Examining Pollutants Affecting Air Circulation

Examining Pollutants Affecting Air Circulation

Importance of Multimeter Selection for Mobile Home HVAC Systems

Mobile homes, known for their affordability and versatility, have become a staple housing option for many individuals and families. However, due to their unique construction and design, they face specific challenges when it comes to heating, ventilation, and air conditioning (HVAC) systems. Understanding these systems is crucial not only for maintaining comfort but also for ensuring healthy air quality within the home. One of the primary concerns in mobile home HVAC systems is the circulation of pollutants that can compromise indoor air quality.


Mobile home HVAC systems are generally compact and designed to fit the limited space available. Energy-efficient HVAC systems reduce utility costs for mobile home owners best hvac system for mobile home water purification. They often include packaged units or small split-systems tailored specifically for mobile homes' size constraints. Despite their efficiency in maintaining temperature control, these systems are vulnerable to certain issues due to the structure's susceptibility to external elements and internal space limitations.


One major vulnerability of mobile home HVAC systems is inadequate ventilation. Mobile homes are typically well-insulated to enhance energy efficiency; however, this can lead to poor air exchange rates. Without adequate ventilation, pollutants such as dust, mold spores, volatile organic compounds (VOCs), and other airborne particles accumulate more easily inside the home. This accumulation can adversely affect respiratory health and overall well-being.


Pollutants enter mobile homes from various sources: outdoor air pollution seeping through cracks or poorly sealed windows and doors; off-gassing from building materials like plywood or manufactured wood products; emissions from household cleaning agents; and combustion by-products from stoves or heaters that burn fossil fuels without proper venting. Given that mobile homes often have smaller spaces with fewer rooms than traditional houses, these pollutants can quickly become concentrated if not adequately managed by an effective HVAC system.


Furthermore, moisture control is another critical aspect where mobile home HVAC systems may falter. Mobile homes located in humid climates are particularly at risk of excess moisture buildup which fosters mold growth-a significant pollutant affecting air circulation-and structural damage over time. Inadequate sealing around windows, roofs, or plumbing fixtures can exacerbate this issue by allowing water intrusion during heavy rainfalls.


Improving air circulation in mobile homes involves several strategies focused on reducing pollutant levels while enhancing system effectiveness. Regular maintenance of HVAC units is essential: changing filters frequently ensures optimal airflow while preventing dust accumulation; inspecting ductwork helps identify leaks or blockages that might impede efficient operation; scheduling professional cleaning services removes any built-up debris within vents.


Additionally, integrating mechanical ventilation solutions-such as exhaust fans in kitchens/bathrooms-or employing heat recovery ventilators (HRVs) can significantly improve fresh air intake without compromising energy efficiency too drastically even though initial installation costs could be higher than simpler alternatives like passive vents alone would require


In conclusion ,the overview presented highlights how understanding vulnerabilities inherent within typical configurations used across most manufactured dwellings coupled together alongside proactive measures aimed towards mitigating risks posed thereby ultimately contributes greatly towards maintaining healthier environments conducive optimal living conditions thus ensuring long-term satisfaction residents alike

Key Features to Look for in a Multimeter for HVAC Applications —

Indoor air quality (IAQ) is a growing concern, particularly in unique living environments such as mobile homes, where the characteristics of construction and space can exacerbate the presence of pollutants. Understanding the common pollutants that affect air circulation in these settings is essential for improving health outcomes and ensuring a comfortable living environment.


Mobile homes, due to their compact nature and often less stringent building codes compared to traditional houses, are susceptible to certain indoor pollutants. One significant contributor to poor IAQ in these spaces is formaldehyde. This volatile organic compound (VOC) is released from various building materials used in mobile home construction, such as pressed wood products, adhesives, and insulation. Due to the smaller volume of air within mobile homes, formaldehyde concentrations can build up more quickly than in larger structures, potentially leading to respiratory issues and other health problems.


Another common pollutant found in mobile homes is mold. The limited space often results in inadequate ventilation systems that fail to effectively manage moisture levels. This situation creates an ideal breeding ground for mold growth, especially in areas like bathrooms or near water fixtures where humidity tends to accumulate. Mold spores can trigger allergic reactions and asthma attacks, particularly affecting children and those with preexisting respiratory conditions.


Additionally, carbon monoxide (CO) poses a significant threat to IAQ in mobile homes. Many units rely on gas-powered appliances for heating and cooking, which can emit CO if not properly maintained or ventilated. Given that mobile homes may not have advanced detection systems compared to permanent dwellings, occupants might be at greater risk of CO exposure-a colorless and odorless gas that can cause serious health effects or even be fatal at high concentrations.


Particulate matter (PM), including dust mites and pet dander, also plays a role in diminishing indoor air quality within mobile homes. With limited space often comes limited options for effective cleaning routines or advanced filtration systems that might otherwise reduce PM levels. This accumulation can deteriorate air quality over time, contributing to allergies and other respiratory concerns.


Addressing these issues requires both preventive measures during construction and proactive management by residents. For instance, opting for low-emission building materials can mitigate formaldehyde release. Ensuring adequate ventilation through exhaust fans or portable air purifiers helps control moisture levels and reduce mold risk. Regular maintenance of gas appliances alongside installing carbon monoxide detectors are crucial steps toward safeguarding against CO exposure.


In conclusion, while mobile homes offer affordable housing solutions for many individuals and families across the country, they present unique challenges concerning indoor air quality due to their design limitations and material choices. By identifying common pollutants like formaldehyde, mold spores, carbon monoxide, and particulate matter-and implementing appropriate mitigation strategies-residents can significantly enhance their living environment's safety and comfort.

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Types of Measurements Required in Mobile Home HVAC Checks

The impact of poor air circulation on health and comfort is a growing concern, particularly in the context of indoor environments where most people spend a significant portion of their time. Poor air circulation can exacerbate the presence of pollutants, which not only degrade air quality but also pose serious risks to human health and well-being.


One of the primary repercussions of inadequate air circulation is the accumulation of indoor pollutants. Without proper ventilation, substances such as volatile organic compounds (VOCs), mold spores, dust mites, and carbon dioxide can reach harmful levels. VOCs are emitted from common household items like paints, cleaning supplies, and even furniture. When these compounds build up due to poor ventilation, they can cause headaches, dizziness, respiratory irritation, and long-term health issues such as liver or kidney damage.


Mold is another significant pollutant that thrives in poorly ventilated spaces. Moisture-laden areas with insufficient airflow create ideal conditions for mold growth. Exposure to mold can lead to allergic reactions, asthma attacks, and other respiratory problems. Over time, chronic exposure may weaken the immune system and exacerbate pre-existing health conditions.


Furthermore, poor air circulation contributes to discomfort by affecting temperature regulation within a space. Stagnant air often results in uneven temperatures throughout a room or building. In warmer climates or during summer months, this lack of airflow can make spaces feel stuffy and oppressive. Conversely, during colder periods, it can lead to drafty conditions that undermine thermal comfort.


Moreover, compromised air circulation affects mental well-being and productivity. Studies have shown that stale indoor environments with high pollutant concentrations are linked to decreased cognitive function and increased fatigue among occupants. This impact is particularly evident in workplaces where employees report lower concentration levels and reduced work performance when exposed to suboptimal air quality.


To mitigate these effects on health and comfort, improving ventilation systems should be a priority. This could involve incorporating mechanical solutions like HVAC systems equipped with high-efficiency particulate air (HEPA) filters or ensuring natural ventilation through strategically placed windows or vents that promote cross-breezes.


In conclusion, the intricate relationship between poor air circulation and indoor pollutants underscores an urgent need for awareness and action towards better ventilation practices. By addressing these issues proactively through design improvements and regular maintenance checks on existing systems, we can significantly enhance both our immediate comfort levels as well as protect long-term health outcomes from the insidious impacts of polluted indoor environments.

