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1. Introduction

Rapid growth in world energy use has caused concerns about supply difficulties, energy depletion, and serious environmental impacts. For instance, climate change and ozone layer depletion have been key issues with which people have had to deal [1]. According to the reviewed literature, building energy consumption, including its operation and maintenance, currently accounts for 40% of the total global energy demand [2,3]. Moreover, heating, ventilation, and air conditioning systems (HVACs) consume 40–60% of a building’s energy consumption, with the precise value varying by climate [1]. Meanwhile, this energy consumption causes a large amount of greenhouse gas emissions, such as the emission of carbon dioxide (CO2). It is predicted that continued increases in carbon dioxide emissions will lead to major climate change [4]. Therefore, governments are making efforts to develop energy-saving and eco-friendly building technologies [5].

A great many energy-saving processes and techniques have been proposed for residential building applications, including recovering the waste energy of buildings, which is also referred to as a heat recovery system. In the context of the global energy crisis, on the one hand, the improvement of indoor air quality is required. On the other hand, there is an urgent need to promote energy-saving emission reductions in the field of HVAC. The application of air-to-air heat recovery would solve the contradiction between abundant fresh air supply and the reduction of energy consumption. According to Cuce et al., heat recovery systems are regarded as a greatly promising technology because of their ability to provide significant energy savings for residential buildings [6].

The purpose of this review is partly to summarize the current development of heat recovery systems for residential building applications, including their normal types, characteristics, and technical energy-saving possibilities, and partly to discuss the application of heat recovery in energy-efficient systems of buildings, including heat recovery combined with passive systems, mechanical ventilation systems, dehumidification systems, and thermoelectric module (TE) systems of buildings. Finally, a summary and outlook of these systems will be presented. 2. The Definition of Heat Recovery Systems Heat recovery is often referred to as a device operating between two air sources at different temperatures which transfers energy from one side to the other. In other words, it is based on preheating the incoming air to the interior through recycled waste heat. In general, heat recovery systems could be classified into sensible heat recovery and enthalpy heat recovery. Because of its ability to recover both the sensible heat and the latent heat, enthalpy heat exchangers have a better sustainability effect because of the large proportion of the wet load in the ventilation system and the requirements of the indoor air humidity for modern buildings.

A representative heat exchanger system in residential buildings is usually composed of a heat exchanger core, a fresh air inlet and separate contaminated air exhaust outlet, and a fan, as shown in Figure 1 [7]. At present, heat recovery systems can recover about 60–95% of waste energy, which is very promising [6]. This review focuses on four categories of heat recovery for sustainable residential building systems, including rotary wheel, fixed-plate, heat pipe, and run-around systems, which will be discussed in later sections.

3. Types of Heat Recovery Systems for Residential Building Applications According to the classification of different constructions, heat recovery systems can be divided into four types: rotary wheel, fixed-plate, heat pipe, and run-around. 3.1. Rotary Wheel

The rotary wheel heat recovery system is a motor-driven rotating porous wheel. When heat and moisture exchange happen, the two streams alternately pass through the wheel, as shown in Figure 2. The speed of rotors is usually low, ranging from 3 rpm to 15 rpm [7].

The overall efficiency of rotary wheel heat recovery is generally much higher than that of any other air-side heat recovery system due to the nature of the heat wheels, which allow heat to transfer from the exhaust stream to the supply stream without having to pass directly through the exchange medium. Normally, rotary wheel heat recovery is able to obtain a heat exchange efficiency of above 80% [7]. It is stated in [8] that the rotary wheel system has been proven to be one of the most efficient solutions for handling the moisture carried by the ventilation air. However, the rotary wheel heat recovery barely recovers 40% of the available enthalpy. Atmospheric conditions [9], the air mixing rate [10], rotation speed [11], and wheel materials [12] could be the major contributing factors in terms of the performance of rotary wheel heat recovery have a significant influence.

Many researchers have been working on achieving high performance of rotary wheel heat recovery. The optimal values of length and porosity can be obtained through the numerical model from Dallaire et al. [13]. The schematic representation of the optimal rotary wheel is shown in Figure 3 [13].

