFF of numbers of the air conditionings to be regulated in the present operation is extracted from the minimum regulation control set according to quOFF(j,3), j=1, 2, . . . , r*, and IOFF′={iεIOFF|Tai>Tgoffi} is calculated (in which, as a parameter represents a participating degree of the air conditioning in the frequency regulation, Tgoffi may be preset by users of the air conditionings and people who controls the frequency regulation system, for example, Tgoffi may be set as
In block 23, after the frequency regulation in block 22 is finished, each local controller estimates the on-off states of all the air conditionings at a beginning of a next action period.
In some embodiments, the next action period is one action period tact ahead from the present moment.
Because on-off states of some of the air conditionings have been changed in the present action period, each local controller estimates the on-off states of all the air conditionings at the beginning of the next action period after each frequency regulation in block 22 is finished.
The process (block 23) of estimating the on-off states of all the air conditionings includes following actions.
In block 231, the set ION′ or IOFF′ in block 22) are obtained.
In block 232, it is set that i=1.
In block 233, it is determined whether iεION to determine whether the i th air conditioning participates in the frequency regulation action, if iεION, the present state of the i th air conditioning is “OFF”, i.e. statei0, and the air temperature Taitog before the switch is flipped and the moment titog when the switch is flipped are recorded. if iεIOFF, the present state of the i th air conditioning is “ON”, i.e. statei=1, and the air temperature Taitog before the switch is shifted and the moment titog when the switch is shifted are recorded;
In block 234, let i=i+1, if i≦N block 233 is executed, else, block 24 is executed.
In block 24, each local controller estimates air temperatures in other rooms at the beginning of the next action period, and modifies on-off state statei of the i th air conditioning at the beginning of the next action period tact according to the coordinating parameters transmitted from the central controller and the on-off states of all the air conditionings estimated in block 23 via the autonomous control method.
Block 21 is executed when the next action period comes, or block 1 is executed when the next communication interval begins.
The autonomous control method can refer to equations (6) and (7) illustrated in block 13.
Block 24 may include following acts.
In block 241, a first-order thermal model is used for estimating the temperature in a present embodiment, for the i th air conditioning, a time variance relative to titog at moment t is Δti, and i=1.
In block 242, if the on-off state of the i th air conditioning stored locally is “ON”, i.e. statei=1, the room air temperature stored locally is Tai(t)=αiONeγ
In block 243, if the room air temperature meets a condition Tai(t)≦Ti, the state of the i th air conditioning stored locally is statei=0, and Taitog and titog are recorded, if the room air temperature meets a condition Tai(t)≧
In block 244, let i=i+1, if i≦N block 242 is executed, else, block 21 is executed when the next action period tact comes, or, block 1 is executed if next communication moment comes.
The method for regulating primary frequency of a power grid based on an air conditioning load cluster in a large building according to embodiments of the present disclosure has following characteristics.
With the method according to embodiments of the present disclosure, by taking advantage of heat capacity of large buildings, the two layers control structure including the central coordinating layer and the local control layer is formed, via rapid control of the air conditioning cluster, it is now possible to involve the air conditioning cluster in primary frequency regulation with a linear power-frequency characteristic similar to that of an electric generator. Each air conditioning performs a primary frequency regulation response locally to increase the speed of entire response, and communicate with the central controller every a certain time interval to upload local information and obtain overall coordinating information so as to ensure accuracy of the entire power-frequency linear response. Meanwhile, a temperature monitor threshold guarantees comfort of users and useful life of the equipment will not be significantly affected.
With the method according to embodiments of the present disclosure, a two-layer control structure including a slow centralized coordination and a rapid distributed local control is provided. In the centralized coordinating layer (i.e. the central coordinating layer), information of each room, such as operation power and state of corresponding air conditioning, the temperature in the room, thermal model parameters of the room, etc., is collected according to coordinating control period, and then is broadcasted to each of the local controllers. The problems of long time delay in centralized control and lack of coordination in distributed control are solved, thus improving the control accuracy and solving the problem of rebound effect.
The controllers in the local control layer estimate operation states of all the air conditionings and temperatures in all rooms based on dynamic thermal models respectively, and sequence the air conditioning cluster accordingly. Whether a local frequency regulation will be triggered is determined by an order of the air conditioning in the sequence and a real-time frequency deviation. The method is a local algorithm, thus improving speed of response to the power-frequency deviation.
With the method according to embodiments of the present disclosure, loads of the air conditioning cluster is a linear response to a frequency deviation and the comfort of users is not effected, the contradiction of slow response in central control and lack of coordinating information in local decentralized control when an air conditioning cluster participating in primary frequency regulation is eliminated. The control accuracy is increased and the problem of rebound effect is solved.
Number | Date | Country | Kind |
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201610390839.X | Jun 2016 | CN | national |