Types of Measurements Required in Mobile Home HVAC Checks

Comparing Digital vs Analog Multimeters for HVAC Use

In recent years, the quality of indoor air has become a growing concern, particularly as we spend an increasing amount of time indoors. Central to this issue is the role of HVAC (Heating, Ventilation, and Air Conditioning) systems, which are responsible for maintaining indoor air quality and comfort. However, these systems can also be conduits for pollutants that affect air circulation within buildings. To ensure a healthy indoor environment, it is crucial to identify and measure these pollutants effectively.


HVAC systems can harbor a variety of pollutants ranging from particulate matter such as dust and pollen to volatile organic compounds (VOCs) emitted by cleaning products or furnishings. Biological contaminants like mold spores and bacteria can also proliferate within these systems if not maintained properly. Identifying these pollutants requires a strategic approach utilizing both technological tools and professional expertise.


One common method for identifying pollutants in HVAC systems is through the use of sensors designed to detect specific contaminants. These sensors can monitor air quality in real-time, providing data on concentrations of different pollutants such as carbon dioxide, VOCs, or particulates. Advanced sensors may even offer capabilities to identify biological contaminants by analyzing microbial DNA present in the air.


Another vital technique involves sampling methods where air samples are collected from various points within the HVAC system and analyzed in laboratories. This analysis often includes particle counting to quantify particulates or gas chromatography-mass spectrometry (GC-MS) to identify complex chemical compounds found in VOCs.


Regular inspections and maintenance checks are also critical in identifying potential pollutant sources before they become significant problems. Technicians trained in HVAC system maintenance use visual inspections alongside diagnostic tools like thermal imaging cameras to spot leaks or areas prone to moisture accumulation-a common precursor to mold growth.


Once identified, measuring the concentration levels of these pollutants is essential for assessing their impact on indoor air quality. This process often involves using calibrated instruments capable of providing precise measurements over time, facilitating trend analysis that can guide remediation efforts.


For instance, high levels of particulate matter might indicate inadequate filtration or ductwork issues requiring immediate attention. Elevated VOC readings could suggest off-gassing from new materials used within the building or poor ventilation practices needing adjustment.


Ultimately, integrating pollutant identification and measurement into routine HVAC maintenance protocols ensures cleaner air circulation and healthier indoor environments. By leveraging technology alongside professional expertise, building managers can proactively address potential threats posed by airborne contaminants-protecting occupants' health while enhancing overall comfort.


In conclusion, effective methods for identifying and measuring pollutants in HVAC systems are indispensable tools in our quest for improved indoor air quality. As awareness grows around this issue's importance amidst evolving environmental standards globally-it becomes ever more critical that we continue refining these techniques-ensuring that our living spaces remain safe havens free from harmful airborne intrusions.

Safety Considerations When Using Multimeters in Mobile Homes

Air circulation plays a crucial role in maintaining indoor air quality and ensuring a healthy living environment. However, various pollutants can adversely affect air circulation, leading to poor indoor air quality and associated health issues. To address these challenges, it is essential to examine the pollutants that impact air circulation and explore strategies to improve it while reducing these contaminants.


Pollutants affecting air circulation often originate from both outdoor and indoor sources. Common outdoor pollutants include particulate matter, vehicle emissions, industrial discharges, and pollen. Indoors, sources such as tobacco smoke, household cleaning products, building materials, and cooking fumes contribute significantly to deteriorating air quality. These pollutants can interfere with airflow by accumulating in ventilation systems or creating obstructions within spaces where air needs to circulate freely.


To enhance air circulation while minimizing pollutant levels, one effective strategy is to optimize ventilation systems. Properly designed and maintained ventilation systems help ensure consistent airflow throughout a building or home. Regular cleaning of ducts and filters is vital in preventing the buildup of dust and other particles that can hinder efficient airflow. Additionally, incorporating advanced filtration systems can capture finer particulates and allergens before they circulate indoors.


Another key approach involves leveraging natural ventilation whenever possible. Opening windows and doors allows for the exchange of indoor stale air with fresh outdoor air. This simple yet effective method can reduce concentrations of harmful pollutants indoors while promoting better airflow patterns. In climates where opening windows may not be feasible due to extreme temperatures or pollution levels outside, mechanical ventilation solutions equipped with heat recovery ventilators (HRVs) or energy recovery ventilators (ERVs) offer an alternative by providing fresh air without significant energy loss.


Indoor plants have also emerged as a natural solution for improving both air quality and circulation. Certain plant species are known for their ability to absorb airborne toxins through their leaves while simultaneously releasing oxygen into the environment-a process that enhances overall airflow dynamics within a space.


In addition to these strategies focused on improving physical aspects of buildings or homes themselves; behavioral changes play an important role too: encouraging non-smoking policies at home/workplaces reduces exposure risks dramatically; choosing low-emission paints/furnishings minimizes introduction new VOCs into environment; using eco-friendly cleaning agents helps limit release harsh chemicals into atmosphere thereby contributing healthier surroundings overall.


Ultimately-whether through technological innovations like smart sensors monitoring pollutant levels adjusting HVAC settings accordingly-or simply adopting more mindful habits aimed reducing unnecessary exposure harmful substances-we must continue striving create environments conducive optimal health well-being all occupants involved!

In recent years, the importance of indoor air quality has gained significant attention, prompting technological advances in HVAC systems designed to enhance air quality management. As urban environments grow more complex and the understanding of pollutants affecting air circulation expands, it becomes increasingly crucial to innovate solutions that ensure cleaner and healthier indoor environments. These technological strides are not only vital for comfort but are essential for public health.


The primary function of HVAC systems is to regulate temperature and airflow within buildings. However, modern requirements demand a broader focus on air purification as well. Pollutants such as volatile organic compounds (VOCs), particulate matter, mold spores, and microbial contaminants can significantly degrade indoor air quality. These elements originate from various sources including building materials, furnishings, cleaning agents, and outdoor pollution seeping indoors.


To combat these challenges, recent advancements in HVAC technology have introduced several innovative features aimed at improving air purification capabilities. One notable advancement is the integration of high-efficiency particulate air (HEPA) filters. These filters are capable of trapping up to 99.97% of particles as small as 0.3 microns, which includes dust mites, pollen, and even some bacteria and viruses. By incorporating HEPA filters into HVAC systems, airborne particulates can be effectively reduced.


Another breakthrough is the use of ultraviolet germicidal irradiation (UVGI) technology within HVAC ductwork or directly in rooms through standalone units. UVGI uses short-wavelength ultraviolet light to kill or inactivate microorganisms by destroying nucleic acids and disrupting their DNA. This method has proven effective against a range of pathogens including bacteria and viruses that contribute to poor indoor air quality.


Moreover, advanced ventilation control systems now utilize smart sensors that constantly monitor indoor air conditions such as humidity levels and concentrations of carbon dioxide or other pollutants. These sensors provide real-time data enabling automated adjustments to ventilation rates based on current needs rather than fixed schedules or manual operation alone.


Additionally, energy recovery ventilators (ERVs) have become more prevalent in modern HVAC designs due to their dual benefit: conserving energy while ensuring adequate ventilation with fresh outdoor air exchange without losing thermal comfort inside the building premises.


Looking ahead, further innovations are likely focused towards enhancing system efficiency through artificial intelligence algorithms capable of predicting environmental changes before they occur - adapting operational settings dynamically for optimal performance while minimizing energy consumption simultaneously.


As we continue examining pollutants affecting our everyday spaces' circulation patterns closely alongside leveraging cutting-edge technologies tailored specifically toward mitigating these adverse impacts effectively; it remains an ongoing mission striving towards achieving sustainable solutions fostering improved human health outcomes globally across diverse architectural landscapes worldwide driven primarily by innovative advancements witnessed within contemporary Heating Ventilation Air Conditioning sectors today!

