Demand Side Management and Battery Storage Utilization to Increase PV Self-consumption of a Modulating Heat Pump

The combination of photovoltaic (PV) systems and heat pumps for heating and cooling of buildings is a promising solution to increase the share of renewable energy in the residential sector. The interaction between the system components is fundamental to assure a high performance of the system. The level of PV energy self-consumption is strictly dependent on the control strategy applied to the system. The solar source is intermittent and it does not always match the building loads for heating and cooling. Furthermore, even the heating and cooling demands are strongly time-dependent in high performance buildings. For these reasons, an efficient control system is essential to ensure the high performance. Several papers in the literature have proposed advanced control techniques based on the model predictive control (MPC). However, their implementation in residential buildings is often limited due to high device costs. This paper proposes a rule-based control strategy for a modulating air-source heat pump coupled with a PV plant, which provide space heating, space cooling and domestic hot water in a residential building. The proposed control strategy can be easily implemented in residential buildings by using low-cost board shields. The heat pump is modulated and optimized depending on the instantaneous PV production, to maximize the direct use of solar energy onsite. When an overproduction of PV energy occurs, the heat pump operates to store the solar energy as thermal energy, exploiting thermal storage tanks and the building thermal capacitance (aka virtual battery). The heat pump is controlled by varying its compressor rotational speed. The compressor is regulated to operate at the maximum capacity level compatible with the supplied PV power. The control strategy is evaluated in combination with a electric storage system. The efficacy of the control strategy is assessed by means of dynamic energy simulations. The simulations are run for the whole year. A parametric analysis is carried out by considering different PV and battery size, to understand the impact of the system component size on the results

Investigation of vapor injection heat pump system with a flash tank utilizing R410A and low-GWP refrigerant R32

Vapor injection technique has proven to be effective in improving heat pump system performance, especially for cooling application at high ambient and heating application at low ambient temperature conditions. Recent research on vapor injection technique has been mostly focused on the internal heat exchanger cycle and flash tank cycle. The flash tank cycle typically shows better performance than the internal heat exchanger cycle. However, the flash tank cycle control strategy is not yet clearly defined. Improper system control strategy would result in undesirable amount of liquid refrigerant injected to the compressor or poor system performance. In this research work, a novel cycle control strategy for a residential R-410A vapor injection flash tank heat pump system was developed and experimentally investigated. The proposed cycle control strategy utilizes an electronic expansion valve (EEV) coupled with a proportional-integral-derivative (PID) controller for the upper-stage expansion and a thermostatic expansion valve (TXV) for the lower-stage expansion, and applies a small electric heater in the vapor injection line to introduce superheat to the injected vapor thus providing a control signal to the upper-stage EEV. The proposed control strategy functions effectively for both transient and steady-state operating conditions. As global warming has raised more critical concerns in recent years, refrigerants with high global warming potentials (GWP) are facing the challenges of being phased out. R410A, with a GWP of 2,088, has been widely used in residential air-conditioners and heat pump systems. A potential substitute for R410A is R32, which has a GWP of 675. This research work also investigates the performance difference using R410A and R32 in a vapor-injected heat pump system. A drop-in test was performed using R32 in a heat pump system that is designed to utilize R410A, for both cooling and heating conditions. Through experimentation, it was found that there was improvement for capacity and coefficient of performance (COP) using R32, as compared to an identical cycle using R410A. The compressor, heat exchangers and two-stage vapor injection cycle have been modeled and validated against experimental data to facilitate an optimization study. Heat exchangers were optimized using 5 mm copper tubes and result in significant cost reduction while maintaining the same capacity. Compressor cooling was investigated to decrease the high compressor discharge temperature for R32

Energy efficient renovation of heritage residential buildings using modelica simulations

Historic homesteads can be found on a large scale in Europe and particularly in Flanders. In Flanders there are hundreds of homesteads in desperate need of renovation. Within the framework of the Europe 2020 objectives both CO2 emission and energy use need to be reduced with 20% by 2020. Unlike for the average residential building renovation, focus lies on synergy between respect to heritage and achieving an optimal energetic effectiveness. The object of this research is a case study homestead in Bruges, named the Schipjes. The first step in energy efficient renovation is to lower energy use by optimizing the building physics, therefore dynamic simulations in Modelica are performed to evaluate primary energy demand, especially for heating, and thermal comfort. The second step is the choice of the most energy efficient technical installations for a district heating system as will be used for Schipjes. Five different scenarios or combinations of heat production and distribution systems are developed as input options for future research simulations and energetic equations in Modelica

