He Wang
Hongfeng Chen1- 1School of Technology, Beijing Forestry University, Beijing, China
- 2Energy Development Research Institute of China Southern Power Grid, Guangzhou, China
In the context of global energy transformation, it is particularly important to tap the potential of flexible load on the distribution network side to participate in grid operation. As an important flexible adjustable load in the distribution network, air conditioning loads have typical characteristics of thermal energy storage, rapid response, and flexible scheduling, which is an ideal load resource. Effective and reliable load aggregation technologies for air conditioning load participation are the basis for operation in a power grid. To better understand the current research status of air conditioning load aggregation technologies and make full use of the existing research results to carry out further research, this paper comprehensively reviews the various aggregation technologies being used in distribution networks, including the modeling strategy for air conditioning load aggregation, control strategy, control method, and application analysis. Moreover, future research directions are summarized as a guide to improving the technology of air conditioning load aggregation.
1 Introduction
At present, the large-scale development and utilization of new energy has become a common choice for all countries in the world to promote energy transition and ensure energy security (Suo et al., 2021). New energy is mainly used by the grid in two ways: large-scale centralized grid connection; or hierarchical distributed grid connection. Large-scale centralized grid-connected new energy units, such as traditional fire, water, and nuclear power units, present difficulties in terms of conducting centralized management and control. The power grid needs to reserve sufficient capacity to cope with its high levels of randomness and volatility (Naik et al., 2018; Gil et al., 2020). However, the hierarchical and distributed new energy grid connection makes the capacity and availability factor of each region in the grid different at each moment. This will increase uncertainty in the power flow of the power grid, increase the risk of branch circuits, cross-section active heavy loads, or overruns, increase difficulties related to frequency and peak regulation, and endanger the security of the power grid (Jiang et al., 2011; Luo et al., 2019). Dealing with these problems and improving the grid’s new energy consumption capacity and stable operation is generally achieved by increasing the reserve of the power system, but this method will lead to an increase in grid investment and the waste of resources. In recent years, generally speaking, starting from tapping the demand response load resources on the distribution network side, increasing the potential of the demand response load resources on the distribution network side to participate in grid regulation has been favored by researchers (Mohammadi et al., 2011; Madzharov et al., 2014; Wang et al., 2017).
Compared with the power generation side, the demand response load resources on the distribution network side have lower control costs and faster response speed. Among the various demand response load resources on the distribution network side, the air conditioning load accounts for a large proportion. In many countries, buildings account for a large proportion of the total energy consumption, and almost half of the energy consumption is caused by the heating, ventilation, and air conditioning (HVAC) systems (Zhao et al., 2021). For example, available data and market surveys conducted in Ghana have shown that 60–80% of electricity consumed in the offices of public and commercial buildings was used to run air conditioners to provide indoor thermal comfort for productive office work (Opoku et al., 2019). A large amount of air conditioning load entails huge response potential. At the same time, air conditioning load as a typical temperature control load has cold and hot storage capacity and can effectively respond to energy demand without affecting human comfort. Compared with other distribution network loads, it has broader application prospects. However, the power of a single air conditioner is small, and the power is easy to jump. Through effective control methods and reasonable control modes, a combined polymerization that combines multiple air conditioners has great potential. Further, it is easy to control. On the one hand, it can provide a variety of auxiliary services for the power grid and can be used as an important distribution network demand response load resource for in-depth exploration. On the other hand, it has good economic and environmental benefits.
Technically, the air conditioning load in the power grid is widely used, characterized by its large amount, wide distribution, small capacity, and different characteristics. Stable and advanced two-way communication (Viel et al., 2020) and advanced measurement techniques (Zhang et al., 2020) can be applied to the grid. The continuous development of active distribution networks (Martins and Borges, 2011) and virtual power plant (VPP) technology (Pudjianto et al., 2007) provides an opportunity and a solid technical foundation for centralized air conditioning loads to participate in grid operation.
Air conditioning load aggregates participate in different power system application fields, and different modeling methods are also required. When air conditioning load aggregates are included in power system stability calculations, it is necessary to appropriately simplify the air conditioning load model from the perspective of the power grid (Waseem et al., 2021). The air conditioning model is equivalent to the relevant constant impedance model, constant current model, constant power load model, etc., which meet the grid stability calculation (Waseem et al., 2021). For example, if the application field is power system transient calculation, the air conditioning model needs to be equivalent to a corresponding model that conforms to transient calculations, such as an air conditioner compressor single phase induction motor (SPIM) model for use in electromagnetic transients (EMTs) (Liu et al., 2013), while a thermal model of a room and the electrical model of an inverter AC is required for providing FRS (Hui et al., 2019), etc. These modeling methods are of great significance for the macroscopic participation of air conditioning load in the stability analysis and power flow calculation of the power system, but they ignore the unique properties of the air conditioning itself and the environment in which the air conditioning is located, and at the same time, it is impossible to consider the user experience in a refined manner. Therefore, this is not suitable for modeling air conditioning in demand response. Relatively speaking, the air conditioning load has the advantages of rapid response and easy control, so the demand response of participating in the power grid after aggregation has been the focus of researchers. The load model of demand response in the distribution network needs to be based on the characteristic relationship between room temperature and air conditioning load, and the model should be refined considering the response to the customer’s feelings; for example, the thermal characteristics of buildings, multiple comfort requirements of users, and dynamic ambient temperature were comprehensively considered by Hui et al.(2022). On this basis, a multi-stage bidding strategy of a high-voltage air conditioning system based on an inverter was proposed to reduce energy costs and alleviate distribution network congestion. In order to solve the problems caused by standardizing the centralized control scheme of inverter air conditioners (IACs), Hong et al. (2022) developed a distributed consensus algorithm with a nonlinear protocol for IACs to achieve the regulation objective of guaranteeing customers’ comfort requirements. A smart grid interactive building controller was developed by Zhang et al.(2022), which can optimize building operation during demand response events. This article mainly summarizes the air conditioning load aggregation model for demand response in the distribution network.