A DuPont R-134a refrigerant

A refrigerant is a working fluid used in cooling, heating or reverse cooling and heating of air conditioning systems and heat pumps where they undergo a repeated phase transition from a liquid to a gas and back again. Refrigerants are heavily regulated because of their toxicity and flammability[1] and the contribution of CFC and HCFC refrigerants to ozone depletion[2] and that of HFC refrigerants to climate change.[3]

Refrigerants are used in a direct expansion (DX- Direct Expansion) system (circulating system)to transfer energy from one environment to another, typically from inside a building to outside (or vice versa) commonly known as an air conditioner cooling only or cooling & heating reverse DX system or heat pump a heating only DX cycle. Refrigerants can carry 10 times more energy per kg than water, and 50 times more than air.

Refrigerants are controlled substances and classified by International safety regulations ISO 817/5149, AHRAE 34/15 & BS EN 378 due to high pressures (700–1,000 kPa (100–150 psi)), extreme temperatures (−50 °C [−58 °F] to over 100 °C [212 °F]), flammability (A1 class non-flammable, A2/A2L class flammable and A3 class extremely flammable/explosive) and toxicity (B1-low, B2-medium & B3-high). The regulations relate to situations when these refrigerants are released into the atmosphere in the event of an accidental leak not while circulated.

Refrigerants (controlled substances) must only be handled by qualified/certified engineers for the relevant classes (in the UK, C&G 2079 for A1-class and C&G 6187-2 for A2/A2L & A3-class refrigerants).

Refrigerants (A1 class only) Due to their non-flammability, A1 class non-flammability, non-explosivity, and non-toxicity, non-explosivity they have been used in open systems (consumed when used) like fire extinguishers, inhalers, computer rooms fire extinguishing and insulation, etc.) since 1928.

History

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The observed stabilization of HCFC concentrations (left graphs) and the growth of HFCs (right graphs) in earth's atmosphere.

The first air conditioners and refrigerators employed toxic or flammable gases, such as ammonia, sulfur dioxide, methyl chloride, or propane, that could result in fatal accidents when they leaked.[4]

In 1928 Thomas Midgley Jr. created the first non-flammable, non-toxic chlorofluorocarbon gas, Freon (R-12). The name is a trademark name owned by DuPont (now Chemours) for any chlorofluorocarbon (CFC), hydrochlorofluorocarbon (HCFC), or hydrofluorocarbon (HFC) refrigerant. Following the discovery of better synthesis methods, CFCs such as R-11,[5] R-12,[6] R-123[5] and R-502[7] dominated the market.

Phasing out of CFCs

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See also: Montreal Protocol

In the mid-1970s, scientists discovered that CFCs were causing major damage to the ozone layer that protects the earth from ultraviolet radiation, and to the ozone holes over polar regions.[8][9] This led to the signing of the Montreal Protocol in 1987 which aimed to phase out CFCs and HCFC[10] but did not address the contributions that HFCs made to climate change. The adoption of HCFCs such as R-22,[11][12][13] and R-123[5] was accelerated and so were used in most U.S. homes in air conditioners and in chillers[14] from the 1980s as they have a dramatically lower Ozone Depletion Potential (ODP) than CFCs, but their ODP was still not zero which led to their eventual phase-out.

Hydrofluorocarbons (HFCs) such as R-134a,[15][16] R-407A,[17] R-407C,[18] R-404A,[7] R-410A[19] (a 50/50 blend of R-125/R-32) and R-507[20][21] were promoted as replacements for CFCs and HCFCs in the 1990s and 2000s. HFCs were not ozone-depleting but did have global warming potentials (GWPs) thousands of times greater than CO2 with atmospheric lifetimes that can extend for decades. This in turn, starting from the 2010s, led to the adoption in new equipment of Hydrocarbon and HFO (hydrofluoroolefin) refrigerants R-32,[22] R-290,[23] R-600a,[23] R-454B,[24] R-1234yf,[25][26] R-514A,[27] R-744 (CO2),[28] R-1234ze(E)[29] and R-1233zd(E),[30] which have both an ODP of zero and a lower GWP. Hydrocarbons and CO2 are sometimes called natural refrigerants because they can be found in nature.

The environmental organization Greenpeace provided funding to a former East German refrigerator company to research alternative ozone- and climate-safe refrigerants in 1992. The company developed a hydrocarbon mixture of propane and isobutane, or pure isobutane,[31] called "Greenfreeze", but as a condition of the contract with Greenpeace could not patent the technology, which led to widespread adoption by other firms.[32][33][34] Policy and political influence by corporate executives resisted change however,[35][36] citing the flammability and explosive properties of the refrigerants,[37] and DuPont together with other companies blocked them in the U.S. with the U.S. EPA.[38][39]

Beginning on 14 November 1994, the U.S. Environmental Protection Agency restricted the sale, possession and use of refrigerants to only licensed technicians, per rules under sections 608 and 609 of the Clean Air Act.[40] In 1995, Germany made CFC refrigerators illegal.[41]

In 1996 Eurammon, a European non-profit initiative for natural refrigerants, was established and comprises European companies, institutions, and industry experts.[42][43][44]

In 1997, FCs and HFCs were included in the Kyoto Protocol to the Framework Convention on Climate Change.

In 2000 in the UK, the Ozone Regulations[45] came into force which banned the use of ozone-depleting HCFC refrigerants such as R22 in new systems. The Regulation banned the use of R22 as a "top-up" fluid for maintenance from 2010 for virgin fluid and from 2015 for recycled fluid.[citation needed]

Addressing greenhouse gases

[edit]

With growing interest in natural refrigerants as alternatives to synthetic refrigerants such as CFCs, HCFCs and HFCs, in 2004, Greenpeace worked with multinational corporations like Coca-Cola and Unilever, and later Pepsico and others, to create a corporate coalition called Refrigerants Naturally!.[41][46] Four years later, Ben & Jerry's of Unilever and General Electric began to take steps to support production and use in the U.S.[47] It is estimated that almost 75 percent of the refrigeration and air conditioning sector has the potential to be converted to natural refrigerants.[48]

In 2006, the EU adopted a Regulation on fluorinated greenhouse gases (FCs and HFCs) to encourage to transition to natural refrigerants (such as hydrocarbons). It was reported in 2010 that some refrigerants are being used as recreational drugs, leading to an extremely dangerous phenomenon known as inhalant abuse.[49]

From 2011 the European Union started to phase out refrigerants with a global warming potential (GWP) of more than 150 in automotive air conditioning (GWP = 100-year warming potential of one kilogram of a gas relative to one kilogram of CO2) such as the refrigerant HFC-134a (known as R-134a in North America) which has a GWP of 1526.[50] In the same year the EPA decided in favour of the ozone- and climate-safe refrigerant for U.S. manufacture.[32][51][52]

A 2018 study by the nonprofit organization "Drawdown" put proper refrigerant management and disposal at the very top of the list of climate impact solutions, with an impact equivalent to eliminating over 17 years of US carbon dioxide emissions.[53]

In 2019 it was estimated that CFCs, HCFCs, and HFCs were responsible for about 10% of direct radiative forcing from all long-lived anthropogenic greenhouse gases.[54] and in the same year the UNEP published new voluntary guidelines,[55] however many countries have not yet ratified the Kigali Amendment.

From early 2020 HFCs (including R-404A, R-134a and R-410A) are being superseded: Residential air-conditioning systems and heat pumps are increasingly using R-32. This still has a GWP of more than 600. Progressive devices use refrigerants with almost no climate impact, namely R-290 (propane), R-600a (isobutane) or R-1234yf (less flammable, in cars). In commercial refrigeration also CO2 (R-744) can be used.