Besides their high heat transfer efficiency, rotary wheels can also recover both sensible and latent heat, which makes them able to be desiccant wheels for dehumidification and enthalpy recovery [14,15].

With regard to economic factors, a recent study in Chicago showed that the application of a rotary wheel heat exchanger enjoys a much shorter payback period in new buildings (less than one year) than in retrofitted existing building (two to four years) [16]. Another work from Chicago found that normally, total life cycle costs are 25–50% lower with the application of a rotary wheel than without it [17].

All the aforementioned studies show the advantages of the rotary wheel heat exchanger, these advantages being its rather high heat exchanger effectiveness and relatively short payback period [16]. However, the development of rotary wheel heat recovery is limited by the problems of air short circuiting and cross contamination [18]. Air short circuits can circulate air in unintended directions, greatly reducing the efficiency of the system.

3.2. Fixed-Plate

Fixed-plate heat exchangers use thin plates stacked together to create flow channels, which are illustrated below in Figure 4 [7]. The first plate type heat exchanger was invented by Dr Richard Seligman in 1923 and was used for indirect heating/cooling fluid [19]. There are three types of airflow arrangement, including counter flow, cross flow, and parallel flow. When the plates are made of a material with thermal conductivity and moisture permeability, they constitute an enthalpy heat exchanger. Mardiana-Idayu et al. introduced an experiment to investigate a novel enthalpy recovery system with a micro heat and mass cell cycle core, as shown as Figure 5. The results showed that the sensible energy efficiency was close to 66%, whereas for latent energy it was 59% [20]. Similarly, Nasif et al. conducted a fixed-plate heat recovery system by using a porous membrane material, shown as Figure 6. The thermal effectiveness of the new system was found to be about 75% of the sensible energy efficiency and 65% for the latent equivalent [21].

When plates (including metal plates and plastic plates, etc.) cannot absorb moisture, the material thermal conductivity and geometry is paramount for recovery of sensible heat. Normally, sensible heat recovery can achieve a heat exchange rate between 50% and 80% [22]. The factors that could affect the heat transfer efficiency of fixed-plate type heat recovery include:

  • Plate types and constructions (such as different arrangement and orientation) [23,24];

  • Heat exchanger materials [21,25];

  • Flow pattern [26].

Recently, some commercial products have achieved a better heat exchanger rate. One improved fixed-plate heat recovery system produced by a Danish company can achieve a heat recovery rate of 93%, as certificated by Passive House Institute, Darmstadt [27,28]. Therefore, fixed-plate type heat exchangers enjoy a promising future in higher thermal performance in residential building applications.

3.3. Heat Pipe

Heat recovery systems using heat pipes to transfer heat combine the principles of heat conduction and phase change to effectively transfer heat between two solid interfaces. The typical heat pipe consist of two closed tubes filled with working fluid [29]. The heat pipe transfers thermal energy from one side to the other side with a small temperature difference [30]. During operation, the condensed liquid travels to the evaporation section due to the wick structure exerting capillary action or the gravitational force [29].

Typical heat pipe exchangers can achieve thermal efficiency of around 50% [31]. Experiments from Shao et al. have proven that the efficiency of a heat pipe recovery system in a naturally ventilated house can achieve 50% with pressure loss less than 1 Pa [32]. The effectiveness will decrease with increasing air flow rate, and substandard thermal contact between plates and heat pipe occurs [33]. In terms of factors that could affect heat pipe effectiveness, there are some key points [34,35]: working fluid, the arrangement of the pipes, the air velocity and the inlet temperature of the evaporator part.

For the last decade, many researchers have focused on the application of heat pipe type recovery. El-Baky et al. have developed an experiment to test its thermal performance and to collect data for the effectiveness of heat pipe systems for heat recovery in air conditioning applications, shown as Figure 7. The results have shown that the heat transfer rate for both the evaporator and condenser sections has increased to around 48% [36].