Sub-hourly simulation of residential ground coupled heat pump systems

Residential Ground Coupled Heat Pump systems are usually characterised by an ON/OFF behaviour of the heat pump with typical cycling frequencies of 1 - 4 cycles per hour. The ground loop fluid pump has the same ON/OFF behaviour and the borehole heat exchanger operates either in full flow or no flow conditions. Typical hourly simulations of GCHP systems use steady-state models for the heat pump and the borehole fluid (transient models being used for buildings and heat transfer in the ground). This paper reviews the models used in typical hourly simulations as well as transient models that are available and compares the results obtained using the two classes of models within the TRNSYS simulation environment. Both the long-term energy performance and the optimum system design are compared. It is shown that using steady-state models leads to an overestimation of the energy use that ranges from a few percents with oversized borehole heat exchangers to 75% for undersized exchangers. A simple Life Cycle Cost analysis shows that using steady-state models can lead to selecting a very different design than the one that would have been selected using dynamic models

Control of heat pumps with CO2 emission intensity forecasts

An optimized heat pump control for building heating was developed for minimizing CO2 emissions from related electrical power generation. The control is using weather and CO2 emission forecasts as input to a Model Predictive Control (MPC) - a multivariate control algorithm using a dynamic process model, constraints and a cost function to be minimized. In a simulation study the control was applied using weather and power grid conditions during a full year period in 2017-2018 for the power bidding zone DK2 (East, Denmark). Two scenarios were studied; one with a family house and one with an office building. The buildings were dimensioned on the basis of standards and building codes. The main results are measured as the CO2 emission savings relative to a classical thermostatic control. Note that this only measures the gain achieved using the MPC control, i.e. the energy flexibility, not the absolute savings. The results show that around 16% savings could have been achieved during the period in well insulated new buildings with floor heating. Further, a sensitivity analysis was carried out to evaluate the effect of various building properties, e.g. level of insulation and thermal capacity. Danish building codes from 1977 and forward was used as benchmarks for insulation levels. It was shown that both insulation and thermal mass influence the achievable flexibility savings, especially for floor heating. Buildings that comply with codes later than 1979 could provide flexibility emission savings of around 10%, while buildings that comply with earlier codes provided savings in the range of 0-5% depending on the heating system and thermal mass.Comment: 16 pages, 12 figures. Submitted to Energie

COP improvement of refrigerator/freezers, air-conditioners, and heat pumps using nonazeotropic refrigerant mixtures

With the February, 1992 announcement by President Bush to move the deadline for outlawing CFC (chloro-fluoro-carbon) refrigerants from the year 2000 to the year 1996, the refrigeration and air-conditioning industries have been accelerating their efforts to find alternative refrigerants. Many of the alternative refrigerants being evaluated require synthetic lubricants, are less efficient, and have toxicity problems. One option to developing new, alternative refrigerants is to combine existing non-CFC refrigerants to form a nonazeotropic mixture, with the concentration optimized for the given application so that system COP (Coefficient Of Performance) may be maintained or even improved. This paper will discuss the dilemma that industry is facing regarding CFC phase-out and the problems associated with CFC alternatives presently under development. A definition of nonazeotropic mixtures will be provided, and the characteristics and COP benefits of nonazeotropic refrigerant mixtures will be explained using thermodynamic principles. Limitations and disadvantages of nonazeotropic mixtures will be discussed, and example systems using such mixtures will be reviewed

Research on the performance of radiative cooling and solar heating coupling module to direct control indoor temperature

The energy crisis and environmental pollution pose great challenges to human development. Traditional vapor-compression cooling consumes abundant energy and leads to a series of environmental problems. Radiative cooling without energy consumption and environmental pollution holds great promise as the next generation cooling technology, applied in buildings mostly in indirect way. In this work, a temperature-regulating module was introduced for direct summer cooling and winter heating. Firstly, the summer experiments were conduct to investigate the radiative cooling performance of the module. And the results indicated that the maximum indoor temperature reached only 27.5 °C with the ambient temperature of 34 °C in low latitude areas and the air conditioning system was on for only about a quarter of the day. Subsequently, the winter experiments were performed to explore the performance of the module in cooling and heating modes. The results indicated that indoor temperature can reach 25 °C in the daytime without additional heat supply and about a quarter of the day didn't require heating in winter. Additionally, the transient model of the module and the building revealed that the electricity saving of 42.4% (963.5 kWh) can be achieved in cooling season with the module, and that was 63.7% (1449.1 kWh) when coupling with energy storage system. Lastly, further discussion about the challenges and feasible solutions for radiative cooling to directly combine with the buildings were provided to advance the application of radiative cooling. Furthermore, with an acceptable payback period of 8 years, the maximum acceptable incremental cost reached 26.2 $/m2. The work opens up a new avenue for the application mode of the daytime radiative cooling technology