Requirements and desirable properties

[edit]

A refrigerant needs to have: a boiling point that is somewhat below the target temperature (although boiling point can be adjusted by adjusting the pressure appropriately), a high heat of vaporization, a moderate density in liquid form, a relatively high density in gaseous form (which can also be adjusted by setting pressure appropriately), and a high critical temperature. Working pressures should ideally be containable by copper tubing, a commonly available material. Extremely high pressures should be avoided.[citation needed]

The ideal refrigerant would be: non-corrosive, non-toxic, non-flammable, with no ozone depletion and global warming potential. It should preferably be natural with well-studied and low environmental impact. Newer refrigerants address the issue of the damage that CFCs caused to the ozone layer and the contribution that HCFCs make to climate change, but some do raise issues relating to toxicity and/or flammability.[56]

Common refrigerants

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Refrigerants with very low climate impact

[edit]

With increasing regulations, refrigerants with a very low global warming potential are expected to play a dominant role in the 21st century,[57] in particular, R-290 and R-1234yf. Starting from almost no market share in 2018,[58] low GWPO devices are gaining market share in 2022.

Code Chemical Name GWP 20yr[59] GWP 100yr[59] Status Commentary
R-290 C3H8 Propane   3.3[60] Increasing use Low cost, widely available and efficient. They also have zero ozone depletion potential. Despite their flammability, they are increasingly used in domestic refrigerators and heat pumps. In 2010, about one-third of all household refrigerators and freezers manufactured globally used isobutane or an isobutane/propane blend, and this was expected to increase to 75% by 2020.[61]
R-600a HC(CH3)3 Isobutane   3.3 Widely used See R-290.
R-717 NH3 Ammonia 0 0[62] Widely used Commonly used before the popularisation of CFCs, it is again being considered but does suffer from the disadvantage of toxicity, and it requires corrosion-resistant components, which restricts its domestic and small-scale use. Anhydrous ammonia is widely used in industrial refrigeration applications and hockey rinks because of its high energy efficiency and low cost.
R-1234yf HFO-1234yf C3H2F4 2,3,3,3-Tetrafluoropropene   <1   Less performance but also less flammable than R-290.[57] GM announced that it would start using "hydro-fluoro olefin", HFO-1234yf, in all of its brands by 2013.[63]
R-744 CO2 Carbon dioxide 1 1 In use Was used as a refrigerant prior to the discovery of CFCs (this was also the case for propane)[4] and now having a renaissance due to it being non-ozone depleting, non-toxic and non-flammable. It may become the working fluid of choice to replace current HFCs in cars, supermarkets, and heat pumps. Coca-Cola has fielded CO2-based beverage coolers and the U.S. Army is considering CO2 refrigeration.[64][65] Due to the need to operate at pressures of up to 130 bars (1,900 psi; 13,000 kPa), CO2 systems require highly resistant components, however these have already been developed for mass production in many sectors.

Most used

[edit]
Code Chemical Name Global warming potential 20yr[59] GWP 100yr[59] Status Commentary
R-32 HFC-32 CH2F2 Difluoromethane 2430 677 Widely used Promoted as climate-friendly substitute for R-134a and R-410A, but still with high climate impact. Has excellent heat transfer and pressure drop performance, both in condensation and vaporisation.[66] It has an atmospheric lifetime of nearly 5 years.[67] Currently used in residential and commercial air-conditioners and heat pumps.
R-134a HFC-134a CH2FCF3 1,1,1,2-Tetrafluoroethane 3790 1550 Widely used Most used in 2020 for hydronic heat pumps in Europe and the United States in spite of high GWP.[58] Commonly used in automotive air conditioners prior to phase out which began in 2012.
R-410A   50% R-32 / 50% R-125 (pentafluoroethane) Between 2430 (R-32) and 6350 (R-125) > 677 Widely Used Most used in split heat pumps / AC by 2018. Almost 100% share in the USA.[58] Being phased out in the US starting in 2022.[68][69]

Banned / Phased out

[edit]
Code Chemical Name Global warming potential 20yr[59] GWP 100yr[59] Status Commentary
R-11 CFC-11 CCl3F Trichlorofluoromethane 6900 4660 Banned Production was banned in developed countries by Montreal Protocol in 1996
R-12 CFC-12 CCl2F2 Dichlorodifluoromethane 10800 10200 Banned Also known as Freon, a widely used chlorofluorocarbon halomethane (CFC). Production was banned in developed countries by Montreal Protocol in 1996, and in developing countries (article 5 countries) in 2010.[70]
R-22 HCFC-22 CHClF2 Chlorodifluoromethane 5280 1760 Being phased out A widely used hydrochlorofluorocarbon (HCFC) and powerful greenhouse gas with a GWP equal to 1810. Worldwide production of R-22 in 2008 was about 800 Gg per year, up from about 450 Gg per year in 1998. R-438A (MO-99) is a R-22 replacement.[71]
R-123 HCFC-123 CHCl2CF3 2,2-Dichloro-1,1,1-trifluoroethane 292 79 US phase-out Used in large tonnage centrifugal chiller applications. All U.S. production and import of virgin HCFCs will be phased out by 2030, with limited exceptions.[72] R-123 refrigerant was used to retrofit some chiller that used R-11 refrigerant Trichlorofluoromethane. The production of R-11 was banned in developed countries by Montreal Protocol in 1996.[73]

Other

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Code Chemical Name Global warming potential 20yr[59] GWP 100yr[59] Commentary
R-152a HFC-152a CH3CHF2 1,1-Difluoroethane 506 138 As a compressed air duster
R-407C   Mixture of difluoromethane and pentafluoroethane and 1,1,1,2-tetrafluoroethane     A mixture of R-32, R-125, and R-134a
R-454B   Difluoromethane and 2,3,3,3-Tetrafluoropropene     HFOs blend of refrigerants Difluoromethane (R-32) and 2,3,3,3-Tetrafluoropropene (R-1234yf).[74][75][76][77]
R-513A   An HFO/HFC blend (56% R-1234yf/44%R-134a)     May replace R-134a as an interim alternative[78]
R-514A   HFO-1336mzz-Z/trans-1,2- dichloroethylene (t-DCE)     An hydrofluoroolefin (HFO)-based refrigerant to replace R-123 in low pressure centrifugal chillers for commercial and industrial applications.[79][80]

Refrigerant reclamation and disposal

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Main article: Refrigerant reclamation

Coolant and refrigerants are found throughout the industrialized world, in homes, offices, and factories, in devices such as refrigerators, air conditioners, central air conditioning systems (HVAC), freezers, and dehumidifiers. When these units are serviced, there is a risk that refrigerant gas will be vented into the atmosphere either accidentally or intentionally, hence the creation of technician training and certification programs in order to ensure that the material is conserved and managed safely. Mistreatment of these gases has been shown to deplete the ozone layer and is suspected to contribute to global warming.[81]

With the exception of isobutane and propane (R600a, R441A and R290), ammonia and CO2 under Section 608 of the United States' Clean Air Act it is illegal to knowingly release any refrigerants into the atmosphere.[82][83]

Refrigerant reclamation is the act of processing used refrigerant gas which has previously been used in some type of refrigeration loop such that it meets specifications for new refrigerant gas. In the United States, the Clean Air Act of 1990 requires that used refrigerant be processed by a certified reclaimer, which must be licensed by the United States Environmental Protection Agency (EPA), and the material must be recovered and delivered to the reclaimer by EPA-certified technicians.[84]

Classification of refrigerants

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R407C pressure-enthalpy diagram, isotherms between the two saturation lines
Main article: List of refrigerants

Refrigerants may be divided into three classes according to their manner of absorption or extraction of heat from the substances to be refrigerated:[citation needed]

  • Class 1: This class includes refrigerants that cool by phase change (typically boiling), using the refrigerant's latent heat.
  • Class 2: These refrigerants cool by temperature change or 'sensible heat', the quantity of heat being the specific heat capacity x the temperature change. They are air, calcium chloride brine, sodium chloride brine, alcohol, and similar nonfreezing solutions. The purpose of Class 2 refrigerants is to receive a reduction of temperature from Class 1 refrigerants and convey this lower temperature to the area to be cooled.
  • Class 3: This group consists of solutions that contain absorbed vapors of liquefiable agents or refrigerating media. These solutions function by nature of their ability to carry liquefiable vapors, which produce a cooling effect by the absorption of their heat of solution. They can also be classified into many categories.