From Yau et al. it can also be found that using heat pipe recovery systems can lead to significant energy savings in domestic appliances within tropical climates [37,38]. Recently, Diao et al. provided a new study involving a small flat heat pipe heat recovery device which applies a flat micro-heat pipe array with welded, serrated, and staggered fins on its surface, as shown in Figure 8. The results showed that the maximum heat exchange rate and coefficient of performance (COP) could be 78% and 91.9, respectively, under experimental conditions [39]. This study of a small flat heat pipe heat recovery system indicates the potential for improving the thermal performance of heat pipe heat recovery. However, further real-life evaluation is still needed.

In summary, heat pipe heat recovery enjoys the following advantages: handy manufacturing and convenient maintenance, a lack of cross contamination, and greater thermal conductance [40].

3.4. Run-Around

Run-around heat recovery systems consist of two individual heat exchangers and a coupling liquid, as shown in Figure 9. With the help of the pump, it allows liquid to transfer absorbed heat from one stream into the other side [7].

Run-around heat recovery can avoid cross contamination because of the separation of the two heat exchangers [41]. The heat exchange rate of run-around heat recovery ranges from 45% to 65% under normal conditions [7]. Using a run-around heat recovery system in a building can increase the ventilation airflow rate without increasing energy consumption [42]. As to the thermal performance of run-around heat recovery, Vali et al.’s experimental results showed that for a given total surface area of exchangers, the highest overall sensible effectiveness was achieved with exchangers which have a small exchanger aspect ratio [41].

In addition, the effectiveness of run-around heat recovery is significantly dependent on outdoor conditions. Run-around heat recovery systems are often positioned within the supply and exhaust air streams of industrial processes.

Table 1 compares the basic performance of different types of heat recovery systems.

By sorting through 100 research papers published in the last five years about the study of the application of heat recovery systems in residential buildings, such a summary could be given as follows. Figure 10 shows the distribution of the main studies according to the four heat recovery system types. Nearly one third of researchers were interested in heat pipe heat recovery (HPHR). Around 40% of these newly published articles were related to fixed-plate heat recovery (FPHR). About 21% of researchers focused on rotary wheel heat recovery. However, just 3% considered run-around heat recovery. Normally, run-around heat recovery systems are more popular in the industrial field and are not as common in domestic building applications. The following sections discussing fixed-plate, rotary wheel, and heat pipe heat recovery combined with energy-efficient systems for building applications.

4. Applications of Heat Recovery in Energy-Saving Systems of Residential Buildings The combination of heat recovery and different energy-efficient systems could contribute to reducing heat loss, stabilizing heat flux, and improving the thermal performance of residential buildings. This section reviews the recent development in heat recovery combined with energy-efficient technologies of buildings over four subsections. 4.1. Heat-Recovery-Assisted Decentralized Ventilation System

Mechanical ventilation systems are applied for achieving the desired airflow and obtaining a comfortable interior environment. However, mechanical ventilation can consume much electrical energy, and, can at times increase household power consumption by up to 50% [43]. Tommerup et al. have reported that with heat recovery technology, up to 90% of ventilation heat loss (about 30–35 kWh/m2 per year) can be recovered depending on airtightness and the insulation of the building [2].

Compared with centralized ventilation, pressure loss can be minimized within decentralized ventilation, due to the shorter distance of the air routing [44]. Several researchers have tested the performance of heat recovery units with decentralized ventilation systems based on different outdoors conditions. Baldini et al. has conducted a decentralized cooling and dehumidification system, as shown in Figure 11. Multi-stage type heat recovery could help to reduce the temperature compared to a single heat exchanger. Experimental results showed that under an environment temperature of around 30 °C and a humidity ratio of 20 g/kg, the application of the multi-stage heat recovery could reach the preferred target, with the supply air at 14–15 °C and 8–9 g/kg. Additionally, because of the free reheating, the system is able to save about 4–5% of cooling energy demand [44].

Another novel rotary wheel unit in Europe has been described by Smith et al. (shown in Figure 12), which uses plastic as the heat transfer material and was installed in the exterior wall of an individual room vent, requiring minimal space. Testing results indicated that this novel unit could recover about 84% of sensible heat with a ventilation rate of 7.8 L/s [45]. In addition, bypass leakage was observed during the experiment and the pressure drop reached around 18% [45]. High-pressure leakage could cause discomfort noise due to the higher fan speed required to achieve the desired vent rate. Therefore, proper sealing and slowing of the rotational speed to prevent frost accumulation should be ensured [45].