Examining the demand response and regulation of power systems through the precise aggregation of air conditioning load in the distribution network is of great significance in breaking the boundary between the physical generation side and the user side of traditional power systems, promoting distributed energy access, fine grid management, and intelligent decision-making. Researchers both in China and abroad have also undertaken much useful research regarding air conditioning load aggregation technology. Based on the summary of the work of Chinese and foreign researchers, this article analyzes the aggregation modeling, control strategy, regulation method, and application of air conditioning load in the distribution network. The research status of demand response aggregation of air conditioning load in a distribution network is summarized using four dimensions. These four dimensions are complementary and organically unified. An accurate air conditioning aggregation model was used as the basis for the air conditioning load in the distribution network to participate in the grid demand response. An effective control strategy was used as a prerequisite for the distribution network load aggregates to participate in the grid response. An intelligent control method was used as the guarantee for the air conditioning load aggregate to participate in the grid operation. A demand response application analysis was used to analyze the effect of the air conditioning load aggregate in the power grid; this is an example verification of the previous three dimensions. Finally, this article examines the development trend of demand response air conditioning load aggregation technology in future distribution networks.
2 Air Conditioning System Model
An accurate single unit air conditioning system model is the basis of the effective aggregation of air conditioning. Early researchers mostly focused on single unit air conditioning systems and ignored the complex environment of air conditioning. For example, Mortensen and Haggerty (1990) established five state equations for an air conditioning system operation by studying the transient state of recovery in the start-up process of cooling and heating load. Malhame and Chong (1985), considering the dynamic characteristics of the air conditioning system, modeled the switching dynamics of a single device and proposed a stochastic mixed-state model for the air conditioning system. Based on research on the relationship between the temperature and the power of the air conditioning system in the building, the complicated environment of the air conditioning system has been increasingly taken into account, and a more mature model of the air conditioning system has been developed. The model can divided into two parts. The first part is the building’s thermodynamic model (Sonderegger, 1978; Bruning, 2004; Kämpf and Robinson, 2007; Lu, 2012; Zhang et al., 2012; Zhang et al., 2013; Peppanen et al., 2014; Hao et al., 2015; Zhang et al., 2021), which describes the time-varying relationship between the indoor temperature of the building where the air conditioner is located and the refrigeration (heat) quantity of the air conditioner. The second part is the electrothermal conversion model, which describes the quantitative relationship between air conditioning power and refrigeration (heat) quantity (Lu and Chassin, 2004; Lu, 2012; Kim et al., 2015; Yan et al., 2015; Kim et al., 2016; Peng et al., 2020). The first part is used to describe the relationship between the air conditioning refrigeration capacity and the surrounding environment, while the second part describes the relationship between the air conditioning motor and air conditioning refrigeration capacity.
2.1 Thermodynamic Model for Air Conditioning
The study of the thermodynamic model of the building in which the air conditioner is located began some time ago, and the current models are more mature, mainly comprising the equivalent thermal parameter (ETP) model (Sonderegger, 1978; Bruning, 2004; Kämpf and Robinson, 2007; Lu, 2012; Zhang et al., 2013; Peppanen et al., 2014) and the air conditioning load modeling method based on the cold (hot) load calculation (Bruning, 2004; Peppanen et al., 2014). The ETP model introduces the concepts of power supply, resistance, and capacitance into thermodynamics, adopts the circuit parameter model of power supply, resistance, and capacitance, and describes the indoor and outdoor environment characteristics (indoor and outdoor environment temperature, indoor and outdoor heat production, and indoor and outdoor heat exchange) and other thermodynamic behavior (Malhame and Chong, 1985). A classical thermodynamic model of the third-order state space was proposed by Zhang et al. (2013), which takes into account the air temperature change process in the building, the temperature difference between indoors and outdoors, and other thermodynamic scenarios in detail. This model has high accuracy. Lu (2012) and Zhang et al. (2012) ignored the temperature difference between indoors and outdoors, and the model was reduced to a second-order model. To simplify the calculation, the model was equivalent to the first-order model (Hao et al., 2015; Zhang et al., 2021), which only considered the process of indoor temperature change. Although the high-order model had high accuracy and provided a detailed description of the thermodynamic process under air conditioning, the computational process was complicated, and generally speaking, the first-order model has been favored by the majority of researchers. The ETP first-order equivalent thermodynamic parameter model is shown in Figure 1.
FIGURE 1. ETP first-order equivalent thermal parameter model diagram.
The first-order differential equation for the ETP model shown in Figure 1 can be obtained as follows:
where: C is the equivalent heat capacity of the room (F); Ti(t) is the indoor temperature at time t (°C); T0(t) is the outdoor temperature at time t (°C); R is the equivalent thermal resistance of the room (Ω); and Q(t) is the cooling capacity of air conditioning at time t (kW).