R numbering system

[edit]

The R- numbering system was developed by DuPont (which owned the Freon trademark), and systematically identifies the molecular structure of refrigerants made with a single halogenated hydrocarbon. ASHRAE has since set guidelines for the numbering system as follows:[85]

R-X1X2X3X4

  • X1 = Number of unsaturated carbon-carbon bonds (omit if zero)
  • X2 = Number of carbon atoms minus 1 (omit if zero)
  • X3 = Number of hydrogen atoms plus 1
  • X4 = Number of fluorine atoms

Series

[edit]
  • R-xx Methane Series
  • R-1xx Ethane Series
  • R-2xx Propane Series
  • R-4xx Zeotropic blend
  • R-5xx Azeotropic blend
  • R-6xx Saturated hydrocarbons (except for propane which is R-290)
  • R-7xx Inorganic Compounds with a molar mass < 100
  • R-7xxx Inorganic Compounds with a molar mass ≥ 100

Ethane Derived Chains

[edit]
  • Number Only Most symmetrical isomer
  • Lower Case Suffix (a, b, c, etc.) indicates increasingly unsymmetrical isomers

Propane Derived Chains

[edit]
  • Number Only If only one isomer exists; otherwise:
  • First lower case suffix (a-f):
    • a Suffix Cl2 central carbon substitution
    • b Suffix Cl, F central carbon substitution
    • c Suffix F2 central carbon substitution
    • d Suffix Cl, H central carbon substitution
    • e Suffix F, H central carbon substitution
    • f Suffix H2 central carbon substitution
  • 2nd Lower Case Suffix (a, b, c, etc.) Indicates increasingly unsymmetrical isomers

Propene derivatives

[edit]
  • First lower case suffix (x, y, z):
    • x Suffix Cl substitution on central atom
    • y Suffix F substitution on central atom
    • z Suffix H substitution on central atom
  • Second lower case suffix (a-f):
    • a Suffix =CCl2 methylene substitution
    • b Suffix =CClF methylene substitution
    • c Suffix =CF2 methylene substitution
    • d Suffix =CHCl methylene substitution
    • e Suffix =CHF methylene substitution
    • f Suffix =CH2 methylene substitution

Blends

[edit]
  • Upper Case Suffix (A, B, C, etc.) Same blend with different compositions of refrigerants

Miscellaneous

[edit]
  • R-Cxxx Cyclic compound
  • R-Exxx Ether group is present
  • R-CExxx Cyclic compound with an ether group
  • R-4xx/5xx + Upper Case Suffix (A, B, C, etc.) Same blend with different composition of refrigerants
  • R-6xx + Lower Case Letter Indicates increasingly unsymmetrical isomers
  • 7xx/7xxx + Upper Case Letter Same molar mass, different compound
  • R-xxxxB# Bromine is present with the number after B indicating how many bromine atoms
  • R-xxxxI# Iodine is present with the number after I indicating how many iodine atoms
  • R-xxx(E) Trans Molecule
  • R-xxx(Z) Cis Molecule

For example, R-134a has 2 carbon atoms, 2 hydrogen atoms, and 4 fluorine atoms, an empirical formula of tetrafluoroethane. The "a" suffix indicates that the isomer is unbalanced by one atom, giving 1,1,1,2-Tetrafluoroethane. R-134 (without the "a" suffix) would have a molecular structure of 1,1,2,2-Tetrafluoroethane.

The same numbers are used with an R- prefix for generic refrigerants, with a "Propellant" prefix (e.g., "Propellant 12") for the same chemical used as a propellant for an aerosol spray, and with trade names for the compounds, such as "Freon 12". Recently, a practice of using abbreviations HFC- for hydrofluorocarbons, CFC- for chlorofluorocarbons, and HCFC- for hydrochlorofluorocarbons has arisen, because of the regulatory differences among these groups.[citation needed]

Refrigerant safety

[edit]

ASHRAE Standard 34, Designation and Safety Classification of Refrigerants, assigns safety classifications to refrigerants based upon toxicity and flammability.

Using safety information provided by producers, ASHRAE assigns a capital letter to indicate toxicity and a number to indicate flammability. The letter "A" is the least toxic and the number 1 is the least flammable.[86]