Plate type heat exchangers can also be integrated within ventilation systems. Coydon et al. have evaluated different facades combined with heat recovery ventilation units seasonally, as shown in Figure 13. The results showed that integration, including counter flow heat recovery, achieved recovery ranging from 64.6% to 70.0% of heat [46]. Another unit which adopted regenerative heat recovery could recover between 72.8% and 80.2% of heat [46].

Recently, Cuce et al. proposed a novel polycarbonate heat recovery system. The experiment carried out measurements of temperature, relative humidity, and CO2 in a period of one week. The results indicated that through the application of the novel system within the testing house, a sensible increment, about 7 °C, was observed in the temperature of fresh air and a considerable decrease, about 4 °C, was achieved in the temperature of stale air [47]. They also showed that the average relative humidity in the testing room in the post-retrofit case was around 57%, which was within the desired range [47]. Figure 14 shows a temperature monitoring diagram during the testing period. The Cuce et al. experiments proved that by utilizing a combination of heat exchanger and ventilation, except for the mitigation of the heating or cooling load, the actual comfort conditions for indoor environments including CO2 concentrate and relative humidity reaching the desired range can also be achieved [47].

The following problems of integrated systems of heat recovery and decentralized ventilation can be found based on the aforementioned studies:

  • Unexpected air bypass leakage [45];

  • Noise from fans to achieve ventilation requirements [45];

  • Lack of ventilation unit operation and airflow control strategy [44,46].

4.2. Heat Recovery Combined with Passive Systems for Building Components

Recently, heat recovery systems have been considered to be combined with building components such as building walls [48,49,50,51], roofs [52] and wind towers [53,54,55,56]. For example, it has been found that wind towers can provide significantly higher airflow rates than open windows with the same area [57]. However, application of wind towers is generally limited to tropical climates because seasonal temperatures in colder climates are too low to circulate directly into interior spaces. Wind towers are usually closed to avoid loss of heating energy in winter [55]. To address this limitation, combining heat recovery technology with wind towers could be a sensible solution. This kind of integration would be helpful for stabilizing the heat flux of buildings to reduce total energy consumption demands and enhance indoor thermal comfort.

Table 2 summarizes the studies of different building components integrated into heat recovery.

According to aforementioned studies, the superiority of the combination system can be described as follows:

  • Can reach the desired airflow rate (8 L/s to 10 L/s per person) for wind tower combination system applications [54];

  • Can help to stabilize the heat flux of buildings to reduce the total energy consumption demands and enhance indoor thermal comfort [48,49,50,51];

  • Can heat the indoor air (which varies from 0.9 to 4.5 °C) through heat recovery, reducing energy loss [53,54,55,56].

However, except for the potential of energy savings, the limitations of the systems may also be summarized:

  • Insufficient data of real-scale investigations for heat pipes combined with walls. Latest research focuses on computational simulations or testing of single wall prototypes [48,49,51];

  • Lack of real-life testing. There is insufficient data to evaluate performance of durability, cost, and easy-operation. Further modelling using different climate zones needs to be investigated as well [53];

  • The side effects of air pollution on heat recovery systems and inlet air are ignored [55];

  • For heat pipe heat recovery, the optimization of heat pipe space and plans are also disregarded [53,54,55].

4.3. Heat Recovery in Dehumidification Systems

Heat recovery is an important component of a dehumidification system [12]. Kabeel has stated that higher pressure drops and uneven humidity distribution are caused by using densely packed beds [58]. Many studies have been carried out to investigate the performance of dehumidification with heat recovery systems. Table 3 lists the development on common types of heat recovery, including rotary wheel exchangers, fixed-plate exchangers, and desiccant-coated heat exchangers, combined with dehumidification systems.

