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Review

Adsorption Air-Conditioning for Automotive Applications: A Critical Review

by
Salvatore Vasta
Italian National Research Council, Institute for Advanced Energy Technologies “Nicola Giordano” (CNR-ITAE), 98126 Messina, Italy
Energies 2023, 16(14), 5382; https://doi.org/10.3390/en16145382
Submission received: 14 June 2023 / Revised: 8 July 2023 / Accepted: 12 July 2023 / Published: 14 July 2023
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Abstract

:
The automotive industry seeks innovative solutions for energy-efficient and sustainable vehicles. Conventional air-conditioning systems consume significant energy and have environmental impacts. Adsorption technology offers a promising alternative with higher energy efficiency and reduced emissions. This review analyzes recent advancements in adsorption air-conditioning for automotive applications, including material selection and system integration. It discusses the benefits, challenges, environmental impact, and waste heat recovery potential of adsorption systems. This review explores emerging trends like hybridization with vapour-compression (VC) systems to optimize energy efficiency and sustainability. By evaluating the existing literature, this review provides insights into thermally driven technologies for automotive air-conditioning.

1. Introduction

The automotive industry has experienced remarkable advancements in recent years, with an increased emphasis on improving vehicle efficiency and reducing environmental impact. One critical aspect that significantly influences both driver comfort and energy consumption is the air-conditioning (AC) system. Traditional vapour-compression-based AC systems have been the primary choice for automotive applications for decades. However, their reliance on mechanical compression and the use of environmentally harmful refrigerants have spurred the exploration of alternative technologies.
In recent years, thermally driven air-conditioning systems have gained considerable attention as a promising solution. These systems leverage waste heat or solar energy to drive the cooling process, presenting a viable and sustainable alternative to conventional AC systems. This review paper aims to provide a comprehensive overview of the advancements in air-conditioning systems for automotive applications, with a special focus on adsorption systems [1].
The primary objective of this review is to analyze the latest developments in adsorption AC technology. These systems utilize low-grade waste heat or renewable energy sources to drive the cooling cycle, reducing the dependency on mechanical compression and offering improved energy efficiency and environmental friendliness.
Throughout this paper, the fundamental working principles, key components, and operating characteristics of adsorption AC systems are discussed. Additionally, the study delves into recent research, technological innovations, and commercialization efforts in this field. Emphasis is placed on the potential benefits, challenges, and prospects in the automotive sector.
Moreover, this review explores the performance comparison between adsorption AC systems and conventional vapour-compression-based systems in terms of cooling capacity, energy efficiency, environmental impact, and overall system integration. Special attention is given to practical considerations, such as system size, weight, cost, and feasibility for mass production and integration into existing vehicle platforms.
By examining the current state-of-the-art for automotive applications, this review aims to provide researchers, engineers, and industry professionals with valuable insights into technological advancements and potential avenues for further research and development. The ultimate goal is to contribute to the ongoing efforts in improving vehicle sustainability, enhancing energy efficiency, and providing occupants with comfortable and environmentally friendly AC solutions.
Indeed, air-conditioning in cars plays a crucial role in ensuring passenger comfort and safety. It helps to maintain a comfortable temperature inside the vehicle, especially during hot and humid weather conditions. Effective air-conditioning promotes driver alertness and concentration, leading to safer driving experiences. It also aids in preventing heat-related illnesses and fatigue among occupants, contributing to their overall well-being. Furthermore, air-conditioning helps to improve the air quality by filtering out pollutants, allergens, and harmful particles, creating a healthier environment inside the car. In summary, air-conditioning in cars is not just a luxury, but a necessity, as it provides comfort, safety, and enhanced driving experiences for passengers.
Recently, Kwon et al. [2] offered an interesting overview of the issue. In their study, the authors emphasize the significance of thermal management in automobiles, particularly in the context of autonomous driving and electric vehicles. They identify the need for research that addresses changing mobility dynamics and propose basic research directions. The study highlights environmental factors such as vehicle diversification, personalized air-conditioning, and dynamic thermal management.
However, compression air-conditioning systems dominate automotive applications due to their efficiency and widespread availability. They offer reliable cooling performance, even in extreme temperatures, making them ideal for automotive applications. Additionally, compression air-conditioning systems are compatible with various types of vehicles, including hybrid and electric vehicles. Their dominance in the automotive industry is attributed to their proven effectiveness, durability, and the extensive infrastructure supporting their maintenance and repair. For such a reason, several studies on specific technological aspects of these systems are available in the literature. For example, in [3], the authors investigate the power consumption and energy efficiency issues of the scroll compressors of car air conditioners caused by friction and explore the use of coating technology to improve the performance of the scroll compressor.
The significant concerns regarding air-conditioning compressors in cars revolve around their consumption and environmental impact. These systems consume a considerable amount of energy, leading to increased fuel consumption and contributing to the emission of greenhouse gases. In [4], the authors study the transition to eco-friendly refrigerants by investigating the performance of three refrigerants, R152a, R1234yf, and R134a, in an oil-free vapour-compression refrigeration (VCR) system. As is well known, the R134a has been commonly used in automotive air-conditioning until 2022, when it was banned due to its high global warming potential. The R152a and R1234yf are low global warming potential alternatives. Experimental tests were conducted, and the R152a exhibited higher volumetric efficiency, adiabatic efficiency, cooling capacity, and COP than the R134a. Although the R152a’s flammability restricts its use in conventional automotive air conditioners, it is considered a more promising alternative for oil-free automotive air-conditioning due to its high efficiency, lower cost, and reasonable safety level in the absence of oil lubricants. Also, Meng et al. [5] studied alternative refrigerants for mobile air-conditioning. The authors evaluated the performance of a new refrigerant, the R1234yf/R134a mixture (89:11 ratio), as an alternative to the R134a in automotive air-conditioning systems. The results indicate similar cooling and heating capacities between the R1234yf/R134a and R134a. However, the COP of the R1234yf/R134a is slightly lower by 4–9% in cooling mode and by 4–16% in heating mode compared to the R134a. The R1234yf/R134a exhibits a significantly lower compressor discharge temperature than the R134a. By adding 11% R134a, the R1234yf/R134a becomes virtually non-flammable and meets environmental standards. The R1234yf/R134a is a viable replacement for the R134a in automotive air-conditioning systems with minor modifications, even though it has a lower performance.
However, novel technical solutions were also investigated. In [6], the author compared the performances of an automotive air-conditioning system equipped with a liquid–vapour separation micro-channel condenser and a common parallel-flow micro-channel condenser (PFMC). Under normal running conditions, the proposed system exhibited a 5.18% higher cooling capacity and a 3.73% higher EER (energy efficiency ratio) compared to the standard solution. Cola et al. [7] investigated the factors influencing the length of the stable operating plateau in integrated receivers used in automotive air-conditioning systems. They found that the receiver diameter and axial spacing between the inlet and outlet holes have the most significant impact on the receiver operation. These findings were used to develop a numerical model that accurately estimates the filling efficiency of the integrated receiver. The study highlights the importance of geometrical and thermodynamic conditions in optimizing the performance of the systems.
A considerable amount of effort is being dedicated to the study, testing, and implementation of energy-efficient systems and the transition towards eco-friendly refrigerants. Stricter regulations and incentives are driving the industry towards sustainability. The primary objective is to achieve efficient and environmentally responsible air-conditioning in automotive applications. In this context, adsorption systems possess a clear advantage over compression-based systems for automotive air-conditioning. By effectively utilizing waste heat from the internal combustion engine (ICE), these systems significantly reduce energy consumption and improve overall efficiency.
With environmentally friendly refrigerants and fewer moving parts, they offer a sustainable and efficient cooling solution for vehicles. This review paper presents a comprehensive exploration of air-conditioning systems for automotive applications, with a specific focus on the advancements and potential of adsorption systems. By examining the latest research, technologies, and prospects, this review seeks to foster innovation and contribute to the advancement of sustainable and efficient AC solutions in the automotive industry. Also, a special focus is given, during the analysis, to some key performance parameters including the coefficient of performance (COP), specific cooling power (SCP), capacity, and operating temperatures. However, at the current status, it is not possible to provide cost parameters yet. The technology is not at a commercial stage (at least for the sizes and capacities that can fit mobile applications), and data about the production cost are not available anywhere. The reader can obtain a general idea of the cost level by reading the recently published work by AL-Hasni and Santori [8]. The present review is structured as follows:
  • The impact of AC systems on fuel consumption and electric vehicle range. This section focuses on the impact of air-conditioning systems on fuel consumption and the range of electric vehicles. It examines the energy requirements of these systems and their implications for vehicle efficiency.
  • The classification of air-conditioning systems for automotive applications. A comprehensive classification of air-conditioning systems used in automotive applications is presented in this section. It provides an overview of the different types of systems and their key characteristics.
  • Vapour-compression (VC) systems. This section delves into the widely employed VC systems, discussing their working principles, innovative refrigerants, and efficiency. It highlights the advantages and drawbacks of this established technology.
  • Thermally driven automotive air-conditioning systems. This section explores thermally driven air-conditioning systems, which offer improved energy efficiency and a reduced environmental impact.
  • Adsorption air conditioners. This section focuses on adsorption air conditioners. It presents all of the most updated and recent research works dealing with all of the main aspects of such technology including materials, components, system integration, etc.
  • Limitations of adsorption air conditioners. While adsorption air conditioners show promise, this section addresses their limitations and challenges. Factors such as system complexity, regeneration requirements, and cost are discussed.
  • The issue of electric vehicles—other active air-conditioning technologies. Given the unique requirements of electric vehicles, this section explores other active air-conditioning technologies tailored specifically for electric vehicle applications. It highlights innovations and advancements in this area.