See also

[edit]
  • Brine (Refrigerant)
  • Section 608
  • List of Refrigerants

References

[edit]
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  6. ^ https://asrjetsjournal.org/index.php/American_Scientific_Journal/article/download/3297/1244/
  7. ^ a b Tomczyk, John (1 May 2017). "What's the Latest with R-404A?". achrnews.com.
  8. ^ Molina, Mario J.; Rowland, F. S (28 June 1974). "Stratospheric sink for chlorofluoromethanes: chlorine catalysed destruction of ozone" (PDF). Nature. 249: 810–812. doi:10.1038/249810a0. Retrieved October 6, 2024.
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  26. ^ Kontomaris, Konstantinos (2014). "HFO-1336mzz-Z: High Temperature Chemical Stability and Use as A Working Fluid in Organic Rankine Cycles". International Refrigeration and Air Conditioning Conference. Paper 1525
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  29. ^ "Carrier expands R1234ze chiller range". Cooling Post. 20 May 2020.
  30. ^ "Carrier confirms an HFO refrigerant future". Cooling Post. 5 June 2019.
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  36. ^ Benedick, Richard Elliot Ozone Diplomacy Cambridge, MA: Harvard University 1991.
  37. ^ Honeywell International, Inc. (2010-07-09). "Comment on EPA Proposed Rule Office of Air and Radiation Proposed Significant New Alternatives Policy (SNAP) Protection of Stratospheric Ozone: Listing of Substitutes for Ozone-Depleting Substances – Hydrocarbon Refrigerants" (PDF).
  38. ^ "Discurso de Frank Guggenheim no lançamento do Greenfreeze | Brasil". Greenpeace.org. Archived from the original on 24 September 2015. Retrieved 10 June 2015.
  39. ^ "Der Greenfreeze - endlich in den USA angekommen". Greenpeace.de (in German). 28 December 2011. Retrieved 10 June 2015.
  40. ^ "Complying With The Section 608 Refrigerant Recycling Rule | Ozone Layer Protection - Regulatory Programs". Epa.gov. 21 April 2015. Retrieved 10 June 2015.
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  42. ^ "Company background". Archived from the original on 2020-02-20. Retrieved 2021-03-15.
  43. ^ Safeguarding the ozone layer and the global climate System: issues related to Hydrofluorocarbons and Perfluorocarbons (Report). IPCC/TEAP. 2005.
  44. ^ Crowley, Thomas J. (2000). "Causes of Climate Change over the Past 1000 Years". Science. 289 (5477): 270–277. Bibcode:2000Sci...289..270C. doi:10.1126/science.289.5477.270. PMID 10894770.
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  47. ^ "Climate-Friendly Greenfreezers Come to the United States". WNBC. 2 October 2008. Retrieved 8 June 2015.
  48. ^ Data, Reports and (7 August 2020). "Natural Refrigerants Market To Reach USD 2.88 Billion By 2027 | Reports and Data". GlobeNewswire News Room (Press release). Retrieved 17 December 2020.
  49. ^ Harris, Catharine. "Anti-inhalant Abuse Campaign Targets Building Codes: 'Huffing’ of Air Conditioning Refrigerant a Dangerous Risk." The Nation's Health. American Public Health Association, 2010. Web. 5 December 2010. https://www.thenationshealth.org/content/39/4/20
  50. ^ IPCC AR6 WG1 Ch7 2021
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  53. ^ Berwald, Juli (29 April 2019). "One overlooked way to fight climate change? Dispose of old CFCs". National Geographic - Environment. Archived from the original on April 29, 2019. Retrieved 30 April 2019.
  54. ^ Butler J. and Montzka S. (2020). "The NOAA Annual Greenhouse Gas Index (AGGI)". NOAA Global Monitoring Laboratory/Earth System Research Laboratories.
  55. ^ Environment, U. N. (31 October 2019). "New guidelines for air conditioners and refrigerators set to tackle climate change". UN Environment. Retrieved 30 March 2020.
  56. ^ Rosenthal, Elisabeth; Lehren, Andrew (20 June 2011). "Relief in Every Window, but Global Worry Too". The New York Times. Retrieved 21 June 2012.
  57. ^ a b Yadav et al 2022
  58. ^ a b c BSRIA 2020
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  60. ^ "European Commission on retrofit refrigerants for stationary applications" (PDF). Archived from the original on August 5, 2009. Retrieved 2010-10-29.cite web: CS1 maint: unfit URL (link)
  61. ^ "Protection of Stratospheric Ozone: Hydrocarbon Refrigerants" (PDF). Environment Protection Agency. Retrieved 5 August 2018.
  62. ^ ARB 2022
  63. ^ GM to Introduce HFO-1234yf AC Refrigerant in 2013 US Models
  64. ^ "The Coca-Cola Company Announces Adoption of HFC-Free Insulation in Refrigeration Units to Combat Global Warming". The Coca-Cola Company. 5 June 2006. Archived from the original on 1 November 2013. Retrieved 11 October 2007.
  65. ^ "Modine reinforces its CO2 research efforts". R744.com. 28 June 2007. Archived from the original on 10 February 2008.
  66. ^ Longo, Giovanni A.; Mancin, Simone; Righetti, Giulia; Zilio, Claudio (2015). "HFC32 vaporisation inside a Brazed Plate Heat Exchanger (BPHE): Experimental measurements and IR thermography analysis". International Journal of Refrigeration. 57: 77–86. doi:10.1016/j.ijrefrig.2015.04.017.
  67. ^ May 2010 TEAP XXI/9 Task Force Report
  68. ^ "Protecting Our Climate by Reducing Use of HFCs". US Environmental Protection Agency. 8 February 2021. Retrieved 25 August 2022.
  69. ^ "Background on HFCs and the AIM Act". www.usepa.gov. US EPA. March 2021. Retrieved 27 June 2024.
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  71. ^ [1] Chemours M099 as R22 Replacement
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  73. ^ [3] Refrigerant R11 (R-11), Freon 11 (Freon R-11) Properties & Replacement
  74. ^ [4] R-454B XL41 refrigerant fact & info sheet
  75. ^ [5] R-454B emerges as a replacement for R-410A | ACHR News (Air Conditioning, Heating, Refrigeration News)
  76. ^ [6] Ccarrier introduces [R-454B] Puron Advance™ as the next generation refrigerant for ducted residential, light commercial products in North America | Indianapolis - 19 December 2018
  77. ^ [7] Johnson Controls selects R-454B as future refrigerant for new HVAC equipment | 27 May 2021
  78. ^ [8] A conversation on refrigerants | ASHRAE Journal, March 2021 | page 30, column 1, paragraph 2
  79. ^ [9] Opteon™ XP30 (R-514A) refrigerant
  80. ^ [10] Trane adopts new low GWP refrigerant R514A | 15 June 2016
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  85. ^ ASHRAE; UNEP (Nov 2022). "Designation and Safety Classification of Refrigerants" (PDF). ASHRAE. Retrieved 1 July 2023.
  86. ^ "Update on New Refrigerants Designations and Safety Classifications" (PDF). American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE). April 2020. Archived from the original (PDF) on February 13, 2023. Retrieved October 22, 2022.
 

Sources

[edit]

IPCC reports

[edit]
  • IPCC (2013). Stocker, T. F.; Qin, D.; Plattner, G.-K.; Tignor, M.; et al. (eds.). Climate Change 2013: The Physical Science Basis (PDF). Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, United Kingdom and New York, NY, USA: Cambridge University Press. ISBN 978-1-107-05799-9. (pb: 978-1-107-66182-0). Fifth Assessment Report - Climate Change 2013
    • Myhre, G.; Shindell, D.; Bréon, F.-M.; Collins, W.; et al. (2013). "Chapter 8: Anthropogenic and Natural Radiative Forcing" (PDF). Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. pp. 659–740.
  • IPCC (2021). Masson-Delmotte, V.; Zhai, P.; Pirani, A.; Connors, S. L.; et al. (eds.). Climate Change 2021: The Physical Science Basis (PDF). Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press (In Press).
  • Forster, Piers; Storelvmo, Trude (2021). "Chapter 7: The Earth's Energy Budget, Climate Feedbacks, and Climate Sensitivity" (PDF). IPCC AR6 WG1 2021.

Other

[edit]
  • "High GWP refrigerants". California Air Resources Board. Retrieved 13 February 2022.
  • "BSRIA's view on refrigerant trends in AC and Heat Pump segments". 2020. Retrieved 2022-02-14.
  • Yadav, Saurabh; Liu, Jie; Kim, Sung Chul (2022). "A comprehensive study on 21st-century refrigerants - R290 and R1234yf: A review". International Journal of Heat and Mass Transfer. 122: 121947. Bibcode:2022IJHMT.18221947Y. doi:10.1016/j.ijheatmasstransfer.2021.121947. S2CID 240534198.
[edit]
  • US Environmental Protection Agency page on the GWPs of various substances
  • Green Cooling Initiative on alternative natural refrigerants cooling technologies
  • International Institute of Refrigeration Archived 2018-09-25 at the Wayback Machine
 

 

This article is about cooling of air. For the Curved Air album, see Air Conditioning (album). For a similar device capable of both cooling and heating, see heat pump.
"a/c" redirects here. For the abbreviation used in banking and book-keeping, see Account (disambiguation). For other uses, see AC.

 

There are various types of air conditioners. Popular examples include: Window-mounted air conditioner (Suriname, 1955); Ceiling-mounted cassette air conditioner (China, 2023); Wall-mounted air conditioner (Japan, 2020); Ceiling-mounted console (Also called ceiling suspended) air conditioner (China, 2023); and portable air conditioner (Vatican City, 2018).

 

Air conditioning, often abbreviated as A/C (US) or air con (UK),[1] is the process of removing heat from an enclosed space to achieve a more comfortable interior temperature (sometimes referred to as 'comfort cooling') and in some cases also strictly controlling the humidity of internal air. Air conditioning can be achieved using a mechanical 'air conditioner' or by other methods, including passive cooling and ventilative cooling.[2][3] Air conditioning is a member of a family of systems and techniques that provide heating, ventilation, and air conditioning (HVAC).[4] Heat pumps are similar in many ways to air conditioners, but use a reversing valve to allow them both to heat and to cool an enclosed space.[5]

Air conditioners, which typically use vapor-compression refrigeration, range in size from small units used in vehicles or single rooms to massive units that can cool large buildings.[6] Air source heat pumps, which can be used for heating as well as cooling, are becoming increasingly common in cooler climates.

Air conditioners can reduce mortality rates due to higher temperature.[7] According to the International Energy Agency (IEA) 1.6 billion air conditioning units were used globally in 2016.[8] The United Nations called for the technology to be made more sustainable to mitigate climate change and for the use of alternatives, like passive cooling, evaporative cooling, selective shading, windcatchers, and better thermal insulation.