According to the aforementioned studies, the following summary could be given:

  • Rotary desiccant wheels are always the better choice for adjusting the relative humidity of airflows [59]. These systems can achieve moisture removal rates of 1.7 g/kg~7 g/kg [60,61]. Rotary desiccant wheels find wide use in various climate conditions, mostly in humid and hot climates. However, more optimal models and verification are needed, including extensive cross-sectional area [62], airflow and rotation speed control [63], and lower pressure drop strategies [59];

  • For fixed-plate heat exchangers, enthalpy heat recovery can improve frost resistance compared to fixed-plate sensible heat recovery, as well as better sensible and latent effectiveness and smaller space due to its more compact design compared to common cross-flow heat recovery system [64]. Fixed-plate enthalpy heat recovery enjoys a bright future in residential building applications as it helps to avoid cross contamination and to improve air quality with the dehumidification system. To achieve better thermal performance of enthalpy heat exchangers and more wide-ranging applications for different climate conditions, increasing transfer units or changing the properties of membrane materials chemically might be considered;

  • Solid desiccant cooling technology is energy-saving and eco-friendly. Desiccant-coated heat recovery can transfer sensible and latent heat at the same time. It has been found that silica gel-coated heat recovery has better performance than polymer-coated heat recovery [65]. As the dehumidification and regeneration cycles greatly affect the dehumidification process, the best adjustable mode should be identified. However, it would be hard to repair or replace desiccant-coated heat recovery system, as this would bring about high costs to the system, making it unsuitable for small-scale residential building applications.

For all combination systems, strategies for controlling airflow and real-life investigation under different climate conditions are needed. 4.4. Heat Recovery with Thermoelectric Units

Since passive heat recovery systems take advantage of temperature differences between indoor and outdoor air streams, exhaust heat cannot be fully recovered. To tackle this disadvantage of conventional heat recovery, some researchers have proposed novel thermoelectric heat pump recovery systems [71,72,73,74]. Thermoelectric modules are solid state heat pumps that utilize the Peltier effect. During operation, DC current flows through the thermoelectric module, causing heat to be transferred from one side of the thermoelectric device to the other and creating a cold and hot side [75]. Temperature difference could be an approach to achieve heat recovery. Thermoelectric modules can also create electric energy when there is heat flux, which is called the thermoelectric generator (TEG) and works via the Seebeck effect [75]. Much focus has been placed on heat exchangers with thermoelectric generators for industrial and car waste heat recovery over decades, especially with the heat pipe type [76,77,78,79]. Currently, several studies about fixed-plate and heat pipe heat exchangers combined with thermoelectric modules for building ventilation application have appeared.

Table 4 lists current studies of heat recovery combined with thermoelectric units, including key features and economic evaluation.

From the current literature, some prospects and outlooks may be described:

  • Heat exchangers combined with TE modules have more potential to achieve better thermal performance under optimal condition simulations [71]. However, further study is needed to investigate their long-term operation in domestic building applications;

  • These novel systems benefit from their compact size, low electric energy consumption, environmental-friendly device structure, and rather low cost [71], which makes them a sensible choice with which to deal with heat loss during building ventilation;

  • Since TE modules create redundant heat during their operation, the application of energy storage materials might be considered to balance out cooling and heating needs [72].

5. Summary This review has presented a summary of heat recovery technologies for residential building applications, including the integration of heat recovery with some energy-saving systems. Some conclusions about and limitations of these current studies are the following:

  • The combination of heat recovery with passive systems of building components can obviously reduce heat losses and inlet air flow rate. The combination of heat pipe and rotary wheel heat recovery with wind towers would be more compact than normal fixed-plate heat recovery [40]. However, unexpected noise from the DC motor for rotary wheel heat recovery could be an issue. Further real-scale testing is needed for complex building wall systems to improve their heat flux stability. In addition to wind towers and roofs, chimneys and transom could also be chosen to be combined with heat recovery technology.

  • The effects of air pollution on decentralized ventilation with heat recovery systems lack further investigation. Future study is also needed to deal with bypass leakages during operation [44].

  • Regarding heat recovery-assisted dehumidification systems, desiccant material should have low sensible heat effectiveness [63]. Meanwhile, for membrane heat recovery, increasing transfer units could be considered as a means to process better heat transfer.