2. The Impact of AC Systems on Fuel Consumption and Electric Vehicle Range

Air-conditioning (AC) systems in vehicles, whether thermal or electric, have a significant impact on fuel consumption [9] and the electric vehicle (EV) range [10]. The operation of AC systems requires energy, which can be supplied by burning fuel in traditional combustion engines or drawing power from the vehicle’s battery pack in electric vehicles. In combustion engine vehicles, AC systems are typically driven by the engine’s mechanical power and rely on the engine’s cooling system. The compressor, condenser, and other components consume additional energy from the engine, resulting in increased fuel consumption. The Society of Automotive Engineers (SAE) has conducted studies to quantify the impact of AC systems on fuel consumption in different driving conditions [11]. According to the SAE J1634 test procedures, AC usage can increase fuel consumption by up to 20% in urban driving and around 5–10% on highways.
Some modern vehicles feature electrically driven AC systems that reduce the load on the engine and improve efficiency. These systems use electric motors to power the compressor instead of a belt connected to the engine. Electric AC systems can provide more precise control over the cooling process, reducing energy wastage. While the exact fuel consumption data for vehicles with electric AC systems are limited, studies suggest potential fuel savings of up to 2–3% compared to traditional mechanical AC systems [12].
In electric vehicles, the impact of AC systems on the driving range is more pronounced. AC systems draw power from the vehicle’s battery, consuming energy that could otherwise be used for propulsion [13]. Several factors influence the range reduction caused by AC usage, including the outside temperature, desired cabin temperature, AC system efficiency, and vehicle speed. Studies conducted by the National Renewable Energy Laboratory (NREL) have evaluated the impact of AC usage on the electric vehicle range [14]. According to the NREL’s analysis, AC usage can result in a range reduction of approximately 5–20% depending on the aforementioned factors. Higher range reductions are observed in extreme temperatures and aggressive AC settings.
For such reasons, automakers and researchers are continuously working on improving the efficiency of AC systems and developing strategies to mitigate the impact on fuel consumption and electric vehicle range. These efforts include the following:
  • Advancements in compressor design and refrigerant technology to reduce energy consumption [15,16,17,18].
  • Integration of waste heat recovery systems to utilize excess heat from the AC system and reduce the load on the engine [19].
  • Improved insulation and cabin temperature management techniques to minimize the need for extensive cooling or heating [20,21,22].
  • Smart control algorithms and predictive thermal management systems to optimize AC usage based on driving conditions and driver preferences [23,24,25].
It is worth mentioning a 2016 study that analyzed the progress in the air-conditioning sector with a special focus on electric vehicles. In [26], the authors provide an extensive review of the literature regarding the advances made in heat pump air-conditioning systems for electric vehicles through a double review; they started with a review of the alternatives to environmentally harmful refrigerants and then they went on to describe other innovative components such as inverter technology. A detailed analysis of the system structure of the heat pump air-conditioning system was also provided. As an outcome, the paper presents the recent developments in multiple-source heat pump systems, which can not only provide sufficient refrigerating capacity for the electric vehicle, but also higher climate control system efficiency.

3. Classification of Air-Conditioning Systems for Automotive Applications

Air-conditioning (AC) systems for automotive applications can be classified based on various factors, including the cooling technology used, the source of energy or power, and the system’s overall design and functionality. Figure 1 shows a classification of cooling systems that are suitable for automotive applications. However, this paper only deals with active air conditioners that are commonly employed in automotive applications with a focus on adsorption systems.

3.1. Vapour-Compression Systems

Vapour-compression-based AC systems have been the traditional choice for automotive applications. These systems utilize a mechanical compressor, condenser, evaporator, and expansion valve to cool the air. They rely on refrigerants such as hydrofluorocarbons (HFCs) or hydrochlorofluorocarbons (HCFCs) for heat transfer.

3.2. Thermally Driven Systems

Thermally driven AC systems utilize waste heat to drive the cooling process. They can be further categorized into the following:
  • Adsorption systems;
  • Absorption systems;
  • Thermochemical systems;
  • Ejector systems;
  • Rankine systems;
  • Steam jet coolers.

3.3. Electrically Driven Systems

Electrically driven AC systems rely on electrical power to directly produce a cooling effect via semiconductors or to operate a compression cooling cycle. In the latter case, these systems typically incorporate an electric compressor and refrigerant-based heat exchange components, similar to VC systems. Electrically driven AC systems are commonly found in electric and hybrid vehicles where high-voltage electrical systems are available.

3.4. Hybrid Systems

Hybrid AC systems combine different cooling technologies to optimize performance and efficiency. These systems often integrate a VC unit with thermally driven components to utilize waste heat, solar energy, or other renewable energy sources, while maintaining the benefits of mechanical compression when required.

3.5. Climate Control Systems

Climate control systems are a passive (concerning the classification of Figure 1) approach to provide more advanced functionalities, allowing for precise temperature control, air distribution, and individual passenger comfort settings. These systems often incorporate multiple sensors, actuators, and control algorithms to optimize cabin comfort while minimizing energy consumption.
It is important to note that advancements and ongoing research in the field of automotive air-conditioning continually introduce new technologies and variations. Therefore, this classification serves as a general framework to understand the different types of air-conditioning systems that are commonly used in automotive applications.

4. Vapour-Compression Systems

To provide a thorough understanding of adsorption units for mobile applications, it is imperative to first address the concept of vapour-compression (VC) air-conditioning, as it stands as the conventional and widely adopted technique in automotive air-conditioning technology. Furthermore, gaining a deep comprehension of such systems is fundamental before delving into emerging and less established technologies such as the adsorption unit.
VC systems have historically been the preferred choice for automotive air-conditioning, owing to their superior cooling capacity and efficiency. The following paragraphs present further elucidation on VC systems that are specifically designed for automotive applications. They consist of the following key components (see Figure 2): the compressor (1) is the heart of the system and is responsible for compressing the refrigerant vapour, increasing its pressure and temperature; the condenser (2) facilitates the transfer of heat from the refrigerant to the ambient air, resulting in the condensation of the refrigerant vapour into a liquid state; the evaporator (3) is located inside the vehicle cabin and allows for the refrigerant to absorb heat from the air, thereby cooling the cabin. As the refrigerant evaporates, it transforms from a liquid to a vapour state; the expansion valve (4) regulates the flow of the refrigerant from the high-pressure side to the low-pressure side, causing a drop in the pressure and temperature before entering the evaporator.
The history of automobile air-conditioning systems traces back to the early 1900s when the first units were developed. Packard, a luxury car manufacturer, introduced the first automobile air-conditioning system in 1930. This system utilized a network of tubes and a refrigerant-driven compressor to cool the passenger compartment. Over time, automakers continuously improved these systems, enhancing their efficiency and reliability. By the 1960s, air-conditioning became a standard feature in many cars, particularly in regions with hot summers. General Motors introduced the first modern air-conditioning system in 1953, incorporating a compressor, condenser, evaporator, and expansion valve. The system initially employed the refrigerant R-12, but later transitioned to the R-134a due to environmental considerations. [27].
In recent years, there has been a growing emphasis on improving the efficiency of automobile air-conditioning systems to address concerns about global warming and fuel costs. Manufacturers have developed systems that consume less energy and use environmentally friendly refrigerants. Today, air-conditioning has become a crucial feature, greatly enhancing the driving experience worldwide. Ongoing technological advancements continue to enhance the efficiency, reliability, and affordability of these systems, ensuring their continued presence in vehicles for the foreseeable future.
VC systems historically used hydrofluorocarbons (HFCs) or hydrochlorofluorocarbons (HCFCs) as refrigerants. However, due to their high global warming potential (GWP), there has been a transition towards more environmentally friendly refrigerants. Common refrigerants used in automotive AC systems today include hydrofluoroolefins (HFOs) such as R1234yf, which have significantly lower GWPs compared to their predecessors. Table 1 reports a comprehensive list of refrigerants that are widely used in automotive applications (1–5) as well as new refrigerants (6–9).
Energy Efficiency:
The enhancement of energy efficiency is a primary objective in the progression of automotive VC systems. Diligent efforts are directed towards optimizing system design, refining component efficiency, and diminishing power consumption. Variable displacement compressors, for instance, dynamically adjust their capacity in response to cooling requirements, thereby minimizing energy wastage during partial load conditions. Furthermore, advancements in heat exchanger designs and refrigerant flow control mechanisms contribute to elevated system performance.
Integration with Vehicle Controls:
Contemporary VC systems are seamlessly integrated into the vehicle’s control system, enabling intelligent operation and precise temperature regulation. Strategically positioned temperature sensors within the cabin provide feedback to the system, facilitating automatic adjustments of the compressor speed, air distribution, and fan operation to maintain desired cabin temperature levels. These integrated controls optimize comfort levels while concurrently minimizing energy consumption.
Environmental Considerations:
In recognition of environmental concerns, significant endeavours have been undertaken to phase out or minimize the utilization of high-GWP (global warming potential) refrigerants in VC systems. Regulations such as the European Union’s mobile air-conditioning (MAC) directive and the United States’ Significant New Alternatives Policy (SNAP) program have stimulated the adoption of low-GWP refrigerants. Automotive manufacturers and AC system suppliers are actively engaged in ensuring compliance with these regulations and promoting sustainable practices.
Future Trends:
Future advancements in VC systems are predominantly focused on augmenting the overall system efficiency, reducing the refrigerant charge, and advancing technologies for leak detection and mitigation. Additionally, ongoing research is being conducted into advanced heat exchanger designs, including microchannel and parallel-flow condensers and evaporators, which offer enhanced heat transfer efficiency and compactness. By continually enhancing VC systems for automotive use, manufacturers endeavour to improve passenger comfort, curtail energy consumption, and minimize environmental impact.