History

[edit]

Air conditioning dates back to prehistory.[9] Double-walled living quarters, with a gap between the two walls to encourage air flow, were found in the ancient city of Hamoukar, in modern Syria.[10] Ancient Egyptian buildings also used a wide variety of passive air-conditioning techniques.[11] These became widespread from the Iberian Peninsula through North Africa, the Middle East, and Northern India.[12]

Passive techniques remained widespread until the 20th century when they fell out of fashion and were replaced by powered air conditioning. Using information from engineering studies of traditional buildings, passive techniques are being revived and modified for 21st-century architectural designs.[13][12]

An array of air conditioner condenser units outside a commercial office building

Air conditioners allow the building's indoor environment to remain relatively constant, largely independent of changes in external weather conditions and internal heat loads. They also enable deep plan buildings to be created and have allowed people to live comfortably in hotter parts of the world.[14]

Development

[edit]

Preceding discoveries

[edit]

In 1558, Giambattista della Porta described a method of chilling ice to temperatures far below its freezing point by mixing it with potassium nitrate (then called "nitre") in his popular science book Natural Magic.[15][16][17] In 1620, Cornelis Drebbel demonstrated "Turning Summer into Winter" for James I of England, chilling part of the Great Hall of Westminster Abbey with an apparatus of troughs and vats.[18] Drebbel's contemporary Francis Bacon, like della Porta a believer in science communication, may not have been present at the demonstration, but in a book published later the same year, he described it as "experiment of artificial freezing" and said that "Nitre (or rather its spirit) is very cold, and hence nitre or salt when added to snow or ice intensifies the cold of the latter, the nitre by adding to its cold, but the salt by supplying activity to the cold of the snow."[15]

In 1758, Benjamin Franklin and John Hadley, a chemistry professor at the University of Cambridge, conducted experiments applying the principle of evaporation as a means to cool an object rapidly. Franklin and Hadley confirmed that the evaporation of highly volatile liquids (such as alcohol and ether) could be used to drive down the temperature of an object past the freezing point of water. They experimented with the bulb of a mercury-in-glass thermometer as their object. They used a bellows to speed up the evaporation. They lowered the temperature of the thermometer bulb down to −14 °C (7 °F) while the ambient temperature was 18 °C (64 °F). Franklin noted that soon after they passed the freezing point of water 0 °C (32 °F), a thin film of ice formed on the surface of the thermometer's bulb and that the ice mass was about 6 mm (14 in) thick when they stopped the experiment upon reaching −14 °C (7 °F). Franklin concluded: "From this experiment, one may see the possibility of freezing a man to death on a warm summer's day."[19]

The 19th century included many developments in compression technology. In 1820, English scientist and inventor Michael Faraday discovered that compressing and liquefying ammonia could chill air when the liquefied ammonia was allowed to evaporate.[20] In 1842, Florida physician John Gorrie used compressor technology to create ice, which he used to cool air for his patients in his hospital in Apalachicola, Florida. He hoped to eventually use his ice-making machine to regulate the temperature of buildings.[20][21] He envisioned centralized air conditioning that could cool entire cities. Gorrie was granted a patent in 1851,[22] but following the death of his main backer, he was not able to realize his invention.[23] In 1851, James Harrison created the first mechanical ice-making machine in Geelong, Australia, and was granted a patent for an ether vapor-compression refrigeration system in 1855 that produced three tons of ice per day.[24] In 1860, Harrison established a second ice company. He later entered the debate over competing against the American advantage of ice-refrigerated beef sales to the United Kingdom.[24]

First devices

[edit]
Willis Carrier, who is credited with building the first modern electrical air conditioning unit

Electricity made the development of effective units possible. In 1901, American inventor Willis H. Carrier built what is considered the first modern electrical air conditioning unit.[25][26][27][28] In 1902, he installed his first air-conditioning system, in the Sackett-Wilhelms Lithographing & Publishing Company in Brooklyn, New York.[29] His invention controlled both the temperature and humidity, which helped maintain consistent paper dimensions and ink alignment at the printing plant. Later, together with six other employees, Carrier formed The Carrier Air Conditioning Company of America, a business that in 2020 employed 53,000 people and was valued at $18.6 billion.[30][31]

In 1906, Stuart W. Cramer of Charlotte, North Carolina, was exploring ways to add moisture to the air in his textile mill. Cramer coined the term "air conditioning" in a patent claim which he filed that year, where he suggested that air conditioning was analogous to "water conditioning", then a well-known process for making textiles easier to process.[32] He combined moisture with ventilation to "condition" and change the air in the factories; thus, controlling the humidity that is necessary in textile plants. Willis Carrier adopted the term and incorporated it into the name of his company.[33]

Domestic air conditioning soon took off. In 1914, the first domestic air conditioning was installed in Minneapolis in the home of Charles Gilbert Gates. It is, however, possible that the considerable device (c. 2.1 m × 1.8 m × 6.1 m; 7 ft × 6 ft × 20 ft) was never used, as the house remained uninhabited[20] (Gates had already died in October 1913.)

In 1931, H.H. Schultz and J.Q. Sherman developed what would become the most common type of individual room air conditioner: one designed to sit on a window ledge. The units went on sale in 1932 at US$10,000 to $50,000 (the equivalent of $200,000 to $1,100,000 in 2023.)[20] A year later, the first air conditioning systems for cars were offered for sale.[34] Chrysler Motors introduced the first practical semi-portable air conditioning unit in 1935,[35] and Packard became the first automobile manufacturer to offer an air conditioning unit in its cars in 1939.[36]

Further development

[edit]

Innovations in the latter half of the 20th century allowed more ubiquitous air conditioner use. In 1945, Robert Sherman of Lynn, Massachusetts, invented a portable, in-window air conditioner that cooled, heated, humidified, dehumidified, and filtered the air.[37] The first inverter air conditioners were released in 1980–1981.[38][39]

In 1954, Ned Cole, a 1939 architecture graduate from the University of Texas at Austin, developed the first experimental "suburb" with inbuilt air conditioning in each house. 22 homes were developed on a flat, treeless track in northwest Austin, Texas, and the community was christened the 'Austin Air-Conditioned Village.' The residents were subjected to a year-long study of the effects of air conditioning led by the nation’s premier air conditioning companies, builders, and social scientists. In addition, researchers from UT’s Health Service and Psychology Department studied the effects on the "artificially cooled humans." One of the more amusing discoveries was that each family reported being troubled with scorpions, the leading theory being that scorpions sought cool, shady places. Other reported changes in lifestyle were that mothers baked more, families ate heavier foods, and they were more apt to choose hot drinks.[40][41]

Air conditioner adoption tends to increase above around $10,000 annual household income in warmer areas.[42] Global GDP growth explains around 85% of increased air condition adoption by 2050, while the remaining 15% can be explained by climate change.[42]

As of 2016 an estimated 1.6 billion air conditioning units were used worldwide, with over half of them in China and USA, and a total cooling capacity of 11,675 gigawatts.[8][43] The International Energy Agency predicted in 2018 that the number of air conditioning units would grow to around 4 billion units by 2050 and that the total cooling capacity would grow to around 23,000 GW, with the biggest increases in India and China.[8] Between 1995 and 2004, the proportion of urban households in China with air conditioners increased from 8% to 70%.[44] As of 2015, nearly 100 million homes, or about 87% of US households, had air conditioning systems.[45] In 2019, it was estimated that 90% of new single-family homes constructed in the US included air conditioning (ranging from 99% in the South to 62% in the West).[46][47]

Operation

[edit]

Operating principles

[edit]
Main article: Vapor-compression refrigeration
A simple stylized diagram of the refrigeration cycle: 1) condensing coil, 2) expansion valve, 3) evaporator coil, 4) compressor

Cooling in traditional air conditioner systems is accomplished using the vapor-compression cycle, which uses a refrigerant's forced circulation and phase change between gas and liquid to transfer heat.[48][49] The vapor-compression cycle can occur within a unitary, or packaged piece of equipment; or within a chiller that is connected to terminal cooling equipment (such as a fan coil unit in an air handler) on its evaporator side and heat rejection equipment such as a cooling tower on its condenser side. An air source heat pump shares many components with an air conditioning system, but includes a reversing valve, which allows the unit to be used to heat as well as cool a space.[50]