  • Heat recovery combined with TE modules should be developed due to its compact size, low electric energy consumption, environmental-friendly devices, and rather low cost. Further study is needed to investigate its long-term operation in domestic building applications.

  • Heat pipe heat recovery systems enjoy more potential to be combined with other sustainable technologies such as thermoelectric modules and solar energy systems due to its advantages, including handy manufacturing and convenient maintenance, a lack of cross contamination, and greater thermal conductance [39,73].

  • As seen in the current literature, many studies focus on mathematical model-based economic analysis for heat recovery systems [71]. Further investigations into real-life evaluations with economic analysis should be developed [56].

Figure 1. Typical heat recovery system for a residential building application [7].

Figure 2. Diagram of rotary wheel heat exchanger working mode [7].

Figure 3. A schematic representation of the optimal rotary wheel [13] (redrawn by the authors).

Figure 4. A fixed-plate heat exchanger [7].

Figure 5. Graph results for an air-to-air enthalpy heat exchanger [20].

Figure 6. Z-flow fixed-plate heat exchanger (HE) built using porous membrane material [21].

Figure 7. Heat pipe heat exchanger in an air conditioning system and graphs of effects under different conditions on effectiveness [36].

Figure 8. Schematic representation of a micro-heat pipe recovery system [39].

Figure 9. The working principles of run-around heat recovery [7].

Figure 10. Heat recovery system research article distribution.

Figure 11. Arrangement of the three heat exchangers [44].

Figure 12. Schematic representation of the plastic rotary wheel system [45].

Figure 13. Facade system with (a) counter flow heat recovery and (b) regenerative heat recovery [46].

Figure 14. Temperature monitoring during testing [47].

Types of Heat Recovery Rotary Wheel Fixed-Plate Heat Pipe Run-Around
Main airflow arrangementsCounter flow, parallel flowCross flow, counter flow, parallel flowCounter flow, parallel flowN/A
Typical efficiencyAbove 80%50~80%45~55%45~65%
Air speed (m/s)2.5~50.5~52~41.5~3
Air pressure (Pa)100~17025~370100~500100~500
Temperature range (°C)−60~800−60~800−40~35−45~500
Advantages [7]High efficiency, compact equipment, potential to recover sensible and latent heat.Compact, relatively high heat transfer coefficient, no cross contamination, easy maintenance, can be coupled with counter-current flow which enables the production of closed-temperature differences, capable of recovering sensible and latent heat.Fixed components, no extra power supply, high reliability, separate air duct, compact, suitable for naturally ventilated building, fully reversible, easy maintenance but only capable of recovering sensible heat.Air ducts can be located side by side, ducts can be physically separated, no cross contamination, only capable of recovering sensible heat.

Building Component Images Research Methodology Key Features Outcomes Economic Analysis Reference
Building wall Experimental investigation with 1720 mm × 1720 mm wall implanted with heat pipes (WIHP) and theoretical analysisA new type of passive solar utilization technology; WIHP; different direction facing wall according to the located regions.Application of the integration could reduce heat loss by more than 14.47% in winter.NA[48,49]
MATLAB based simulationMultilayer wall with capillary pipe network; significantly reduces building load; three locations for heat pipes including external, middle, and internal.The wall could help save power energy from 2 W to 39 W with variation in outdoor air temperature depending on the season.NA[50]
TRNSYS software simulationA pipe-embedded wall integrated with ground source-coupled heat exchanger; multi-criteria system design.Using the same number of ground source-coupled heat exchangers (GDHE) the system could achieve over 30% energy savings in hot summer and cold winter climates.NA[51]
Roof Experimental investigation with a real-scale test houseA plate-type heat exchanger parallel-flow arrangement under roof application; recovers waste heat; preheats fresh air using stale air.Heat recovery efficiency was found to be around 89%. The coefficient of its thermal performance is 4.5.Relatively low cost of polycarbonate sheet-based roof type heat recovery panel, about €14.31/m2.[52]
Wind tower CFD software simulationA cooling wind tower incorporating heat pipe technology and cool sink; passive cooling system.System can cool down air flow up to 12 °C, and at lower weed speeds (1–2 m/s), it can reduce the temperature significantly.NA[53,54]
CFD software simulation and experimental investigation (1:10 scale experimental platform)Heat pipes integrated into a multi-directional wind tower; recovers exhaust heat.The application of the system can heat the supply air by up to 4.5 °C. In addition, the heat pipes can slow down the air supply rates by up to 8–17%.NA[55]
(Redrawn by authors)Experimental investigation using a large-scale chamber (3 m × 3 m × 5.6 m) with a wind catcher unit (0.7 m× 3.2 m × 0.45 m)Integrated system with heat recovery and wind catcher; helps to assist air flow.The combination system can cool down the inlet air temperature up to 0.9–1.8 °C. The heat exchange rate of the unit varies from 50% to 70% with different air flow velocities, which range from 1.2 to 3.1 m/s.NA[56]