Assuming that the outdoor temperature does not change in the step time t, the relationship between the room temperature and the cooling capacity of the air conditioner can be obtained by discretizing the above differential equation as follows:
The ETP model effectively describes the time-varying process of the room temperature in a building, which lays a theoretical foundation for the large-scale aggregation of the air conditioning load. Considering the influence of indoor and outdoor environmental factors on the model parameters, it is necessary to dynamically identify the parameters of the ETP model (Che et al., 2019). Commonly used dynamic model parameter identification methods include the Hilbert transform (Shi et al., 2009), wavelet transforms (Tsatsanis and Giannakis, 1993), the adaptive method, the state estimation method, etc. However, a scenario suitable for Hilbert transform needs to meet the mathematical conditions of Hilbert transform. Wavelet transform needs a reasonable selection of wavelet basis functions. The adaptive method can achieve better identification results when the parameters change, and the Kalman filtering method (Guo, 1990) and particle filtering (Ristic et al., 2003) in the state estimation method can better solve the problem of model parameters. Cheng et al. (2017) used the variable window particle filter method to effectively identify the parameters of the ETP model. In short, the model parameters need to be chosen based on a reasonable parameter identification method according to the actual needs.
The model based on the cooling (heating) load calculation is based on the law of the conservation of energy. The energy change of the building where the air conditioner is located per unit time is equal to the difference between the cooling (heating) quantity of the air conditioner and the cooling load of the building. The cooling load includes outdoor cooling load (solar radiation, heat entering other rooms, etc.), indoor cooling load (human body fever, heat dissipation of other household equipment, etc.), and fresh air cooling load, etc. (Tiptipakorn and Lee, 2007; Khammayom et al., 2020). Through the energy identity of the building, the time-varying equation of indoor temperature can be derived:
where α, β, and γ are constant coefficients.
The modeling method for cooling (heating) load calculation does not need to identify the thermodynamic parameters, but it is more sensitive to the composition of the cooling load in the room. The emphasis of the two thermodynamic models is different. The ETP model focuses on describing the dynamic heat transfer between indoors and outdoors, while the modeling method based on cooling (heating) load calculation focuses on the accurate static calculation of cooling and heating load. However, the essence of the two methods is the same, which is based on the principle of conservation in the process of energy exchange. The performance comparison between the two models is shown in Table 1.
TABLE 1. Features of two thermodynamic models.
The process of air conditioning load aggregation is affected by many factors, and various factors will change with time, so it is necessary to select the air conditioning system model according to the needs of load aggregation modeling.
2.2 Electromechanical Conversion Model for Air Conditioning
The electromechanical conversion model for the air conditioning system is mainly used to describe the relationship between air conditioning refrigeration (heat) and air conditioning power, and the type of air conditioning is related to the type of air conditioner. If it is a split fixed frequency air conditioner, the conversion mode is simple, and the electric power can be multiplied by the energy efficiency ratio of the air conditioner (Lu and Chassin, 2004; Lu, 2012; Yan et al., 2015; Zhang et al., 2021). The relationship between electric power and refrigeration (heat) of split frequency conversion air conditioners has been described by Kim et al. (2015) and Kim et al. (2016). The energy efficiency ratio is not constant, and its value is related to the frequency of the compressor: the lower the frequency, the higher the energy efficiency. On the other hand, the transformation relationship of central air conditioning is more complex, and there are more factors between its power and refrigeration (heat) capacity (energy efficiency ratio). In addition to the compressor, it also involves many modules, such as a fresh air system, cold storage (ice) system during refrigeration, cooling (frozen) water circulation system during heat release, etc. (Peng et al., 2020), which is difficult to model. At present, there is no perfect model for central air conditioning.
Although researchers in China and abroad have undertaken much research on the electric cooling (heat) conversion models of various air conditioning systems, most have focused on split fixed frequency air conditioners, and research on the participation of split frequency conversion air conditioners in the power grid model is lacking. In particular, the electromechanical conversion model of variable frequency air conditioners needs further research. At the same time, because the central air conditioning involves so many modules, and the relationship between each module is complex and changeable, researchers need to further explore this aspect.
3 Modeling of Air Conditioning Load Aggregation
There are many kinds of air conditioners in the distribution network, and the load characteristics of different air conditioners vary. Therefore, it is necessary to cluster the air conditioners first and then aggregate them. Clustering technology refers to the combination of similar data in the same cluster, which can be used to cluster a large number of air conditioning loads. By clustering the air conditioning loads with similar regulation potential and operable space into a group, the demand response regulation ability of the user side can be brought into full play (An et al., 2018; Patteeuw et al., 2019; Li et al., 2020; Luo 2020; Chen et al., 2022). Clustering algorithms include traditional algorithms such as K-means clustering, hierarchical clustering, fuzzy clustering, etc. Several common clustering algorithms are shown in Table 2.
TABLE 2. Comparison of four Classical clustering methods.
The so-called aggregation refers to the air conditioning load group as an organic whole. In the context of the in-depth study of the air conditioning load model, researchers have found that, as far as the single air conditioning load is concerned, the power is small and easy to increase (Ucak and Caglar, 1998; Molina et al., 2004; Molina-García et al., 2011; Zhang et al., 2015; Song et al., 2017). In contrast, air conditioning load aggregates have the advantage of great potential and flexible response, so the aggregation model of air conditioning load groups has received increasing attention. Figure 2 shows the framework for air conditioning load aggregation. The aggregation strategy is formulated based on the basic model, and the aggregation model at the application level of the system is obtained; subsequently, the model needed at the application level of the system, in turn, affects the formulation of the aggregation strategy.