5. Thermally Driven Automotive Air-Conditioning Systems

A significant amount of energy is lost in the internal combustion engines of automobiles. Most vehicles have an efficiency of 20–25%, with the highest recorded thermal efficiency being around 44% for a heavy-duty diesel engine [37]. When accounting for drive, friction, and electronic parts, the total available heat loss is approximately 55–70% of the chemical energy of the fuel (see Figure 3). Recovering waste heat from the combustion process can improve energy utilization [38]. The immediate application of this waste heat recovery is in cabin climate control, which currently consumes a large amount of energy. Some heat-activated cooling processes that have been explored include thermoelectric systems, absorption cycles, and adsorption cycles. Different technologies have been developed for the recovery of exhaust gas waste heat, including organic Rankine cycles, turbocharger technology, etc. Waste heat from automobile engines can be recovered from the following two sources: waste heat from the engine coolant circuit and the thermal energy from the exhaust stream.
Maeda et al. [39] reported the advantages and disadvantages of recovering the heat from the exhaust or coolant. They are summarized in the table below (Table 2).
While there are several advantages to recovering heat, there are also some disadvantages to consider. Other than the ones listed in Table 2, the following have to be considered.
Advantages:
Energy Efficiency: Recovering waste heat from the coolant loop and exhaust gases provides an opportunity to utilize otherwise wasted energy. By using this heat to drive the air-conditioning system, the overall energy efficiency of the vehicle can be significantly improved. This results in reduced fuel consumption and lower greenhouse gas emissions, making it an environmentally friendly solution.
Reduced Load on the Engine: Conventional air-conditioning systems in vehicles are typically powered by the engine, which increases the load and decreases fuel efficiency. By recovering waste heat, the thermally driven air-conditioning system lightens the load on the engine, allowing it to operate more efficiently. This can lead to improved overall vehicle performance and fuel economy.
Lower Operating Costs: Since thermally driven air-conditioning systems utilize waste heat, they can potentially reduce the reliance on the vehicle’s electrical system. This can result in lower operating costs, as the system does not draw power from the engine or the battery. Additionally, it reduces the strain on the vehicle’s electrical system, potentially prolonging its lifespan.
Simplicity and Reliability: Thermally driven air-conditioning systems are generally simpler in design compared to conventional air-conditioning systems, as they do not require a compressor or refrigerant. This simplicity can lead to improved reliability, with fewer components that could potentially fail or require maintenance. It also simplifies the overall vehicle design and can result in weight reduction.
Disadvantages:
Limited Cooling Capacity: One of the main drawbacks of thermally driven air-conditioning systems is their limited cooling capacity. The waste heat recovered from the coolant loop may not be sufficient to provide cooling in extreme conditions or larger vehicles. This can lead to a reduced cooling performance, especially in hot climates, and may require additional cooling sources to supplement the system.
Heat Availability: The effectiveness of a thermally driven air-conditioning system relies heavily on the availability and consistency of waste heat. In situations where the engine is not running, such as during idling or short stops, there may be insufficient heat available to drive the system. This can result in reduced or no cooling capabilities during these periods, which can be inconvenient for occupants.
Integration Challenges: Retrofitting existing vehicles with thermally driven air-conditioning systems can be challenging due to the need for integration with the existing coolant loop and exhaust system. It may require modifications to the vehicle’s design and infrastructure, potentially increasing the cost and complexity of implementation. However, in newly designed vehicles, these challenges can be addressed more effectively.
Limited Applicability: Thermally driven air-conditioning systems are most effective in applications where waste heat is abundant and easily accessible, such as in long-haul trucks or heavy-duty vehicles. In smaller or more fuel-efficient vehicles, the amount of waste heat generated may be insufficient to provide significant cooling. Thus, the applicability of such systems may vary depending on the vehicle type and usage.
Recovering waste heat for driving thermally driven air-conditioning systems in automotive applications offers several advantages. However, there are limitations and challenges to be explored. Careful consideration of these advantages and disadvantages is necessary to determine the feasibility of recovering waste heat.