NA: Not available.

Type Images Key Features Research Methodology Results Climate Conditions Reference
Rotary desiccant wheel Rotary wheel with polymer composite desiccant, sandwiched between the condenser and evaporator section of a heat pump with air channelsLaboratory experimentMoisture removal capacity can achieve 7 g/kg. The desiccant wheel-heat pump system can decrease relative humidity from 59% to 45% and cool down the air from 32 °C to 29 °C during testing.Humid subtropical climate[60]
Rotary desiccant wheel with passive ventilation, coated in silica gel particlesLaboratory experiment and CFD simulationThe model can achieve 55% of airflow dehumidification with lower regeneration air temperature and a lower pressure drop.Temperate marine climate[59]
(Redrawn by authors)Periodic total rotary heat recovery with polymer/alumina composite desiccantLaboratory experimentSilica gel and active alumina desiccant material can achieve high moisture removal, 2.1 g/kg and 1.7 g/kg, at regenerating temperatures of 40 °C and 25 °C, respectively.Humid subtropical climate[66]
Heat pump-driven two-stage desiccant wheel systemMathematical model and laboratory experimentThe COP was calculated as 5.5 under summer conditions with a supply air humidity ratio of 10 g/kg. Humid continental climate[63]
Internally cooled 64% desiccant-coated wheel with heat exchangerLaboratory experimentThe overall cooling capacity can increase by 64% and the EER by 21% with this model compared to those using an adiabatic desiccant wheel.Humid subtropical climate[62]
Desiccant wheel using humidity swing adsorption (HSA)Theoretical study and laboratory experimentThe unit can achieve a temperature rise of up to 9.4 °C with an adsorption-to-regeneration air ratio of 1:2 and 8 rph rotary speed.Humid continental climate[61]
Fixed-plate Membrane heat exchanger using Kraft paper to transfer heat and moisture, assisting heating, ventilation, and air conditioning (HVAC) system.Laboratory experiment and HPRate software analysisThe unit can help save up to 8% of annual energy consumption in hot and humid climates.Humid subtropical climate[21]
Novel quasi-counter-flow membrane energy exchanger Theoretical calculation and laboratory experimentUnder cold conditions, the unit can obtain 88.5–94.5% sensible effectiveness and 73.7–83.5% latent effectiveness with supply air temperature ranging from −4 to 10 °C.Cold climate[64]
Heat exchanger with asymmetric composite membranesMathematical model (outdoor relative humidity range 45%−90%)For cooling, increasing outdoor relative humidity will cause decreased sensible heat transfer efficiency and increased latent heat transfer efficiency. For heating with outdoor relative humidity below 60%, a higher relative humidity (RH) rate will cause a slightly increased latent effectiveness while also producing a rather stable and sensible effectiveness.NA[67]
Desiccant-coated heat exchanger Desiccant-coated heat exchanger, desiccant cooling systemMathematical modelUnder simulated conditions, the lowest humidity ratio of supply air decreases from about 9.5 g/kg to 8 g/kg. The cooling capacity of the model increased by 30% compared with other desiccant-coated heat recovery systems without self-cooled recovery.Humid subtropical climate[68]
Fin-tube heat exchanger with silica gel coatingOutdoor experiment investigationThe average moisture removal rate is 5.3 g/kg and the average thermal COP was calculated as being 0.34.Humid subtropical climate[69]
Solid desiccant-coated heat exchangerOutdoor experiment investigationThe average moisture removal rate was 8 g/kg and the thermal COP was calculated as being 1.2.Humid subtropical climate[70]

NA: Not available.