FIGURE 2. The framework of air conditioning load aggregation.
3.1 Polymerization Method
According to researchers’ different focus, the aggregation methods can be divided into the following categories: Monte Carlo method, state transition and state queue, stochastic model, etc. (as shown in Table 3). The Monte Carlo method, which focuses on expanding the spatial thermal model of a single air conditioning system, is the most direct aggregation method (Ucak and Caglar, 1998; Lin et al., 2012; Zhang et al., 2015; Song et al., 2017; Zhou et al., 2019). Lin et al. (2012) and Zhou et al. (2019) used the Monte Carlo statistical survey method to simulate the overall characteristics of air conditioning load aggregates. Molina et al. (2003) sampled the relevant parameters of the load physical model based on the Monte Carlo method, and a load aggregation model was established. The Monte Carlo principle is simple, and a more accurate aggregation model can be established for air conditioning loads with similar parameter characteristics. However, when the heterogeneity of air conditioning load parameters is obvious, it is difficult to use the Monte Carlo model to describe it, and the accuracy is reduced.
TABLE 3. Advantages and disadvantages of various aggregation methods.
However, it is inevitable that, in the process of practical application, the air conditioning load varies due to its situation (equipment type) and external environment (building structure, climate, etc.). Theoretically, the K-means method can be used to cluster and group the air conditioning parameters. Kalsi et al. (2012) and Zhang et al. (2013) first grouped the air conditioning parameters by similarity (K-means method). They then established a second-order ETP model with high accuracy for the same group of air conditioners, subsequently adding to each group of air conditioners according to different weights. Thus, the aggregation model of air conditioning load can be established. The neural network is another clustering method that can be used to deal with different properties of air conditioning load parameters. A novel control strategy for the aggregation model of air conditioners based on the thermal model of the room was proposed by Hui et al. (2017). By resetting the temperature of each air conditioner, the operation state can be adjusted temporarily without affecting customers’ satisfaction. The operation characteristics both of individual air conditioners and the aggregation model of air conditioners has also been analyzed. Zhao et al. (2017) used a stochastic battery model to solve the problem of the heterogeneity of load parameters, considering the air conditioning load polymerization as a virtual battery, and then fitting the parameters of the virtual battery. Hao et al. (2015) used the Minkowski sum to approximate the parameters of the loaded polymerization. Zhou et al. (2019) focused on air conditioning loads as an example of thermostatically controlled loads (TCLs) and proposed a simple and transferable aggregate model by establishing a virtual house model, which accurately captured the aggregate flexibility. Lin et al. (2012), Mai and Chung (2015), and Mahdavi et al. (2017) established second- and third-order heat storage models of air conditioning systems considering related factors such as air temperature differences and solar radiation in different geographical locations and aggregated the air conditioning load based on the actual scenario of multi-area buildings. On the whole, expanding the spatial thermal model of a single air conditioning system in this way can clearly describe the working process and thermodynamics of the air conditioning system and meet the application requirements in many working conditions. However, this method cannot accurately describe the dynamic evolution process of air conditioning load aggregates, as is not conducive to the control of air conditioning load aggregates. To better describe the dynamic evolution process of air conditioning load aggregates, researchers use state transition to describe air conditioning load aggregation.
Typical methods, such as state transition and state queue, are used to describe the dynamic evolution model of air conditioning load aggregation. A state queue model was proposed to simulate air conditioning load aggregation by Lu and Chassin (2004). Lee et al. (2011) presented a novel load management technique for the air conditioner loads in large apartment complexes using systematic aggregations and load factor controls of the air conditioner loads based on a queuing system model and the Markov birth and death process. Koch et al. (2011) and Mathieu et al. (2013) used a Markov chain to describe the state evolution model of air conditioning load aggregates, and used the Kalman filter method to estimate the state matrix. However, this method requires a large amount of calculation and may fall into the possibility of non-convergence with the increase of the state of air conditioning load aggregates. Song et al. (2019b) proposed an improved aggregate TCL state-space model and a TCL aggregation control model to track the collective TCL performance considering the compressor delay when applying the control signal. State transition and state queue models describe well the dynamic evolution process of air conditioning load aggregation. However, in most cases, to facilitate the solution of the model, it is necessary to simplify the model and study the randomness of load aggregation.
Randomness is also one of the difficulties in modeling the aggregation model. To solve the randomness of the air conditioning load aggregation model, Cheng et al. (2018) adopted the electric power change and heat transfer process in the process of the load operation. The load aggregation model was derived by using the Fokker–Planck equation. This method is suitable for the study of randomly distributed load aggregation power demand. Wu et al. (2018) used the ETP model to analyze the principle of the aggregate load fluctuation of air conditioners with similar or the same parameters caused by traditional temperature regulation methods, and an effective improvement method was put forward. A new distributed aggregation control method was proposed by Wang et al. (2019) for multiple grid-interactive smart buildings in one frequency control area (e.g. a residential community) to provide fast frequency support. The proposed method was based on the distributed sliding mode control via a leader–follower communication scheme. Liu and Jiang (2021) established an energy consumption prediction model for HVAC systems by using the back-propagation neural network (BPNN) and adaptive boost (AdaBoost) algorithms. The random model simulated the random characteristics of air conditioning load aggregation. However, generally speaking, the random model was affected by model samples, equipment data, and social meteorological factors, so the model was relatively rough. A refined stochastic model requires further research.