6. Adsorption Air Conditioners

As seen in the previous sections, adsorption air conditioners (AAC), being a thermally driven technology, have the potential to substitute VC ones, where adsorber beds take the place of compressors. The operating principle of AAC centres around the phenomenon of sorption, in which a permeable solid material (adsorbent) traps a fluid (adsorbate) on its surface. Zeolite–water, silica gel–water, and activated carbon–methanol [40] are some of the popular adsorption pairs employed in AAC [41]. These materials have the added advantage of being cost-effective, eco-friendly, non-toxic, and non-corrosive.
Adsorbents are materials that contain tiny pores that can be as small as nanometers, while the substance that accumulates on its surface is called the adsorbate.
Adsorption mechanisms are classified into physical and chemical types. Physical adsorption involves the use of intermolecular forces or van der Waals forces, whereas chemical adsorption involves covalent or ionic forces between the adsorbent and the molecules. Chemical adsorption produces more heat, as covalent or ionic bonding is typically stronger than van der Waals bonding. Physical adsorption is reversible, while chemical adsorption is permanent [42]. A refrigeration or air-conditioning adsorption cycle does not require mechanical energy, but instead, uses heat energy from a waste heat source, solar energy, or other heat sources, thus leading to negligible energy consumption when compared to VC systems.
The cycle includes one or more adsorbers, a condenser, an evaporator, and a heat source. This cycle is intermittent, but if more than one adsorber is utilized, it can be operated out of phase to produce a nearly continuous cooling effect [43].
Various types of adsorption systems for different applications have been studied and experimented with over the past decades [41,44,45,46,47], also focusing on specific mobile applications, such as trucks and vessels [48,49]. The adsorption cycle typically consists of the following steps:
  • Adsorption: The cycle begins with an adsorber, which contains a solid adsorbent material, often activated carbon, zeolite, or silica gel. The adsorbent has a high affinity for the refrigerant vapour. At low temperatures, the adsorbent attracts and retains the refrigerant vapour molecules on its surface, effectively adsorbing the vapour and releasing heat.
  • Desorption: The adsorbed vapour is then desorbed from the adsorbent material by raising its temperature. This is achieved by supplying heat from an external source, such as hot water or gas. The refrigerant vapour is released from the adsorbent surface, and the adsorbent material is regenerated.
  • Condensation: The desorbed refrigerant vapour is then condensed into a liquid state by transferring heat to a cooling medium, such as air or water. This process releases additional heat, which has to be dissipated in the ambient.
  • Expansion: The high-pressure liquid refrigerant is throttled through a valve, which reduces its pressure, and is transferred to the evaporator. This expansion process is different to the expansion valve in traditional refrigeration cycles.
  • Evaporation: The low-pressure, low-temperature refrigerant liquid absorbs heat from the surrounding environment (such as air or water) and evaporates, turning into a vapour. This heat absorption cools down the environment, making it suitable for air-conditioning in vehicles or other applications.
  • Adsorbent Regeneration: After the evaporation, the low-pressure refrigerant vapour returns to the adsorber, where it is adsorbed again by the adsorbent material. The adsorption process generates heat, which has to be dissipated (usually at the same temperature as the condensation heat) in the ambient. The cycle repeats as the adsorbent is regenerated and used for adsorption again.
Figure 4 reports the above-mentioned working phases of a closed adsorption thermodynamic cycle drawn on a Clapeyron diagram [50]. During the desorption stage, the adsorber or reactor, in which the adsorbent material is saturated with adsorbate, is regenerated by exploiting the waste heat coming from the engine, Q1 + Q2 (lines 1, 2, 3, Figure 4). The desorbed vapour is then condensed in the condenser, and the heat of condensation, Qc, is dissipated in the ambient, at the temperature of point E, through a radiator or an air mass cooled by a fan or direct air. Once the desorption process is completed and the adsorbent material is dry, the connection between the condenser and adsorber is closed. Afterwards, the connection between the evaporator and the adsorber is opened. During this phase, the refrigerant is evaporated by adsorbing heat from the vehicle passenger compartment, Qev, or provides cooling to a specific on-board process (batteries’ cooling) at the temperature of point F, as shown in Figure 4. Then, the vapour fluxes to the adsorber and, since the adsorption process is exothermic, the heat of adsorption is released, Q3 + Q4 (3-4-1). It is self-evident that in a double reactor system, working in counter-phase, the refrigerant is almost continuously condensed/evaporated in a closed system without any mass exchange with the ambient, thus ensuring a proper and reliable operation. Figure 5 depicts an example of a double reactor system for mobile applications.
Moreover, adsorption systems generally have a lower environmental impact compared to conventional systems when considering factors such as greenhouse gas emissions and other relevant environmental considerations.
  • Greenhouse Gas Emissions: Adsorption systems use natural refrigerants or environmentally friendly alternatives, such as water, which have a significantly lower global warming potential compared to the refrigerants used in conventional systems. This results in reduced direct emissions of greenhouse gases, mitigating their contribution to climate change.
  • Energy Consumption: Adsorption systems have the potential to achieve higher energy efficiency by utilizing waste heat. This reduces the overall energy consumption and reliance on fossil fuels, further minimizing their environmental impact.
  • Resource Depletion: Adsorption systems employ adsorbent materials that can be sourced sustainably. Additionally, adsorbents can be regenerated and reused, reducing resource depletion and waste generation compared to conventional systems.
  • Chemical and Toxic Substances: Adsorption systems generally involve the use of non-toxic adsorbent materials and do not require the use of harmful or ozone-depleting substances. This mitigates the potential environmental risks associated with leaks or accidental releases.
Considering the technical features, environmental aspects, and the thermodynamic process involved and presented above, in the pursuit of more sustainable and energy-efficient cooling solutions for automotive applications, more researchers have turned their attention to adsorption technology for air-conditioning. However, the analysis of the literature reported here, which is aimed at exploring the potential of adsorption air-conditioning technology specifically for automotive use, highlights a limited number of studies compared to VC technology. By analyzing the existing research, identifying advancements, and highlighting challenges, this analysis seeks to evaluate the feasibility of employing adsorption air-conditioning as an efficient and eco-friendly cooling solution for automobiles.
With this aim, in [51], the authors present a proposal for an integration of an adsorption air-conditioning system into recent emission control devices for heavy-duty truck applications. As emission standards continue to evolve, there are additional heat sources available to drive cooling systems. Thus, Zhong et al. proposed an adsorption system (see Figure 6) to both reduce engine emissions and improve overall energy efficiency, with the added benefit of reducing engine idle for long-haul vehicles. They reviewed the emission control components applicable to the adsorption system, presented a modular design of the system, and developed a model using zeolite and water as its working pair to study its dynamic performance and parametric effects. The results show that the cooling rate is greatly impacted by the mass transfer within the adsorber and increases as the adsorption rate increases. Additionally, there is a temperature transition during the transition between the adsorption and desorption phases. The heat transfer rate into or out of the adsorber reaches the maximum during this transition and then decreases as the process continues.
Moreover, they examined the system’s adsorbent properties, operating temperatures, and cycle periods, finding out that they can provide valuable design guidance. Interestingly, a shorter cycle period may result in a low COP but provide a larger total cooling capacity for the vehicle. To minimize the required number of modules for a given cooling load, an optimal cycle period must be determined due to the system’s performance decay.
However, the mass of the adsorbent embedded in the reactor can also heavily affect the overall performance. Indeed, in [52], the authors present a specific study on this issue. Indeed, in the field of vehicle air-conditioning, the adsorption air conditioners’ (ACS) weight and bulkiness prove to be significant challenges for their commercialization as eco-friendly alternatives to standard units. To try to address this issue, Sharafian et al. assessed the impact of the adsorbent mass and the number of adsorber beds on the performance of a FAM-Z02/water ACS under various operational conditions. Their experiments indicate that reducing the FAM-Z02 mass from 1.9 to 0.5 kg significantly increases the specific cooling power (SCP) by 82% from 65.8 to 119.4 W/kg at a 20 min cycle time but comes at the expense of a 37% decrease in the coefficient of performance (COP) due to the rise in the adsorber bed to adsorbent mass ratio. Moreover, their findings demonstrate that the ACS’s thermal mass limits its overall efficiency, particularly under shorter cycle times (i.e., 8–20 min). To ensure continuous cooling in the evaporator, a second adsorber bed is integrated into the initial ACS test bed containing one adsorber bed, and the results reveal an increase in the SCP and COP by 28% and 47%, respectively, when comparing one- and two-adsorber-bed ACSs packed with 0.5 kg of FAM-Z02 particles and a cycle time of 20 min.
Also, other technical aspects are of interest and have been investigated over the years. In this direction, for example, Sharafian et al. [53] investigated how the spacing of fins affects the distribution of temperature within a finned tube adsorber bed. The goal of their work was to minimize the adsorber bed to adsorbent mass ratio (AAMR) and reduce the temperature gradient within the adsorber bed for use in vehicle air-conditioning applications. Finned tube adsorber beds offer a superior specific cooling power, coefficient of performance, and low AAMR compared to other types of adsorber beds. To conduct the study, a single-adsorber-bed ACS with interchangeable heat exchangers was built and fitted with hermetic type T thermocouples. Two copper heat exchangers with custom-built fin spacing were packed with silica gel grains. The results of the study show that decreasing the fin spacing from 9.5 mm to 6.35 mm resulted in a reduction of 4.6 °C in the temperature difference between the fin and adsorbent during a cycle time of 600 s and an adsorption to desorption time ratio (ADTR) of one. Shorter cycle times (600 s) showed a greater reduction in the temperature gradient within the adsorber bed than longer cycle times (1400 s). The optimum fin spacing for a finned tube heat exchanger packed with silica gel grains was found to be approximately 6 mm based on a simultaneous comparison of the temperature gradient between the fins and AAMR against fin spacing.
Also, other studies proved that the design of the adsorber bed has a significant impact on the functioning of waste-heat-driven adsorption cooling systems for vehicle air-conditioning. Indeed, it is necessary to size the adsorber beds specifically for vehicles by taking into account the limitations of mobile applications. To this aim, the same research group also investigated the influence of the reactor design on the performance of an adsorption air conditioner [54]. They used some selected KPIs, such as specific cooling power, adsorber bed to adsorbent mass ratio, and coefficient of performance to evaluate the performance of the ACS. The study was carried out through a review of the existing literature. The analysis shows that a desired specific cooling power of 350 W/kg of dry adsorbent and an adsorber bed to adsorbent mass ratio of under one is necessary. They also highlighted how systems with a two adsorber bed and silica gel–water as a working pair are common for an ACS. The various adsorber bed designs that were examined were summarized into nine groups, with the finned tube adsorber bed design ultimately being selected. Practical solutions, such as optimizing the fin spacing and height, and adding metal wool to enhance the thermal conductivity of the adsorbent material within the finned tube adsorber bed, are suggested to improve the heat and mass transfer rates within the adsorber bed.
One of the most complete studies on the use of an ACS for automotive applications is the one presented by Verde et al. [55]. The authors presented a two-part investigation. The first part involved both theoretical and experimental examinations of a two-bed, automotive-based silica gel adsorption chiller (Figure 7). A prototype adsorption system weighing around 86 kg was created and tested with low-grade waste heat. The single adsorbent bed had three plate-fin heat exchangers linked in parallel (Figure 8).
Moreover, the authors developed a fully dynamic, non-equilibrium lumped parameter model to predict the system’s transient performance while accounting for the mass transfer resistance and pressure drop for each system component. The outcomes show that the model could precisely forecast the system’s dynamic performance under various operating conditions and setup modes while having a short calculation time. The tested chiller (see Figure 8) was capable of generating an average cooling power of roughly 2.1 kW with a COP of 0.35 at the rated operating conditions. The heat recovery system caused a 43% increase in the COP and a 4% increase in the cooling power.
In the second part of their study, Verde et al. [56] validated the model from Part I and integrated it into a comprehensive vehicle model to anticipate the system’s efficiency during actual driving situations. The overall model considered all system elements to simulate the dynamic system performance and predict the available waste heat for regulating the cabin temperature. Experimental tests on the Fiat Grande Punto vehicle were conducted at the Centro Ricerche Fiat (CRF) Italy labs, exploring different design configurations for improved performance. Figure 9 shows a scheme of the system installed into the car and the general layout of the adsorption unit tested. The results show that the model accurately predicted the system’s transient performance in various start-up and ambient conditions, as well as in normal operating conditions. Installing two radiators instead of one increased the cooling capacity by 7.0% and decreased the cabin temperature by 9.1%. However, the adsorption system faced difficulties producing cooling during the warm-up period. The research confirmed that there is adequate engine waste heat available to provide sufficient cooling for reasonably comfortable cabin temperatures.
This last study was supported by an intense model activity, reported in [57]. The research aimed to determine the ideal geometrical and thermal parameters of a flat tube-fin adsorbent bed through an analytical model to achieve optimal performance. Indeed, the design and performance of an adsorbent bed have a significant impact on the overall efficiency of adsorption systems. Flat tube-fin heat exchangers have advantages such as decreased weight, cost, volume, and thermal conductivity, which make them a suitable choice for automobile adsorbent bed applications. The study found that reducing the flat tube thickness and fin pitch, along with increasing the fin and water channel wall thickness, improved both the overall thermal conductance of the bed and the maximum practical specific cooling capacity. Furthermore, decreasing the channel pitch enhanced the specific thermal conductance. Of all the thermal parameters examined, adsorbent thermal conductivity was found to be the most sensitive factor affecting the specific thermal conductance of the beds. The system’s performance improved significantly when reducing the mass of the metal bed and heat transfer fluids, as well as the desorption heat of the selected working pair.
Within the same project, another research group developed and tested a compact adsorption unit designed for the installation of large trucks [48]. In the paper, the authors examined a mobile adsorption chiller as a cooling solution for truck cabins, with a focus on its experimental performance. The unit was developed by CNR ITAE and featured a double-bed adsorber linked to an evaporator and condenser, which utilizes the low-grade thermal energy generated by the engine coolant loop. The machine had an overall volume of 170 dm3 and a weight of 60 kg. The initial testing of the chiller’s performance was conducted under typical EU car air-conditioning conditions, determining an average cooling power (ACP) of 1–2.3 kW and a cooling COP of 0.25–0.45 at a desorption temperature of approx. 90 °C (Tev∼8–14 °C and Tcon∼28–35 °C). The chiller was then integrated into an IVECO STRALIS truck cabin and tested in a laboratory setting, demonstrating its ability to provide cooling comfort to passengers (see Figure 10). This was achieved by simulating the engine cooling loop through an ideal heat source.
