Nonconvex model predictive control for commercial refrigeration

Hovgaard, Tobias Gybel; Boyd, Stephen; Larsen, Lars Finn Sloth; Jørgensen, John Bagterp

doi:10.1080/00207179.2012.742207

Cited by 49 publications

(42 citation statements)

References 55 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A thermal load has zero cost function. More sophisticated models [27] include temperature-dependent cooling and heating efficiencies for heat pumps, more complex dynamics of the system whose temperature is being controlled, and additional additive terms in the thermal dynamics, to represent occupancy or other heat sources.…”

Section: Thermal Loadmentioning

confidence: 99%

Dynamic Network Energy Management via Proximal Message Passing

Kraning

2014

FNT in Optimization

209

228

View full text Add to dashboard Cite

Section: Thermal Loadmentioning

confidence: 99%

Dynamic Network Energy Management via Proximal Message Passing

Kraning

2014

FNT in Optimization

209

228

View full text Add to dashboard Cite

“…Expenditure on power can be reduced by utilizing varying electricity prices, and by participation in a Smart Grid, the system can be rewarded for its flexibility while delivering crucial services to a power grid with increasing amounts of fluctuating renewable energy sources. This is further discussed in [2], [3], [5]. As shown in our previous work load shifting strategies can be beneficial on different time scales.…”

mentioning

confidence: 99%

Analyzing control challenges for thermal energy storage in foodstuffs

Hovgaard

Larsen

Skovrup

et al. 2012

2012 IEEE International Conference on Control Applications

Self Cite

View full text Add to dashboard Cite

Abstract-We consider two important challenges that arise when thermal energy is to be stored in foodstuffs. We have previously introduced economic optimizing MPC schemes that both reduce operating costs and offer flexible power consumption in a future Smart Grid. The goal is to utilize the thermal capacity of refrigerated goods in a supermarket to shift the load of the system in time without deteriorating the quality of the foodstuffs. The analyses in this paper go before closing any control loops. In the first part, we introduce and validate a new model with which we can estimate the actual temperatures of refrigerated goods from available air temperature measurements. This is based on data obtained from a dedicated experiment. Since limits are specified for food temperatures, the estimate is essential for full exploitation of the thermal potential. Secondly, the thermal properties, shapes and sizes of different foodstuffs make them behave differently when exposed to changes in air temperature. We present a novel analysis based on Biot and Fourier numbers for the different foodstuffs. This provides a valuable tool for determining how different items can be utilized in load-shifting schemes on different timescales and for estimating maximum energy storage time. The results are shown for a large range of parameters, and with specific calculations for selected foodstuff items.

show abstract

“…We show that our MPC controller exhibits a sophisticated form of demand response to prices, reducing consumption when the prices are high and pre-cooling when prices are low. Further details and results are provided in Hovgaard et al (2012b).…”

Section: Introductionmentioning

confidence: 99%

Fast Nonconvex Model Predictive Control for Commercial Refrigeration

Hovgard

Larsen

Jørgensen

et al. 2012

IFAC Proceedings Volumes

Self Cite

View full text Add to dashboard Cite

Abstract:We consider the control of a commercial multi-zone refrigeration system, consisting of several cooling units that share a common compressor. The goal is to minimize the total energy cost, using real-time electricity prices, while obeying temperature constraints on the zones. We propose a variation on model predictive control to achieve this goal. When the right variables are used, the dynamics of the system are linear, and the constraints are convex. The cost function, however, is nonconvex. To handle this nonconvexity we propose a sequential convex optimization method, which typically converges in fewer than 5 or so iterations. We employ a fast convex quadratic programming solver to carry out the iterations, which is more than fast enough to run in real-time. We demonstrate our method on a realistic model, with a full year simulation, using real historical data. These simulations show substantial cost savings, and reveal how the method exhibits sophisticated response to real-time variations in electricity prices. This demand response is critical to help balance real-time uncertainties associated with large penetration of intermittent renewable energy sources in a future smart grid.

show abstract

Nonconvex model predictive control for commercial refrigeration

Cited by 49 publications

References 55 publications

Dynamic Network Energy Management via Proximal Message Passing

Dynamic Network Energy Management via Proximal Message Passing

Analyzing control challenges for thermal energy storage in foodstuffs

Fast Nonconvex Model Predictive Control for Commercial Refrigeration

Contact Info

Product

Resources

About