3.2 System-Application-Level Aggregation Model
The final form of air conditioning load aggregation is based on system application. According to the response needs of the system, air conditioning load aggregation can participate in the scheduling and operation of the system or provide auxiliary services of various time scales for the system. At the application level of system response, different time-scale aggregation models mainly include the virtual unit model, virtual battery model, power pulse model, etc. Wang G et al. (2021) proposed an enhanced sufficient battery model (ESBM) as well as a binary search algorithm for an improved inner approximation of the aggregate flexibility of TCL arrays. The air conditioning load was aggregated into a peak shaving unit to participate in the demand response of the power grid by Lee et al. (2011). The model parameters of the virtual battery model were fitted by Hao et al. (2015). The multi-time-scale air conditioning load aggregation model for fixed frequency air conditioning was established by Song et al. (2019a), including the second virtual battery model, minute pulse power model, and hour virtual unit model. According to the inherent heat storage capacity of the air conditioning load, the air conditioning load was modeled as a virtual energy storage device by Ji et al. (2020). Song et al. (2018) established virtual battery and virtual unit models with different time scales according to the characteristics of air conditioning load groups at different time scales. Virtual units or batteries and conventional units or batteries also present different characteristics. The basic model and aggregation method provides an aggregation model for the system application level, and the system application level provides modeling guidance for aggregation.
4 Air Conditioning Load Aggregation Control Mode
An effective control mode is the means to ensure that the load body of the power system normally participates in the demand response of the power grid. The participation of air conditioning load aggregates in the power grid regulation and control process is a typical hierarchical control (Ju et al., 2019; Xia et al., 2019). The hierarchical control framework is presented in Figure 3, in which the top (control) layer is the power grid regulation. It is necessary to issue response instructions to the middle layer (aggregation layer) according to the needs of the power grid, while the middle layer formulates the aggregation modeling method and aggregation control strategy of load aggregates that meet the needs of the power grid according to the instructions of the power grid. Finally, the middle layer sends the control instructions to the bottom layer (response layer). In some cases, the control layer will send control instructions directly to the response layer. This control method is also referred to as centralized control (Zhang and Lu, 2013; Vanouni and Lu, 2015; Gong et al., 2021). Bashash and Fathy (2013) used a new framework of partial differential equations to model these loads, and developed a bilinear partial differential equation model and a sliding mode controller for real-time load management of constant temperature air conditioning. The phenomenon of aggregate load fluctuation was effectively overcome using a temperature control load polymerization by Wu et al. (2018). This control mode has high requirements for the communication system, so it is necessary to set up special communication lines between each layer, which increases the control cost. However, this control mode is more predictable, and it is a system-friendly control mode.
FIGURE 3. Air conditioning load aggregation layered control architecture.
Another control method is to directly add relevant intelligent response devices at the bottom (response layer) to judge whether to participate in the control according to the situation measured by the intelligent response installation. This kind of control is also called decentralized control. Peppanen et al. (2014) proposed a multi-agent distributed cooperative control model based on master–slave consistency to coordinate the control of the middle layer. The autonomous control model for large-scale air conditioning load was established by Lee et al. (2011). This model can enable large-scale air conditioning aggregate load to be calculated and adjusted flexibility and to respond to relevant control signals. Guo et al. (2016) proposed a game-theoretic approach to develop a decentralized aggregated control algorithm. The convergence of the proposed algorithm was shown by employing potential game theory. An event-based distributed control strategy was proposed by Wan et al. (2021). This strategy exchanged the adjacent temperature control load information only when the dynamic event trigger condition was satisfied, in order to intelligently determine the necessary transmission frequency to save communication resources.
5 Demand Response and Economic Operation of Air Conditioning Load Aggregates
In the process of air conditioning load aggregation participating in power grid demand response, the control method and demand response strategy complement each other. According to the different response modes of air conditioning load (Callaway, 2009), there are mainly two ways for air conditioning users to participate in demand response: incentive-based demand response (Yao et al., 2005; Lee et al., 2008; Escrivá-Escrivá et al., 2010; Hui and Yang, 2012; Sinitsyn et al., 2013); and price-based demand response (Li et al., 2016a; Li et al., 2016b).
5.1 Demand Response Based on Incentive
Incentive-based demand response is the attention response mode of air conditioning load aggregation, in which the direct load control (DLC) response is the most common and effective incentive-based demand response (Chu and Jong, 2008; Erdinc et al., 2019). The main control mode of DLC is the centralized control described Section 3 of this paper. The response process is that the power grid layer formulates the response strategy according to the power grid demand or electricity price information, and then directly controls the air conditioner through specific hardware. Generally speaking, the response strategies of DLC air conditioners can be divided into the following categories: temperature control response (Sinitsyn et al., 2013; Wu et al., 2018); switch control response (Yao et al., 2005; Lee et al., 2008); and periodic pause control response (Escrivá-Escrivá et al., 2010; Hui and Yang, 2012). The advantages and disadvantages of the three response strategies are shown in Table 4, in which the temperature control response mode takes the temperature control as the response decision variable, which is a relatively mild response measure, mainly based on the indoor and outdoor temperature changes and electricity price information where the air conditioner is located. This regulation mode provides a certain energy response on the premise affecting the user’s comfort as little as possible. However, its adjustable capacity is difficult to calculate, and its regulation capacity is limited. Wu et al. (2018) used 30,000 air conditioners with a power of 2.5 kW to simulate temperature regulation control. When the scheduling target accounted for 3.3% of the total air conditioning aggregate power, the scheduling result was not ideal.