Also, Tamainot-Telto et al. proposed a novel compact adsorption unit for automotive air-conditioning [58]. The authors developed a compact generator prototype that utilizes activated carbon and ammonia as a working pair and is based on the plate heat exchanger concept (see Figure 11). This innovative generator boasts a low thermal mass and effective heat transfer capabilities. The heat exchanger consists of nickel-brazed shims and spacers, which create thin adsorbent layers (measuring only 4 mm) between pairs of liquid flow channels with a minimal thermal mass. The sorption generator prototype was evaluated under EU car air-conditioning test conditions; when powered by waste heat from the engine coolant water at 90 °C, two of the current prototype generators (loaded with approximately 1 kg of activated carbon) operating out of phase produced an average cooling power of 1.6 kW with 2 kW peaks. The typical average coefficient of performance (COP) obtained was 0.22.
The four above-mentioned studies belong to the same EU-funded project [59], whose main results were summarized in [38]; they represent some of the most notable examples of successful system integration strategies that have been implemented on vehicles.
Another study focused on the impact of fin spacing on the performance of gas-driven adsorption units for heavy trucks. Golparvar et al. [60] demonstrated how the performance of an ACS heavily relies on the design of the adsorber bed heat exchangers (ABHEx). Indeed, according to the authors’ findings, the dynamic behaviour of the ACS is directly influenced by the response time of the ABHEx, as they undergo significant temperature swings to derive the refrigerant. The authors developed a detailed three-dimensional non-equilibrium model to investigate the heat and mass transfer effects in zeolite-13x particle-filled annular and longitudinal finned-tube adsorber beds.
The study focused on studying the impact of fin height and spacing on the operating parameters of the system to identify an optimal fin geometry. The simulation results indicate that decreasing the fin spacing leads to a decrease in the coefficient of performance (COP) and an increase in the specific cooling power (SCP). The results reveal that, under similar dimensions and operating conditions, the ACS employing an annular finned-tube ABHEx provides a 10% higher total cooling power than the ACS with a longitudinal finned-tube ABHEx at the optimum fin spacing. It is worth highlighting that Golparvar et al. found that implementing an ACS with an optimized ABHEx in trucks has the potential to save approximately 370 L of fuel consumption annually and reduce greenhouse gas emissions by up to 738 kg CO2e. These findings emphasize the significance of ABHEx design in enhancing the performance and energy efficiency of the ACS, thereby contributing to fuel savings and environmental sustainability in heavy-duty vehicle air-conditioning systems.
It is worth noting that research has also sometimes been addressed in solving different “on-board” issues for trucks and other heavy-duty transport units. For example, in [61,62], the authors first identified the key technical requirements of a heavy truck auxiliary power unit (APU) and then explored a potential new technology to replace the current diesel-engine vapour-compression APUs, which are known to cause issues related to emissions, noise, and maintenance. They investigated the potential performance of a novel hybrid Stirling engine-adsorption chiller system and compared it to the current technology using experimental data. Figure 12 shows a schematic of the proposed concept. The results of a prototype SAS test rig demonstrated that the system was capable of an average COP of 0.42 ± 0.06 and a cooling capacity of 2.3 ± 0.1 kWt. The study also demonstrated that no significant technological barriers are preventing the adoption of the proposed concept, which could offer reduced emissions, noise, maintenance, and fuel flexibility with increased reliability. The preliminary modelling results indicate that the proposed system could offer superior overall electrical and cooling efficiencies compared to incumbent APUs, with a payback period of lower than 5 years.
In 2001, Jiangzhou, Wang et al. [63] developed and tested an adsorber air-conditioning system for a locomotive driver cabin. The developed prototype is shown in Figure 13. They proved that the system could provide a constant refrigeration capacity during the desorption stage, which simplifies the entire system. Therefore, this system can be practically applied to cool the driver cabin. The desorption period can be optimized to improve the system performance, especially by increasing the adsorption time over the desorption time. The study provided the following interesting evidence:
  • The adsorption and desorption temperatures affect the COP significantly.
  • The condensing temperature is less sensitive to the COP of a zeolite–water adsorption system than an activated carbon–methanol adsorption system.
  • The system’s performance can be enhanced by optimizing the mass transfer within the adsorber, and an air-cooled condenser may be used.
  • A well-designed evaporator can fuel the refrigeration capacity output.
  • The use of adiabatic and cooling adsorption processes can provide additional refrigeration capacity for immediate space cooling.
  • The adsorber can function as another regenerator if there is a refrigeration capacity deficit.
Finally, their tests highlighted that at actual operating conditions, the heating power and flow rates of the cooling air are significantly higher than those of the experimental conditions, making the heating and cooling adsorber processes more efficient, and decreasing the total circulation period, thus increasing the refrigeration capacity.
However, while installation on heavy goods transport vehicles does not pose particular size and weight limits, installation inside passenger transport vehicles, even small ones, poses new challenges, as the size of most adsorption chillers can limit their application in the automotive industry. To overcome this issue, in [64], the authors presented a compact adsorption chiller that meets the specific requirements of automobile installation and has a volume of approximately 40 L. The authors highlighted how the size of the adsorption chiller is often significantly increased by the use of off-the-shelf vacuum valves, resulting in four high vacuum valves for the two adsorbers, evaporator, and condenser. For such a reason, they developed an innovative flap-based valve regulated by the difference in pressure at both ends (see Figure 14a). The cooling power and coefficient of performance were evaluated by analyzing the inlet and outlet temperatures of the evaporator, as well as the flow rate of the chilled water and cycled time. The prototype adsorption chiller had a maximum cooling power output of around 1.5 kW at a driving temperature of 368 K and a cycle time of 90 s.
Also, Sharafian et al. proposed an innovative design both for the expansion valve and the control valve of an automotive adsorption air conditioner [65]. Their idea was to reduce the weight and parasitic power consumption of an adsorption cooling system (ACS) for vehicle air-conditioning by implementing two new expansion valves and control valves. These ideas include a check valve for the expansion valve with a cracking pressure of 3.5–7 kPa and a combination of low cracking pressure check valves and solenoid valves for the control valves. These designs were tested on a two-adsorber-bed silica gel/CaCl2–water ACS under various operating conditions, resulting in a 10.5 kg reduction in the total mass and a 50% decrease in the parasitic power consumption of the control valves. Their tests proved that the expansion valve and control valves functioned effectively under specific temperature ranges for the heating and cooling fluid inlet, coolant water inlet, and chilled water inlet. Additionally, they developed a numerical model of the ACS thermodynamic cycle, showing that increasing the adsorber bed heat transfer coefficient and surface area can increase the specific cooling power of the system by up to six times.
However, the performance of the adsorbent material used in an adsorption air conditioner, especially if designed for mobile applications, also plays a crucial role in determining the overall efficiency and effectiveness of the system. The adsorbent material serves as the key component that is responsible for adsorbing and desorbing the refrigerant, thus facilitating the heat transfer process and achieving cooling. The following key features affect the performance of the adsorption units:
  • Adsorption Capacity: A high adsorption capacity allows for a greater amount of refrigerant to be adsorbed onto the material’s surface, resulting in an improved cooling performance. Adsorbents with a higher adsorption capacity can achieve higher cooling capacities and better overall efficiency.
  • Desorption Temperature: An ideal adsorbent material should have a desorption temperature that matches well with the available heat source.
  • Thermal Conductivity: A higher thermal conductivity allows for better heat transfer between the refrigerant and the adsorbent, leading to faster adsorption and desorption rates. An improved heat transfer enhances the chiller’s overall efficiency and performance.
  • Stability and Durability: Adsorption chillers operate through repeated cycles of adsorption and desorption, subjecting the material to temperature and pressure variations. An adsorbent material with excellent stability and durability can maintain its performance over an extended period, minimizing degradation and ensuring consistent efficiency.
The impact of adsorbent materials on the overall efficiency and effectiveness of adsorption chillers is evident. Therefore, current research and development endeavours are centred around optimizing these materials to enhance the performance and efficiency of adsorption air conditioners. The characteristics and performance of adsorbent materials and their influence on the performance of air conditioners and heat pumps were extensively studied by Freni et al. in [66].
To investigate the impact of the material type on the cooling performance, the researchers at the Laboratory for Alternative Energy Conversion (LAEC) of the School of Mechatronic Systems Engineering at Simon Fraser University studied the impact of the reactor design on the water uptake of a zeolitic material for an adsorption air conditioner for vehicles [67]. In their study, they highlighted how the performance of an ACS can be significantly influenced by the design of the adsorber bed by focusing on measuring the water uptake rate of the AQSOA FAM-Z02 zeolite, packed in two different adsorber beds, under adsorption and desorption temperatures of 30 and 90 °C, respectively, with water vapour supplied at 20 °C. They found that various parameters (heat transfer, fluid density changes, the flexibility of the housing connected to the adsorber bed, etc.) have a notable impact on the adsorbate uptake measurements. To mitigate these undesired effects, they employed a two-step mass measurement method to accurately determine the adsorbate uptake rate and validated it by comparing the equilibrium water uptake of the AQSOA FAM-Z02 zeolite with the available data in the literature obtained from the thermogravimetric analysis. The water uptake of the zeolitic material was measured for different cycle times to calculate the specific cooling power (SCP) and coefficient of performance (COP). The results demonstrate that a well-designed adsorber bed for automotive applications should have a high heat transfer surface area and small fin spacing.
Another study [68] investigated the potentialities of metal–organic frameworks (MOFs). These materials represent a new class of adsorbent materials that exhibit remarkable properties such as a substantial surface area, a significant pore volume, a uniform pore size, and highly adjustable structural characteristics. While numerous MOFs have been developed primarily for gas storage applications, only a limited number have been explored for their potential in water adsorption and heat-pumping applications. In this study, the authors focused on investigating the viability of utilizing a commercially available MOF known as CPO-27(Ni) for automotive adsorption air-conditioning. The investigation involves dynamic modelling and experimental testing to assess the performance of this MOF. To evaluate the performance of the CPO-27(Ni) under different operating conditions, Shi et al. developed a single-bed adsorption system and a Simulink model to simulate the operation of a two-bed adsorption system with a cooling capacity of 2.4 kW, specifically designed for automotive air-conditioning. The results obtained from the study indicate that the adsorption air-conditioning system utilizing the CPO-27(Ni) achieves a specific cooling power (SCP) of 440 W/kg and a coefficient of performance (COP) of 0.456 when the desorption temperature reaches 130 °C, which can be obtained through the utilization of the engine’s exhaust gas. Furthermore, they conducted a comparison between the performance of the CPO-27(Ni) and the ones achieved by using the advanced zeolite SAPO-34. The comparison demonstrated that the CPO-27(Ni) outperformed the SAPO-34, delivering a 42% higher SCP value, thus leading to a more compact air-conditioning system. The research emphasized the potential application of MOF materials in automotive air-conditioning systems, showcasing their capacity to enhance performance and efficiency in this context.
In [69], Wang et al. analyzed different pairs of adsorbent/refrigerant for adsorption air conditioners for electric vehicles. Indeed, the authors highlighted how the use of traditional compression air conditioners on electric vehicles leads to a significant drain on the battery’s power, resulting in reduced range, while intermittent sorption and resorption cycle energy storage phases could be employed to fix the issue. These cycles have a simpler design, requiring only two heat exchangers compared to conventional ACs. An equilibrium performance analysis revealed that resorption cycles have a higher energy density and coefficient of performance (COP) than sorption cycles, given that both have the same high-temperature salt for resorption and halide for sorption. The CaCl2-NH4Cl-NH3 performed the best compared to the MnCl2-CaCl2-NH3 and MnCl2-NH4Cl-NH3, demonstrating a 160% energy density improvement and a minimum COP increase of 35%. Comparing the CaCl2-NH4Cl-NH3 with the CaCl2-NH3 revealed a similar minimum energy density, but the CaCl2-NH4Cl-NH3 performed better in terms of the COP considering year-round working conditions. The energy requirements for electric cars with resorption ACs ranged from 0.23 to 0.265 kWh/km, which is an acceptable level compared to conventional ACs.
Hybrid air-conditioning systems have gained popularity among researchers [46,70,71,72,73] and offer significant potential for automotive applications due to their energy efficiency and reliability. These systems combine adsorption and compression techniques to generate cooling, making them well suited for small or confined spaces. By integrating both adsorption and compression elements, hybrid air-conditioning systems create a highly efficient cooling system that is particularly suitable for mobile applications. They are especially appropriate for commercial trucks, RVs, and boats where space is limited, and energy efficiency is critical. However, despite the advantages discussed in previous sections, the continuous operation of an adsorption air-conditioning system, capable of recovering battery waste heat, is limited. The thermal management systems of vehicles heavily rely on a vapour-compression refrigeration system, and the full potential of an adsorption air-conditioning system in continuous operation is constrained.
To bridge this gap, the authors in [74] tried to merge the benefits of both vapour-compression and adsorption technology; they proposed a vapour-compression-adsorption thermal management system (VCATMS) to tackle the cooling/preheating load and reduce electricity consumption. Their system provides waste heat recovery for battery cooling in the summer and preheating in the winter, plucking from a variety of working fluid pairs. They proved that the best performance is achieved with the activated carbon (AC)-R410A working fluid pair, given its exceptional equilibrium adsorption characteristics. With this system, up to 31.3 kJ and 67 kJ of electricity can be saved in recovery mode during the summer and in preheating mode in the winter, respectively. Additionally, the battery can be preheated to 30 °C in extreme sub-zero temperatures without consuming any electricity.
To conclude, the studies presented here show that the main advancements have focused on improving the efficiency of the adsorption process, enhancing heat transfer mechanisms, implementing innovative system designs, and utilizing advanced adsorbent materials. These advancements contribute to higher energy efficiency, reducing the energy consumption of the system and promoting sustainability in automotive air-conditioning.
Finally, Table 3 shows the performance data of the prototypes of adsorption air conditioners for cars, trucks, and trains. The selected prototypes showcase the potential of adsorption technology in providing air-conditioning solutions for different types of vehicles. The table serves as a reference for the development and implementation of adsorption air-conditioning systems in automotive transportation. Only references with consistent data were selected and are reported in Table 3.