Type Images Extent of Study Research Methodology/Software Outcomes Economic Analysis Suggestions Reference
Fixed-plate Theoretical analysisMathematical model including cost-performance modelBy controlling operating variables, including thermoelectric numbers, filling factors, length of P-N legs, couple numbers of thermoelectric cooler (TEC), and overall thermal conductance, separately, the COP of the system varies from 2.18 to 4.37.Under the optimal parametric conditions, the operating cost of the heat exchanger with thermoelectric module (HE-TE) system is lower than 0.02 $/kWh.Further study is needed to test the feasibility of cost-performance conditions when multiple TECs are applied.[71]
Experimental investigationEstablish an experimental platformThis novel system can achieve overall coefficients of cooling and heating of about 50.6% and 57.9%, respectively, under optimal operating current and voltage.NAPhase change material (PCM) could be considered as the thermal energy storage of the solar-driven exhaust air thermoelectric heat pump recovery (SDEATHP) system to balance the cooling or heating needs of fresh air handling.[72]
Experimental investigationLaboratory conditions and MATLAB mathematic modelThe finned heat sink with thermoelectric units has relatively poor output performance compared to the heat pipe with TE units.Heat exchanger cost is $15.12/(W/K). [73]
Heat pipe Theoretical analysis and experimental investigationTheoretical model using effectiveness-NTU (number of transfer unit) method and laboratory scale with two separate airducts (170 mm × 160 mm)With increasing air flow velocity, the heat recovery efficiency increased from 67.9% to 72.4%.N/A [74]
Experimental investigationLaboratory condition and mathematic modelThe heat pipe combined with the thermoelectric unit cooling method shows better output performance compared to that of the heat sink.Heat exchanger cost is $10.67/(W/K). [73]

NA: Not available. P: p-type semiconductor; N: n-type semiconductor.

Funding

This research was funded by Innovate UK (project code: 104019). And the APC was funded by WSSET (world society of sustainable energy technologies).

Conflicts of Interest

The authors declare no conflict of interest.

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Qi Xu*, Saffa Riffat and Shihao Zhang

Department of Architecture and Built Environment, Faculty of Engineering, The University of Nottingham, University Park, Nottingham NG7 2RD, UK

*Author to whom correspondence should be addressed.

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© 2019. This work is licensed under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

In recent years, interest in heat recovery systems for building applications has resurged due to concerns about the energy crisis and global climate changes. This review presents current developments in four kinds of heat recovery systems for residential building applications. A extensive investigation into the heat recovery integrated in energy-saving systems of residential buildings is also covered, including passive systems for building components, mechanical/natural ventilation systems, dehumidification systems, and the thermoelectric module (TE) system. Based on this review, key issues have been identified as follows: (1) The combination of heat recovery and energy-efficient systems could be considered as a promising approach to reduce greenhouse gas emissions and make residential buildings meet high performance and comfort requirements. However, real-life evaluation of these systems with economic analysis is insufficient; (2) When heat recovery is applied to mechanical ventilation systems, issues such as pressure leakages and air shortcuts should be addressed; (3) The heat pipe heat recovery system enjoys more potential in being combined with other sustainable technologies such as thermoelectric modules and solar energy systems due to its advantages, which include handy manufacturing and convenient maintenance, a lack of cross contamination, and greater thermal conductance.

Details

Title
Review of Heat Recovery Technologies for Building Applications
Author
Xu, Qi; Riffat, Saffa; Zhang, Shihao
First page
1285
Publication year
2019
Publication date
2019
Publisher
MDPI AG
e-ISSN
19961073
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.3390/en12071285
ProQuest document ID
2316760639
Copyright
© 2019. This work is licensed under http://creativecommons.org/licenses/by/3.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.