TABLE 4. Three control methods of DLC.
Relatively speaking, the regulation potential of switch control response is greater. Switch control takes the air conditioning switch state as the decision variable, which generally means that when the power grid needs the air conditioning load to participate in the demand response, the switch instruction is issued to the air conditioner in advance. The air conditioning load is controlled according to the instruction. Switch control response is beneficial to the control of the regulation capacity of the upper power grid. Yao et al. (2005), to minimize the error between the actual value and the predicted value of the polymerization, used the iterative deepening genetic algorithm to solve the optimal switch combination state. Chu and Jong (2008) established an air conditioning load aggregation DLC model for outdoor temperature effect, user thermal comfort level, and air conditioning load recovery phenomenon. As a result, an air conditioning switch control response mode with a good peak cutting effect was established.
The periodic suspension control response takes the “duty cycle” of the air conditioner as the control decision variable, and the so-called “duty cycle” is the proportion of the running time of the air conditioner in a cycle on the premise of ensuring the user’s comfort to define the temperature control range. However, this frequent suspension operation of split air conditioners is not only difficult to respond to in time but also causes damage to the air conditioning load, which is mainly used in the field of central air conditioning (Hui and Yang, 2012). Hui and Yang (2012) analyzed the feasibility and practicability of the periodic pause control response of central air conditioning from the perspectives of system design and practical application. Taking into account the human comfort constraints and taking the maximum power saving as the objective function, an optimization model for the periodic pause control response of central air conditioning was established by Escrivá-Escrivá et al. (2010).
The aggregate response mode of air conditioning load based on excitation response is of great significance to the power grid, but there will inevitably be various working state transitions, such as on and off states. The transition of this state will create short-term power fluctuations in the air conditioning load, which will adversely affect the power grid. At present, there are relatively few studies on the quantification of the power fluctuation of the air conditioning polymerization and its impact on the power grid. The aspect needs to be further studied.
5.2 Demand Response Based on Price
The most typical method of price response is demand-side bidding (DSB). Price response leads to demand-side resources no longer being simple price receivers; they participate in the electricity market competition by changing users’ power consumption mode and obtaining certain economic benefits, which improves the degree of participation of demand-side resources and is of great significance for improving the two-way interaction between the network side and the demand side (Yan et al., 2015; Li et al., 2016). Li et al. (2016) considered the characteristics of the air conditioning load involved in the response in the process of designing the bidding strategy of the electricity market. Although forms of DSB regulation have been deeply studied outside of China (Li et al., 2016) and have become one of the main demand-side response methods, in China, this is still in its initial stage, and we need to formulate targeted DSB regulation methods according to the actual situation of our power grid.
On the whole, the demand response based on incentive is mostly used in the response mode of general air conditioners. Although the demand response based on price is random, its development prospects are broad. At present, when discussing air conditioning load aggregation, most of the regulation methods in the literature have only focused on one regulation method, and research on the integration and combination of multiple regulation modes is still relatively scarce.
5.3 Optimizing Economic Operation
The rapid growth of distributed energy resources (DERs) brings more fluctuating output power to the distribution network, and the output power of DERs is seriously affected by the environment, which has great uncertainty. The main power grid needs to reserve more flexible regulation resources to maintain the balance of the system, which reduces the economic benefits of the system (Hui et al., 2022). Air conditioning load has great regulation potential as a flexible load, and most modern commercial buildings are equipped with advanced building management system (BMS), which can reduce the cost of using commercial HVAC load to benefit the power system (Wang et al., 2021). Han et al.(2019) used the actual operation data to carry out simulation tests, which proved that air conditioning load control can improve the optimal allocation of resources and improve energy efficiency, not only improving the comfort of users, but also reducing the cost of power purchase by participating in demand-side management. Bhattacharya et al.(2019) proposed an algorithm based on low-complexity dynamic programming to control the switching on/off of HVAC units and minimize the cooling cost. An optimal dispatching method for intelligent buildings integrating an active distribution network considering the aggregate load rate of intelligent buildings was proposed by Jiang et al.(2018).
6 Air Conditioning Load’s Participation in the Demand Response of the Power Grid
The increasing integration of intermittent renewable energy brings challenges to the stable operation of the power grid. The intermittence and volatility of renewable energy increase the uncertainty of the system, which makes it more difficult to achieve the balance between supply and demand (Ji and Xu, 2020). For example, the rapid fluctuation of photovoltaic power generation may potentially affect the power balance and quality; the integration of wind power into the power system will lead to low or zero inertia, threatening its frequency stability (Mahdavi et al., 2017; Zhao et al., 2019; Jin et al., 2022). On the other hand, due to the complex load model and the complexity of human behavior, the comprehensive control of power load in large buildings has always been a challenge. The uncoordinated energy management of a large number of buildings in the distribution network feeder may make the distribution system enter a state of emergency in which the operational constraints are not fully satisfied. In addition, an increasing number of energy-saving frequency conversion air conditioners may produce a large number of harmonics in the power grid. The next peak load with insufficient reactive power may cause voltage collapse (Liu et al., 2018; Mirakhorli and Dong, 2018; Zhu et al., 2020).