7. Limitations of Adsorption Air Conditioners

As seen in the previous sections, adsorption air conditioners offer a unique alternative to standard air-conditioning systems in automotive applications. While these systems have several advantages, they also come with certain limitations that need to be considered.
Moreover, it is a well-known fact that adsorption systems or chillers have existed for many decades, even predating mechanical vapour-compression (MVC) systems. However, they have not been able to replace MVC systems. The use of adsorption systems in automotive air-conditioning benefits from the availability of waste heat, but this advantage will be significantly impacted by the rise in electric vehicles. On the other hand, internal combustion engine-driven vehicles are expected to remain in use for the foreseeable future, and the potential success of adsorption cooling systems in automotive air-conditioning could breathe new life into the industry by offering improved fuel efficiency and environmental benefits. Furthermore, the use of green fuels in the automotive sector holds significant potential as a direct retrofit solution. Indeed, green fuels, such as biofuels, hydrogen, and synthetic fuels, offer the advantage of being compatible with existing internal combustion engines and fueling infrastructures. This compatibility allows for a relatively straightforward transition from conventional fossil fuels to greener alternatives, without requiring significant modifications or replacements of existing vehicle systems. This direct retrofit perspective makes green fuels an attractive option for achieving immediate environmental benefits and reducing carbon emissions in the automotive sector [85].
However, the study presented above highlighted how it is essential to consider vehicle adsorption systems separately from stationary chillers, as they operate in different domains and are subject to space and weight constraints. The limitations of adsorption air conditioners for automotive applications in comparison to standard systems that emerged in this study are highlighted as follows:
  • Capacity Density: One of the primary limitations of adsorption air conditioners is their lower cooling capacity density compared to that of standard systems. Adsorption technology relies on the desorption of water vapour from a solid material, and this process is slower and less efficient than the compression and expansion of refrigerant gases used in standard air conditioners. As a result, adsorption systems may struggle to provide adequate cooling performance, especially in extremely hot climates or under heavy load conditions, or they may result in bulk and heavy systems that could impact the integration process in small vehicles, even though the industry has made significant advancements to address this issue, such as compact and efficient evaporator designs [86], compact or innovative adsorber heat exchangers [87,88], the introduction of composite adsorbents [89,90], etc. The reported capacity density values for adsorption systems range from 70 to 110 W/kg (based on different studies [79,91,92]), while a typical VC system has an energy that is higher than 520 W/kg [92]. In terms of volumetric energy density, the reported values are lower than 27 W/m3 [79]. Also, the external piping and valves, whose size and weight increase with the capacity, contribute to reducing the capacity density. A solution for such an issue may be represented by the integration of heat pipe technology for heat exchange into high-power air conditioners [93]. However, there is a need for further improvement in the capacity density of adsorption systems. It is important to note that conventional terminologies, for example, the specific cooling power (SCP) based on dry mass, can be misleading. Instead, specific energy density based on the total mass or volume of the system should be used, and a fair comparison with conventional VC systems should be made when appropriate.
  • Size and Weight: When comparing the size and weight of adsorption systems to compression-based systems for automotive applications, there are notable differences to consider. Adsorption systems tend to be bulkier and heavier than their compression counterparts. This is primarily due to the adsorbent material used in adsorption systems, which requires a larger exchanger surface area for efficient cooling [94]. As a result, adsorption systems often require larger components and additional space for the adsorption and desorption processes to take place effectively. This increased size and weight can pose challenges in automotive applications, where space and weight constraints are crucial considerations for vehicle design and performance. On the other hand, compression-based systems, such as mechanical vapour-compression (MVC) systems, have undergone significant miniaturization and optimization over the years [95]. They have been engineered to be more compact and lightweight, making them a preferred choice for automotive air-conditioning applications. These systems leverage the efficiency of compression and expansion cycles, which can be achieved with smaller components and less material. The size and weight limitations of adsorption systems can impact the overall design and performance of vehicles. They may require more space for installation and could add extra weight, potentially affecting fuel efficiency and vehicle handling. In contrast, compression systems offer more flexibility in terms of integration and can be designed to fit within the available space and weight restrictions of a vehicle. While efforts have been made to reduce the size and weight of adsorption systems through advancements in technology, they still tend to lag behind compression-based systems in this aspect. As a result, the size and weight considerations remain significant limitations for adsorption systems in automotive applications, where compactness and lightweight solutions are highly valued.
  • Response Time: Adsorption air conditioners typically have a longer response time compared to standard systems. Adsorption and desorption processes take time to occur, resulting in a slower cooling performance when the system is first activated. This delay can be problematic in situations where quick cooling is necessary, such as when entering a hot vehicle or during short stops. Moreover, another property of the adsorbent materials that affects the response time is the adsorption kinetic. The adsorption kinetic in adsorption air conditioners is primarily determined by the properties of the adsorbent material, its shape, and its physical status. The adsorbent should have a large surface area and a strong adsorption affinity for the refrigerant being targeted. Additionally, the adsorbent should be able to maintain its structural integrity over many adsorption–desorption cycles to ensure that it provides long-term performance. In terms of adsorption kinetics, the rate at which the refrigerant (usually water) molecules are adsorbed onto the adsorbent material is a key factor in determining the overall efficiency, the cycle time, and the specific cooling capacity of adsorption air conditioners [96,97].
  • Limited Operating Conditions: In automotive applications, closed-cycle adsorption systems face certain limitations in terms of their operating conditions when compared to VC systems. These limitations arise from the fundamental differences in the underlying principles of these two cooling technologies. VC systems allow for a wide range of operating conditions, including varying temperatures, making them adaptable to different environmental conditions and user preferences. The compressors in these systems can adjust their speed and capacity, providing the operator with precise control over cooling output. On the other hand, adsorption systems utilize the adsorption and desorption of a working substance that selectively adsorbs the adsorbate (water vapour) at low temperatures and desorbs it at higher temperatures; this process drives the cooling effect in the system. One of the limitations of adsorption systems in automotive applications is their dependence on specific operating conditions for efficient performance [98,99]. The adsorbent material used in the system has a limited range of temperatures at which it can effectively adsorb and desorb the adsorbate [100]. This restricts the operating temperature range of the system, limiting its adaptability to varying ambient temperatures and user preferences. Moreover, efficient adsorption systems often require high desorption temperatures to release the adsorbed refrigerant effectively. Achieving these high temperatures can be challenging in automotive applications, especially considering the limited temperature of waste heat sources available in some conditions such as start-up and idle operations.
  • Reliability: When evaluating reliability, it has been reported that adsorption systems can effectively function for many years [101], while adsorbent materials are capable of thousands of cycles [102]. It is important to note, however, that the systems presented in the previous references are not suitable for automobile air-conditioning due to the harsh operational environment. Vibrations, sudden impacts, and high temperatures can all potentially damage the adsorber’s heat exchanger. Therefore, sintered or firmly coated adsorber heat exchangers may be preferable to the conventional wire-mesh packing method [103,104,105]. Also, exchangers that are made of plastic material, if well engineered, can represent an effective breakthrough for reliability and lifetime increase [106]. In addition, a high-temperature environment can negatively impact the adsorption process, which is highly dependent on the coolant temperature.
  • Economic aspects: The production cost of adsorption air conditioners for automotive applications can vary depending on various factors, and it is generally higher than that of conventional systems. Recently, Al Hasni and Santori provided the average cost breakdown for an adsorption chiller [8]. They showed that, although adsorption chillers are more environmentally sustainable than other types of chillers, their price-performance trade-off makes it difficult for them to capture a significant share of the air conditioner system. The authors also highlighted that the emphasis in research so far has been on improving performance, without adequately considering whether this will lead to reduced manufacturing costs. To address this gap, they estimated the manufacturing cost and end-user price of silica gel adsorption chillers. The analysis is extended across different COP and SCP combinations and identifies a minimum annual selling volume of 14 units. The manufacturing process used for the production of adsorption air conditioners also plays a role in determining the cost. The cost of the process, such as batch production or continuous production, depends on the equipment needed, the level of automation, and the time it takes to complete the process. Their results assess the economic viability of adsorption chillers with advanced adsorption materials, such as metal–organic frameworks (MOFs) and advanced zeolites, which do not compete, for the moment, with silica gel chillers in cost; thus, future innovative adsorption materials should be compared to silica gel using the correlations they presented in their study.
  • Non-technical aspects: The current development of adsorption systems is predominantly conducted through laboratory- or project-based research. However, for this technology to progress and gain acceptance on a wider scale, active involvement and support from the car manufacturing industry are crucial. In addition, authorities need to provide support and incentives to push new technologies forward. For instance, renewable energy technologies like solar PV and hybrid vehicles gained widespread acceptance through government incentives during their early introduction. Similarly, adsorption systems for automobile air-conditioning could benefit from similar support from authorities.
In summary, while adsorption air conditioners offer some advantages, such as their environmentally friendly operation and potential energy savings during the adsorption process, they also have significant limitations. These limitations include a lower cooling capacity, a larger size and weight, a longer response time, sensitivity to operating conditions, a potentially lower overall energy efficiency, and higher maintenance and cost requirements.
Adsorption units, when compared directly to conventional VC systems for automobile air-conditioning, show inferiority across multiple aspects. However, the crucial features of the adsorption system lie in its potential to enhance fuel economy and environmental friendliness. Yet, realizing these potentials requires addressing negative factors such as the need for an improved capacity density and a reduced cost. Furthermore, with the rise of electric vehicles, which lack waste heat like traditional engines, the energy rejection from battery packs may not suffice to power a thermal system. As a result, the widespread adoption of adsorption systems in vehicles may face further obstacles. These considerations are essential when evaluating the suitability of adsorption air conditioners for automotive applications, particularly when compared to standard air-conditioning systems. All of these aspects serve as valuable inputs for future research in this field.

