Fast Demand Response with Variable Speed Thermal Loads - Towards Universal Modeling for Stability Assessment

Multi-district integrated energy system (IES) can make full use of the complementary characteristics of district power and thermal system, and loads in different districts. It can improve the flexibility and economy of system operation, which has a good development prospect. Firstly, based on the general energy transfer model of the district heating network (DHN), the DHN system is described by the basic equations of the heating network and nodes considering the characteristics of the transmission time delay and heat loss in pipelines. A coupling model of DHN and multi-district IES is established. Secondly, the flexible demand response (FDR) model of electric and thermal loads is established. The load characteristics of each district in IES are studied. A shiftable load model based on the electric quantity balance is constructed. Considering the flexibility of the heat demand, a thermal load adjustment model based on the comfort constraint is constructed to make the thermal load elastic and controllable in time and space. Finally, a mixed integer linear programming (MILP) model for operation optimization of multi-district IES with the DHN considering the FDR of electric and thermal loads is established based on the supply and demand sides. The result shows that the proposed model makes full use of the complementary characteristics of electric and thermal loads in different districts. It realizes the coordinated distribution of thermal energy among different districts and improves the efficiency of thermal energy utilization through the DHN. FDR effectively reduces the peak-valley difference of loads. It further reduces the total operating cost by the coordinated operation of the DHN and multi-district IES.

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Extending the Envelope of Demand Response Provision though Variable Speed Pumps

Procedia Engineering ◽

10.1016/j.proeng.2017.03.274 ◽

2017 ◽

Vol 186 ◽

pp. 584-591 ◽

Cited By ~ 11

Author(s):

R. Menke ◽

E. Abraham ◽

P. Parpas ◽

I. Stoianov

Keyword(s):

Demand Response ◽

Variable Speed

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The Multi-Station Based Variable Speed Limit Model for Realization on Urban Highway

Electronics ◽

10.3390/electronics9050801 ◽

2020 ◽

Vol 9 (5) ◽

pp. 801 ◽

Cited By ~ 2

Author(s):

Soobin Jeon ◽

Chongmyung Park ◽

Dongmahn Seo

Keyword(s):

Real Time ◽

Transportation Systems ◽

Traffic Information ◽

Transport Systems ◽

Speed Limit ◽

Stability Assessment ◽

Variable Speed ◽

Variable Speed Limit ◽

Traffic Conditions ◽

Real Time Traffic

Intelligent transport systems (ITS) are a convergence of information technology and transportation systems as seen in the variable speed limit (VSL) system. Since the VSL system controls the speed limit according to the traffic conditions, it can improve the safety and efficiency of a transport network. Many researchers have studied the real-time VSL (RVSL) algorithm based on real-time traffic information from multiple stations recording traffic data. However, this method can suffer from inaccurate selection of the VSL start station (VSS), incorrect VSL calculations, and is unable to quickly react to the changing traffic conditions. Unstable VSL systems result in more congestion on freeways. In this study, an enhanced VSL algorithm (EVSL) is proposed to address the limitations of the existing RVSL algorithm. This selects preliminary VSL start stations (pVSS), which is expected to end congestion using acceleration and allocates final VSSs for each congestion interval using selected pVSS. This controls the vehicles that entered the congestion area based on the selected VSS. We used four metrics to evaluate the performance of the proposed VSL (VSS stability assessment, speed control stability assessment, travel time, and shockwave), which were all enhanced when compared to the standard RVSL algorithm. In addition, the EVSL algorithm showed stable VSL performance, which is critical for road safety.

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Centralized and Decentralized Optimal Control of Variable Speed Heat Pumps

Energies ◽

10.3390/en14134012 ◽

2021 ◽

Vol 14 (13) ◽

pp. 4012

Author(s):

Ryan S. Montrose ◽

John F. Gardner ◽

Aykut C. Satici

Keyword(s):

Optimal Control ◽

Demand Response ◽

Power Distribution ◽

Energy Savings ◽

Service Providers ◽

Heat Pumps ◽

Variable Speed ◽

Peer Communication ◽

Naturally Occurring ◽

Thermostatically Controlled Loads

Utility service providers are often challenged with the synchronization of thermostatically controlled loads. Load synchronization, as a result of naturally occurring and demand-response events, has the potential to damage power distribution equipment. Because thermostatically controlled loads constitute most of the power consumed by the grid at any given time, the proper control of such devices can lead to significant energy savings and improved grid stability. The contribution of this paper is the development of an optimal control algorithm for commonly used variable speed heat pumps. By means of selective peer-to-peer communication, our control architecture allows for the regulation of home temperatures while simultaneously minimizing aggregate power consumption, and aggregate load volatility. An optimal centralized controller is also explored and compared against its decentralized counterpart.

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