Air conditioning load aggregates play an important role in stabilizing the fluctuation of new energy output, peak regulation, frequency regulation, and increasing system reserve in the power grid. It is of great significance to the reliable and stable operation of the power grid and the improvement of renewable energy consumption capacity.
6.1 Stabilizing the Fluctuation in New Energy Output
The volatility of renewable energy is an important issue that affects its consumption. The traditional way to limit the volatility of renewable energy is to improve the reserve of the system, which increases the operating cost of the system. Scholars in China and abroad have found that, through the aggregation of air conditioning load in the distribution network, it can be combined with the output of renewable energy, limit the volatility of renewable energy to a certain extent, and improve the consumption capacity of renewable energy in the power grid. Short et al. (2007) showed that air conditioning polymerization could effectively limit the power grid frequency fluctuation caused by the wind power grid connection. Peng et al. (2020), based on the analysis of the regulation characteristics of central air conditioning, established an air conditioning polymerization considering user comfort and air conditioning aggregation economy to stabilize the fluctuation in wind power output.
However, at present, research on the use of air conditioning load aggregation for new energy consumption is mainly aimed at the potential and the effect of new energy consumption, as well as the comfort of users, while research on the economy of air conditioning consumption using new energy is scarce. In the future, the problem of multi-objective absorption taking into account user comfort, economic benefits, and consumption potential should be considered.
6.2 Peak Shaving
The thermal inertia of temperature control load in distribution network load and the energy storage characteristics of energy storage load make it possible for flexible load aggregates to respond to power grid dispatching and participate in power grid peak regulation. The economy of heat storage load participating in power grid peak regulation was studied by Kämpf and Robinson (2007). A hierarchical control architecture for air conditioning load aggregates participating in power grid peak regulation was constructed by Ju et al. (2019). Lu (2012) considered the difference in air conditioning in the modeling of air conditioning aggregation, assuming air conditioning polymerization as the peak shaving unit of the power grid to participate in peak regulation.
At present, most research on air conditioning load participation in peak regulation focuses on the peak–trough difference and related economic problems reduced after air conditioning aggregation and peak regulation. The analysis of the impact of power uncertainty caused by the aggregation of air conditioning load on power grid operation (voltage, frequency, etc.) and the impact of air conditioning load aggregates on power grid operation after participating in power grid peak regulation is not yet deep enough and requires further study.
6.3 Frequency Modulation
The flexible load polymerization of the distribution network participates in the frequency stability control of the distribution network because of its advantages, such as high economic benefit and rapid response. Che et al. (2019) proposed a control method to track the secondary frequency modulation signal of the power grid by controlling the temperature of the air conditioner polymerization. Kim et al. (2015), Zhang et al. (2015), and Kim et al. (2016) also examined the primary or secondary frequency modulation of the power grid after effectively aggregating the air conditioning load.
Air conditioning load aggregation participates in the problem of power grid frequency modulation, which mainly focuses on the economic research regarding response control and frequency modulation. The admittance mechanism and management system of air conditioning load participating in frequency modulation are worthy of further exploration in the future.
6.4 Providing a System Backup
Air conditioning load aggregation in distribution networks can also provide support in increasing the system reserve and reducing system operating costs. Che et al. (2019) effectively analyzed the situation of providing a reserve for the power grid after air conditioning load aggregation. Cheng et al. (2017) considered that the temperature control load of residents (air conditioners, water heaters, etc.) could be used for system backup by aggregation. The economy of air conditioning load aggregates as a power grid rotating reserve was calculated by Khammayom et al. (2020). Tiptipakorn and Lee (2007) regarded the aggregate of air conditioning load as the reserve of the power system, and it was incorporated into the dynamic economic dispatching model of the power system. Based on the specific scenario of high power shortage of power system, the effectiveness of air conditioning load aggregation as the reserve can be explored.
As a system backup, air conditioning load has certain advantages, such as large capacity, economic and environmental protection, etc. However, the impact of air conditioning load aggregates on power grid demand response has been mainly addressed in economic research and reserve capacity research. The air conditioners involved in polymerization inevitably have the characteristics of dispersion, so it is necessary to consider the impact of communication architecture to study and design an economical and reasonable communication architecture while taking into account the reliability of communication. At the same time, the types of flexible loads (such as electric vehicles, energy storage, etc.) should be expanded to participate in the system reserve, and a multi-scale and multi-scenario power grid reserve model with multiple flexible loads should be studied to provide support for the safe and stable operation of the power grid and the deep absorption of new energy.
6.5 Air Conditioning Load in Virtual Power Plants (VPPs)
With the development of the smart grid and the improvement of communication technology, it is possible for flexible load to participate in power system regulation (Xu et al., 2020). As a typical constant TCL, air conditioning has the characteristics of inherent operation flexibility and schedulable load, which can be centrally managed by a VPP and gathered together to join the power market. A VPP optimizes resource allocation reasonably through control, measurement, and communication technology, which is a comprehensive technology and operation mode for air conditioning load to participate in power system operation and to facilitate the application of low-carbon renewable energy (Gong et al., 2021). Guo et al.(2021) quantified the potential of central air conditioning through a thermodynamic model, transforming central air conditioning into virtual unit model, and proposing a two-stage operation strategy of a VPP. A quadratic function model of trigger temperature and frequency variation of air conditioning compressor was established by Wan et al.(2017); the primary frequency modulation method and secondary frequency modulation method of energy storage system were combined to optimize the frequency of microgrid. A sequential demand response scheme as part of a VPP control was proposed by Gong et al.(2022) to reduce both ramping rate and peak power at the aggregated level.