8. The Issue of Electric Vehicles—Other Active Air-Conditioning Technologies

As electric vehicles (EVs) gain prominence in the automotive industry, the need for efficient and effective air-conditioning (AC) technologies specifically designed for these vehicles becomes increasingly important. Active air-conditioning technologies play a crucial role in providing cabin comfort, optimizing energy consumption, and extending the range of electric vehicles. Active AC technologies tailored for EVs are the following:

8.1. Electric Compressor Systems

Electric compressor systems are widely used in EVs and work similarly to their counterparts in conventional vehicles. They consist of an electric compressor, condenser, evaporator, and expansion valve. The electric compressor is driven by the vehicle’s high-voltage electrical system, enabling independent operation from the internal combustion engine. This allows for efficient cooling even when the vehicle is stationary or during low-speed operation. Similarly, heat pump systems are designed to provide both heating and cooling capabilities for EVs. These systems utilize the principles of refrigeration in reverse, extracting heat from the ambient air or waste heat sources and transferring it to the cabin during cold weather conditions. Heat pumps improve energy efficiency by utilizing the heat that is already available rather than relying solely on electrical energy for heating.

8.2. Thermal Storage Systems

Thermal storage systems employ phase-change materials (PCMs) to store and release thermal energy [107]. These systems can pre-condition the vehicle’s cabin by absorbing excess heat during charging or discharging cycles. PCMs can store and release heat efficiently, reducing the need for continuous energy consumption during driving, thereby extending the vehicle’s range. Also, adsorption-based cold storage devices have a high energy density and can be used for both heat and cold release in the automotive sector. However, there have only been a few studies on small and compact systems for mobile applications using low-temperature sources [108].

8.3. Solar-Powered Ventilation

Solar-powered ventilation systems utilize photovoltaic (PV) cells installed on the vehicle’s roof or windows to convert solar energy into electrical energy. This energy is used to power ventilation fans that extract hot air from the cabin, thereby reducing the temperature buildup while the vehicle is parked. Solar-powered ventilation enhances passenger comfort upon entry and reduces the need for excessive energy consumption from the vehicle’s battery for cooling [109,110].

8.4. Thermoelectric Air Conditioners

Thermoelectric systems represent a potential alternative in the field of air-conditioning for vehicles. Furthermore, the technological progress is closely linked to the progress of semiconductor technology, and this bodes well. Thermoelectric technology is a promising approach for automotive air-conditioning (AC) applications that offers unique advantages and opportunities for improved energy efficiency and passenger comfort. This technology utilizes the thermoelectric effect to directly convert electrical energy into a temperature gradient and vice versa. Thermoelectric devices, known as thermoelectric coolers or Peltier devices, consist of semiconductor materials that exhibit the thermoelectric effect. When a direct current (DC) is applied to the device, one side becomes hot, while the other side becomes cold, creating a temperature gradient across the device. This effect is based on the Seebeck effect, where a temperature difference generates an electric potential difference (voltage) across a junction of dissimilar materials. By reversing the current flow, the temperature gradient can be reversed, allowing for the device to function as a heater. An example of integration of such a system into a vehicles is depicted in Figure 15.
The advantages of thermoelectric technology for automotive AC are as follows:
  • Compact Size: Thermoelectric devices are compact and have a low-profile design, making them suitable for integration into automotive AC systems without requiring significant space.
  • Solid-State Operation: Thermoelectric devices have no moving parts, making them reliable, vibration-resistant, and maintenance-free.
  • Rapid Response: Thermoelectric devices can quickly adjust the cooling or heating output, providing immediate comfort to the passengers.
  • Zonal Control: Thermoelectric technology enables zonal control, allowing for different areas or seats within the vehicle to be cooled or heated individually based on passenger preferences.
  • Environmentally Friendly: Thermoelectric technology does not use refrigerants or harmful gases, eliminating the environmental concerns that are associated with traditional VC systems.
  • Reduced HVAC System Complexity: Thermoelectric devices can simplify the AC system design by eliminating the need for mechanical compressors, refrigerant lines, and complex control mechanisms.
While thermoelectric technology offers several advantages, it also faces certain challenges and limitations as follows:
  • Limited Cooling Capacity: The cooling capacity of thermoelectric devices is typically lower compared to traditional VC systems, which may limit their application in larger vehicles or extremely hot climates.
  • Efficiency at High-Temperature Differentials: The thermoelectric efficiency decreases as the temperature differential across the device increases. Optimizing the efficiency of thermoelectric devices at higher temperature differentials remains a challenge.
  • Cost: The cost of thermoelectric devices, especially those with a high efficiency and cooling capacity, can be higher compared to that of traditional AC systems. However, advancements in materials and manufacturing processes are gradually reducing costs.
  • Power Consumption: Thermoelectric devices require a significant amount of electrical power, which can impact the overall vehicle’s energy consumption and potentially reduce the driving range in electric vehicles.
Ongoing research and development efforts are focused on enhancing the efficiency and cooling capacity of thermoelectric devices through advancements in materials, device design, and system integration. Improvements in thermoelectric materials, such as the use of nanostructured materials or hybrid systems, show promise in increasing the performance of thermoelectric AC systems. Additionally, integrating thermoelectric technology with other cooling technologies, such as VC or thermally driven systems, can lead to hybrid AC systems that combine the benefits of multiple cooling methods. Thermoelectric technology offers unique advantages and opportunities for automotive air-conditioning applications, including compact size, solid-state operation, zonal control, and improved energy efficiency. While challenges and limitations exist, ongoing research is focusing on new designs and thermal comfort. For example, in [112], the authors propose and explore the effectiveness of a newly designed cooling system based on thermoelectric cooling installed on the car’s roof. They carried out a theoretical model based on energy balance, revealing that the optimal number of thermoelectric modules used is dependent on the input power, with 150 modules needed for an input power of 200 W, and 100 modules needed for an input power of 1000 W. Their experiments proved that the thermoelectric cooling (TEC) system can keep the cabin temperature at 26 °C at a 1000 W input power, while the coefficient of performance decreases from about 3 to 0.85 as the input power increases from 200 W to 1000 W. It is important to note that while the TEC’s coefficient of performance may be lower than that of traditional systems (usually 2.5–4), its advantages make it a competitive alternative. The study provides an economic analysis based on the Egyptian market, proving that the annual cost of the thermoelectric cooling system is lower than that of the conventional air-conditioning system.
In [113], Kim et al. provide us with the details of the development and integration of a thermoelectric cooler and generator for automobile use. The interesting aspect of their work is that they realized and studied a cooler that delivers cool air from the ceiling of the rear seat, thus overtaking the limitations of car air-conditioning systems, which are typically driver-oriented due to space constraints. Their compact cooler operates quietly and efficiently, taking less than three minutes to cool a space that is the size of an average adult’s head from 45 to 26 °C. The required power is generated by a thermoelectric generator, consisting of twelve generators attached to the automobile’s exhaust pipe, that produces about 90 W of power at an average temperature of 90 °C. To ensure a constant power supply to the cooler, a storage device was designed to integrate the generator and cooler.
However, the management strategies of the air-conditioning system have a key role and a huge impact on the system’s efficiency and energy consumption. Since the power usage of conventional air-conditioning systems in commercial vehicles to cool the entire cab is excessive, and because most vehicles have only one driver, adjusting the temperature around the driver can substantially decrease energy wastage. In [114], the authors implemented such an idea and presented a localized air-conditioning system that employs thermoelectric cooling (TEC) devices. The authors studied the system’s operational parameters to determine its optimal performance under practical conditions, investigated the relationship between the device’s operating current and its cooling capacity, and conducted experimental activity. In their experiment, the authors installed the TEC system in a commercial vehicle cab to analyze the thermal comfort and energy efficiency of the local air-conditioning system using computational fluid dynamics. They found out that when applying local thermoelectric refrigeration, the overall thermal comfort deviation is 7.94% higher than that of traditional refrigeration when the cooling power is 3000 W. The semiconductor cooling device’s best refrigeration performance with a low energy consumption occurs when the centrifugal fan governor’s duty ratio is 40–60%. This enables the driver’s thermal comfort to be maintained while lowering the air conditioner’s energy consumption.

8.5. Advanced Control Systems

Optimizing the performance of active AC technologies in electric vehicles (EVs) heavily relies on advanced sensing and control systems. These systems are crucial as they integrate various sensors, such as temperature, occupancy, humidity, and solar radiation sensors, to collect real-time data. By incorporating intelligent control algorithms, these systems dynamically adjust the AC operation based on occupant preferences, ambient conditions, and energy availability, effectively maximizing both comfort and energy efficiency. A notable feature is smart zone cooling, which enables personalized temperature control within distinct zones of the vehicle cabin. Through the utilization of individual vents, sensors, and control mechanisms, passengers can independently adjust the temperature within their respective seating areas to their desired levels. This approach optimizes energy consumption by avoiding unnecessary cooling in unoccupied or less-occupied zones, resulting in improved overall energy efficiency. Furthermore, energy recovery systems capture waste heat generated by various components of the vehicle, including the powertrain and battery. This waste heat is harnessed to preheat or precool the air entering the cabin. By utilizing this recovered energy, the load on the AC system is reduced, leading to enhanced energy efficiency and extended vehicle range.

8.6. Future Innovations

Ongoing research and development regarding active AC technologies for EVs are focused on further enhancing efficiency, reducing weight and size, and exploring novel cooling concepts. Advancements in thermoelectric cooling, solid-state cooling, and advanced materials offer promising possibilities for more efficient and environmentally friendly solutions.
The integration of active air-conditioning technologies tailored for electric vehicles is crucial for maximizing cabin comfort, optimizing energy efficiency, and ensuring the overall driving range. By adopting these technologies, manufacturers can offer superior cooling and heating performance while minimizing the impact on the vehicle’s battery range. With ongoing advancements and continuous research, active AC technologies for electric vehicles will continue to improve.

9. Conclusions

Adsorption AC systems were critically examined in this review article. While various sustainable methods are being explored as replacements for VC systems, each has its unique advantages and disadvantages. Mobile air-conditioning (MAC) in vehicles currently consumes about 1.5% of the world’s oil, and account for approximately 6% of the total energy consumption of cars globally. Depending on various factors such as climate, traffic congestion, and driving habits, this energy consumption can range from 3% to 40%.
In such a scenario, adsorption systems for automobile air-conditioning have proven to be a promising alternative to traditional systems. The technology has shown significant advancements in recent years, providing an energy-efficient and eco-friendly solution for automobile air-conditioning that also addresses the limitations associated with conventional systems. Despite their potential, adsorption systems for automobile air-conditioning still face limitations. Their efficiency is highly dependent on the choice of adsorbent materials and the corresponding design of the system. Additionally, adsorption systems have a slow cooling response compared to conventional systems, making them less adequate for certain driving situations. Other significant limitations include the high cost of adsorbent materials and a lower cooling capacity. All of these problems cannot easily be solved without the strong support of research in the field of engineering and chemistry.
The development of innovative adsorption systems holds significant opportunities for the automotive industry as they move towards sustainable transportation solutions. The application of adsorption systems can promote energy efficiency, reduce greenhouse gas emissions, and provide an eco-friendly alternative to conventional air-conditioning systems for automobiles. However, to reach their full potential, further research and development must be conducted to address the strong limitations that emerged in this review.