7 Research Prospects
Although researchers in China and abroad have undertaken a lot of useful research on air conditioning load aggregation in the distribution network, there are still some directions that researchers need to pay attention to and explore more deeply:
1) Uncertainty quantification of air conditioning load aggregation modeling is required. There are too many random factors in the modeling process of air conditioning load aggregation, which will inevitably lead to uncertainty in the aggregation model. Future research needs to establish a fine-grained flexible load model based on in-depth analysis and quantification of the uncertainty of the air conditioning load in order to lay a foundation for the precise regulation and control of the flexible load in the power grid in the future.
2) Regarding the multi-time-scale fine modeling technology of frequency conversion and central air conditioning, most of the current literature is based on split fixed frequency air conditioning, but there are few studies on split frequency conversion air conditioning and central air conditioning. However, the proportion of frequency conversion air conditioners in the distribution network is increasing, and central air conditioning has high power consumption and great response potential, so it is a good response resource. To make variable frequency air conditioners and central air conditioners better participate in the regulation and control of the power grid, it is necessary to dig more deeply into the characteristics of variable frequency air conditioners and central air conditioners and establish a fine-grained model under multi-time scales.
3) Communication architecture design based on future communication technology is necessary. Communication is the soul of the aggregate regulation and control of the air conditioning load. The fragmentation and decentralization of air conditioning load in the distribution network will inevitably increase the cost of regulation and control communication and reduce the reliability of communication. If we want to carry out the in-depth application of air conditioning load aggregates in the power grid in the future, it is particularly important to design a new communication architecture for future communication technology with low delay, low power consumption, low cost, large capacity, and high reliability.
4) Our national conditions regarding air conditioning load aggregation must be considered in relation to participating in the power system demand response business model. There is a general trend for air conditioning load to participate in the demand response of power systems intelligently and automatically. It is necessary to formulate a strategy for air conditioning load aggregation through the development of laws for China’s power market in advance, on the premise of taking into account the interests of all parties. The formulation of this strategy is inseparable from the analysis of the potential of, and prospects for, air conditioning load participating in power grid operation, based on effectively evaluating the economy of air conditioning load participating in the actual operation of the power grid through technical means such as the power market and formulating the air conditioning load aggregation strategy in line with the development of laws for China’s power market.
5) Affected by the season, short-term but peak electricity demand will increase the cost of upgrading the power infrastructure. Applying the regulation ability of flexible load and improving the capacity of sustainable energy consumption is an effective way to alleviate the shortage of power resources. Exploring the control strategy of air conditioning polymerization that can comprehensively consider the duration of regulation and user comfort is key to unlocking the potential of air conditioning load in peak regulation and stable power fluctuation. This can be achieved through the centralized management of VPPs and access to the power market, in order to achieve the purpose of alleviating the fluctuation of renewable energy generation power output, improve the local utilization rate of low-carbon renewable energy, and alleviate power congestion in the distribution network.
6) It is necessary to formulate technical standards related to air conditioning load aggregation. The air conditioning load itself has unique characteristics. To make better use of load-side resources, it is necessary to develop relevant technical standards, such as load aggregation access standards, communication standards, etc.
8 Conclusion
Effective and reliable air conditioning load aggregation technology in the distribution network is of great significance for the power grid to provide new energy consumption capacity and ensure safe and stable operation. This paper has summarized the technical achievements of researchers in China and abroad, and has systematically discussed and summarized the problem of air conditioning load aggregation on the demand side of the distribution network. Further, this paper has summarized and analyzed the research content pertaining to the four dimensions of air conditioning load aggregation model, control methods, response strategies, and application, and future research directions have been proposed. It is hoped that this paper can provide some ideas and references for researchers regarding air conditioning load aggregation in the distribution network.
Author Contributions
HW completed the writing of the manuscript. HC and YL wrote sections of the manuscript. All authors contributed to manuscript revision and have read and approved the submitted version.
Funding
This work was supported by the Fundamental Research Funds for the Central Universities under Grant BLX2014-05. This research was supported by the National Natural Science Foundation of China (No. 52107069).
Conflict of Interest
YL was employed by Energy Development Research Institute of China Southern Power Grid.
The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s Note
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Keywords: air conditioning load, aggregate modeling, control method, response strategy, application analysis, literature review
Citation: Wang H, Chen H, Li Y and Liu S (2022) A Review of Air Conditioning Load Aggregation in Distribution Networks. Front. Energy Res. 10:890899. doi: 10.3389/fenrg.2022.890899
Received: 07 March 2022; Accepted: 06 June 2022;
Published: 11 July 2022.
Edited by:
Lieven Vandevelde, Ghent University, BelgiumReviewed by:
Hongxun Hui, University of Macau, ChinaTobias Massier, Independent researcher, Singapore
Copyright © 2022 Wang, Chen, Li and Liu. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: He Wang, wanghe@bjfu.edu.cn