Funding

This research received no external funding.

Data Availability Statement

No new data were created for this paper.

Conflicts of Interest

The author declares no conflict of interest.

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Figure 1. Classification of cooling systems for automotive applications (grey-boxed technologies are not treated in this review).
Figure 1. Classification of cooling systems for automotive applications (grey-boxed technologies are not treated in this review).
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Figure 2. Vapour-compression system key components.
Figure 2. Vapour-compression system key components.
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Figure 3. Energy flow Sankey diagram for an average car engine.
Figure 3. Energy flow Sankey diagram for an average car engine.
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Figure 4. Typical adsorption cycle on a Clapeyron diagram.
Figure 4. Typical adsorption cycle on a Clapeyron diagram.
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Figure 5. A simplified compact layout of an adsorption air conditioner for automotive applications.
Figure 5. A simplified compact layout of an adsorption air conditioner for automotive applications.
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Figure 6. The adsorption module proposed by Zhong et al. [51]. (a) single module; (b) double reactor system.
Figure 6. The adsorption module proposed by Zhong et al. [51]. (a) single module; (b) double reactor system.
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Figure 7. Schematic of the adsorption system studied by Verde et al. [55].
Figure 7. Schematic of the adsorption system studied by Verde et al. [55].
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Figure 8. The prototype tested by Verde et al. [55]. (a) Two sorption beds connected to the central housing that contains the refrigerant check valves. (b) One sorption bed assembly.
Figure 8. The prototype tested by Verde et al. [55]. (a) Two sorption beds connected to the central housing that contains the refrigerant check valves. (b) One sorption bed assembly.
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Figure 9. The onboard adsorption air-conditioning system installed in the Fiat Grande Punto and the system layout [56]. (a) arrangement of components on the vehicle; (b) scheme of the system.
Figure 9. The onboard adsorption air-conditioning system installed in the Fiat Grande Punto and the system layout [56]. (a) arrangement of components on the vehicle; (b) scheme of the system.
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Figure 10. The unit developed by Vasta et al. installed on the IVECO STRALIS cabin at CNR ITAE in Messina (Italy) [48].
Figure 10. The unit developed by Vasta et al. installed on the IVECO STRALIS cabin at CNR ITAE in Messina (Italy) [48].
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Figure 11. The sorption reactor for automotive air-conditioning proposed by Tamainot-Telto et al. [58]. (a) reactor’s dimensions; (b) the realized prototype.
Figure 11. The sorption reactor for automotive air-conditioning proposed by Tamainot-Telto et al. [58]. (a) reactor’s dimensions; (b) the realized prototype.
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Figure 12. The concept of the auxiliary power unit proposed by Flannery et al. [61,62].
Figure 12. The concept of the auxiliary power unit proposed by Flannery et al. [61,62].
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Figure 13. Scheme of the adsorption driver cabin air conditioner proposed in [63].
Figure 13. Scheme of the adsorption driver cabin air conditioner proposed in [63].
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Figure 14. The innovative vacuum valve proposed (a) and the scheme of the adsorption air conditioner (b) developed in [64].
Figure 14. The innovative vacuum valve proposed (a) and the scheme of the adsorption air conditioner (b) developed in [64].
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Figure 15. An example of a thermoelectric technology study carried out for automotive applications [111]. (a) arrangement of the system on the vehicle; (b) scheme of the module.
Figure 15. An example of a thermoelectric technology study carried out for automotive applications [111]. (a) arrangement of the system on the vehicle; (b) scheme of the module.
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Table
Table 1. List of refrigerants for automotive AC systems.
Table 1. List of refrigerants for automotive AC systems.
NSigleNameFormulaDescriptionGWP
1R134a [28]1,1,1,2-TetrafluoroethaneF3C-CH2-FThe R134a has been widely used as a replacement for the ozone-depleting refrigerant R12 (CFC-12). It has a relatively low global warming potential (GWP) compared to previous refrigerants. The R134a offers good thermodynamic properties and is compatible with the materials that are commonly found in automotive AC systems. However, its GWP is relatively high, and efforts are being made to transition to lower GWP alternatives.1300
2R1234yf [29]2,3,3,3-TetrafluoropropeneCH2=CF-CF3The R1234yf is a hydrofluoroolefin (HFO) refrigerant specifically designed as a low GWP alternative to the R134a. It has a significantly lower GWP and is being widely adopted in the automotive industry to reduce environmental impact. The R1234yf provides a similar cooling performance to the R134a and is compatible with existing AC system components. It has gained regulatory approval for use in many regions.4
3R744 [30]Carbon DioxideCO2Carbon dioxide, or R744, is an environmentally friendly refrigerant with a GWP of 1. It is a natural refrigerant and has excellent thermodynamic properties. However, due to its high operating pressures, the R744 requires specialized AC system components, including high-pressure compressors and heat exchangers. R744 AC systems are commonly used in electric and hybrid vehicles.1
4R152a [28]1,1-DifluoroethaneC2H4F2The R152a is a hydrofluorocarbon (HFC) refrigerant that has a lower GWP than the R134a. It offers similar thermodynamic properties to the R134a and is compatible with existing AC system components. However, its use is less widespread compared to the R134a and R1234yf.124
5R290 [31]PropaneCH3CH2CH3Propane, or R290, is a hydrocarbon refrigerant with a very low GWP. It is a natural refrigerant and has excellent thermodynamic properties. The R290 is flammable and requires specific safety measures during handling and use. Its application in automotive AC systems is limited due to safety concerns, but it has been explored in some specialized vehicle applications.3
6R1234ze [32]Trans-1,3,3,3-TetrafluoropropeneC3H2F4The R1234ze is an HFO refrigerant with a very low GWP. It is considered a potential replacement for the R134a and R1234yf. The R1234ze offers good energy efficiency and thermal properties, making it suitable for automotive AC systems. It is being actively researched and tested for its applicability in various cooling applications. It has zero ozone depletion potential (ODP = 0), a very low global warming potential that is even lower than CO2 [33], and it is classified by ANSI/ASHRAE as a class A2L refrigerant (lower flammability and lower toxicity).<1 [33]
7R152a/R1234yf Blends [34]----Blends of the R152a and R1234yf are being considered as potential alternatives to single-component refrigerants. These blends aim to combine the desirable characteristics of both refrigerants, such as a low GWP, good energy efficiency, and compatibility with existing AC system components. Research is ongoing to optimize the blend ratios and assess their performance in automotive AC applications.
8HFOs [35]Hydrofluoroolefins (HFOs) with Ultra-Low GWPs--HFOs continue to be an area of exploration for future refrigerants. Researchers are working on developing HFOs with ultra-low GWPs to further reduce the environmental impact of automotive AC systems. These HFOs aim to provide improved energy efficiency and thermodynamic properties while minimizing direct and indirect greenhouse gas emissions.
9R717, R600 [36]Natural Refrigerants: Ammonia, Butane--Natural refrigerants, such as ammonia (R717) and hydrocarbons (propane–R290, butane–R600), are gaining attention as environmentally friendly alternatives. These refrigerants have very low GWPs and are readily available. However, their adoption in automotive AC systems is limited due to safety concerns and the need for specialized components. Ongoing research is focused on enhancing the safety aspects and evaluating the feasibility of natural refrigerants in automotive applications.
Table
Table 2. Pros and cons of recovering the heat from the coolant engine loop or exhaust pipeline.
Table 2. Pros and cons of recovering the heat from the coolant engine loop or exhaust pipeline.
From the CoolantFrom the Exhaust
Temperature 80–90 °C>400 °C
Pros
  • Temperature level suitable for low-temperature systems.
  • Simplified design.
  • Lightweight realization.
  • Direct heating of the system.
  • High-quality energy.
  • Compact design.
  • No capacity limitation.
  • Direct and indirect recovery.
Cons
  • Capacity limitation.
  • Temperature fluctuation.
  • Increased pressure drops in the coolant loop.
  • Increased back pressure to the combustion process.
  • Complex temperature and flow control.
  • Acid gas condensation.
  • Exchanger fouling.
  • Need for high-temperature components.
Table
Table 3. Performance table of comprehensive studies on adsorption air conditioner prototypes.
Table 3. Performance table of comprehensive studies on adsorption air conditioner prototypes.
NType of VehicleAdsorbentRefrigerantTsourceTevCOPSCPCapacityHeat SourceReference
[°C][°C] [W/kg][kW]
1CarZeolite 13XWater300–450100.4145n.a.Exhaust[75]
2CarACAmmonia90200.22<8001.6–2.0Coolant loop[58]
3CarSilica GelWater90120.612053.6Coolant loop[76]
4TruckZeolite Water250–300100.382645Exhaust[77]
5TruckZeolite 13XWater01–160.41800.01Exhaust[78]
6TruckZeoliteWater2507–150.43n.a.2.0Exhaust[51]
7TruckZeoliteWater90100.6n.a.5.0Coolant loop[79]
8TruckZeoliteWater>40011n.an.a.2.5Exhaust[80]
9TruckZeolite FAM Z02Water9090.45300–6002.3Coolant loop[48]
10TrainZeoliteWater230180.38n.a.3.4Exhaust[81]
11TrainZeoliteWater350–450100.251656.5–10.0Exhaust[82]
12TrainZeoliteWater40070.25n.a.5.0Exhaust[83]
13TrainZeoliteWater200–250180.21n.a.3.0–4.2Exhaust[84]
14TrainZeoliteWater200–25050.25n.a.2.8–4.0Exhaust[63]
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Vasta, S. Adsorption Air-Conditioning for Automotive Applications: A Critical Review. Energies 2023, 16, 5382. https://doi.org/10.3390/en16145382

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Vasta S. Adsorption Air-Conditioning for Automotive Applications: A Critical Review. Energies. 2023; 16(14):5382. https://doi.org/10.3390/en16145382

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Vasta, Salvatore. 2023. "Adsorption Air-Conditioning for Automotive Applications: A Critical Review" Energies 16, no. 14: 5382. https://doi.org/10.3390/en16145382

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