Air conditioning equipment will reduce the absolute humidity of the air processed by the system if the surface of the evaporator coil is significantly cooler than the dew point of the surrounding air. An air conditioner designed for an occupied space will typically achieve a 30% to 60% relative humidity in the occupied space.[51]

Most modern air-conditioning systems feature a dehumidification cycle during which the compressor runs. At the same time, the fan is slowed to reduce the evaporator temperature and condense more water. A dehumidifier uses the same refrigeration cycle but incorporates both the evaporator and the condenser into the same air path; the air first passes over the evaporator coil, where it is cooled[52] and dehumidified before passing over the condenser coil, where it is warmed again before it is released back into the room.[citation needed]

Free cooling can sometimes be selected when the external air is cooler than the internal air. Therefore, the compressor does not need to be used, resulting in high cooling efficiencies for these times. This may also be combined with seasonal thermal energy storage.[53]

Heating

[edit]
Main article: Heat pump

Some air conditioning systems can reverse the refrigeration cycle and act as an air source heat pump, thus heating instead of cooling the indoor environment. They are also commonly referred to as "reverse cycle air conditioners". The heat pump is significantly more energy-efficient than electric resistance heating, because it moves energy from air or groundwater to the heated space and the heat from purchased electrical energy. When the heat pump is in heating mode, the indoor evaporator coil switches roles and becomes the condenser coil, producing heat. The outdoor condenser unit also switches roles to serve as the evaporator and discharges cold air (colder than the ambient outdoor air).

Most air source heat pumps become less efficient in outdoor temperatures lower than 4 °C or 40 °F.[54] This is partly because ice forms on the outdoor unit's heat exchanger coil, which blocks air flow over the coil. To compensate for this, the heat pump system must temporarily switch back into the regular air conditioning mode to switch the outdoor evaporator coil back to the condenser coil, to heat up and defrost. Therefore, some heat pump systems will have electric resistance heating in the indoor air path that is activated only in this mode to compensate for the temporary indoor air cooling, which would otherwise be uncomfortable in the winter.

Newer models have improved cold-weather performance, with efficient heating capacity down to −14 °F (−26 °C).[55][54][56] However, there is always a chance that the humidity that condenses on the heat exchanger of the outdoor unit could freeze, even in models that have improved cold-weather performance, requiring a defrosting cycle to be performed.

The icing problem becomes much more severe with lower outdoor temperatures, so heat pumps are sometimes installed in tandem with a more conventional form of heating, such as an electrical heater, a natural gas, heating oil, or wood-burning fireplace or central heating, which is used instead of or in addition to the heat pump during harsher winter temperatures. In this case, the heat pump is used efficiently during milder temperatures, and the system is switched to the conventional heat source when the outdoor temperature is lower.

Performance

[edit]
Main articles: coefficient of performance, Seasonal energy efficiency ratio, and European seasonal energy efficiency ratio

The coefficient of performance (COP) of an air conditioning system is a ratio of useful heating or cooling provided to the work required.[57][58] Higher COPs equate to lower operating costs. The COP usually exceeds 1; however, the exact value is highly dependent on operating conditions, especially absolute temperature and relative temperature between sink and system, and is often graphed or averaged against expected conditions.[59] Air conditioner equipment power in the U.S. is often described in terms of "tons of refrigeration", with each approximately equal to the cooling power of one short ton (2,000 pounds (910 kg) of ice melting in a 24-hour period. The value is equal to 12,000 BTUIT per hour, or 3,517 watts.[60] Residential central air systems are usually from 1 to 5 tons (3.5 to 18 kW) in capacity.[citation needed]

The efficiency of air conditioners is often rated by the seasonal energy efficiency ratio (SEER), which is defined by the Air Conditioning, Heating and Refrigeration Institute in its 2008 standard AHRI 210/240, Performance Rating of Unitary Air-Conditioning and Air-Source Heat Pump Equipment.[61] A similar standard is the European seasonal energy efficiency ratio (ESEER).[citation needed]

Efficiency is strongly affected by the humidity of the air to be cooled. Dehumidifying the air before attempting to cool it can reduce subsequent cooling costs by as much as 90 percent. Thus, reducing dehumidifying costs can materially affect overall air conditioning costs.[62]

Control system

[edit]

Wireless remote control

[edit]
Main articles: Remote control and Infrared blaster
A wireless remote controller
The infrared transmitting LED on the remote
The infrared receiver on the air conditioner

This type of controller uses an infrared LED to relay commands from a remote control to the air conditioner. The output of the infrared LED (like that of any infrared remote) is invisible to the human eye because its wavelength is beyond the range of visible light (940 nm). This system is commonly used on mini-split air conditioners because it is simple and portable. Some window and ducted central air conditioners uses it as well.

Wired controller

[edit]
Main article: Thermostat
Several wired controllers (Indonesia, 2024)

A wired controller, also called a "wired thermostat," is a device that controls an air conditioner by switching heating or cooling on or off. It uses different sensors to measure temperatures and actuate control operations. Mechanical thermostats commonly use bimetallic strips, converting a temperature change into mechanical displacement, to actuate control of the air conditioner. Electronic thermostats, instead, use a thermistor or other semiconductor sensor, processing temperature change as electronic signals to control the air conditioner.

These controllers are usually used in hotel rooms because they are permanently installed into a wall and hard-wired directly into the air conditioner unit, eliminating the need for batteries.

Types

[edit]
 
Types Typical Capacity* Air supply Mounting Typical application
Mini-split small – large Direct Wall Residential
Window very small – small Direct Window Residential
Portable very small – small Direct / Ducted Floor Residential, remote areas
Ducted (individual) small – very large Ducted Ceiling Residential, commercial
Ducted (central) medium – very large Ducted Ceiling Residential, commercial
Ceiling suspended medium – large Direct Ceiling Commercial
Cassette medium – large Direct / Ducted Ceiling Commercial
Floor standing medium – large Direct / Ducted Floor Commercial
Packaged very large Direct / Ducted Floor Commercial
Packaged RTU (Rooftop Unit) very large Ducted Rooftop Commercial

* where the typical capacity is in kilowatt as follows:

  • very small: <1.5 kW
  • small: 1.5–3.5 kW
  • medium: 4.2–7.1 kW
  • large: 7.2–14 kW
  • very large: >14 kW

Mini-split and multi-split systems

[edit]
Evaporator, indoor unit, or terminal, side of a ductless split-type air conditioner

Ductless systems (often mini-split, though there are now ducted mini-split) typically supply conditioned and heated air to a single or a few rooms of a building, without ducts and in a decentralized manner.[63] Multi-zone or multi-split systems are a common application of ductless systems and allow up to eight rooms (zones or locations) to be conditioned independently from each other, each with its indoor unit and simultaneously from a single outdoor unit.

The first mini-split system was sold in 1961 by Toshiba in Japan, and the first wall-mounted mini-split air conditioner was sold in 1968 in Japan by Mitsubishi Electric, where small home sizes motivated their development. The Mitsubishi model was the first air conditioner with a cross-flow fan.[64][65][66] In 1969, the first mini-split air conditioner was sold in the US.[67] Multi-zone ductless systems were invented by Daikin in 1973, and variable refrigerant flow systems (which can be thought of as larger multi-split systems) were also invented by Daikin in 1982. Both were first sold in Japan.[68] Variable refrigerant flow systems when compared with central plant cooling from an air handler, eliminate the need for large cool air ducts, air handlers, and chillers; instead cool refrigerant is transported through much smaller pipes to the indoor units in the spaces to be conditioned, thus allowing for less space above dropped ceilings and a lower structural impact, while also allowing for more individual and independent temperature control of spaces. The outdoor and indoor units can be spread across the building.[69] Variable refrigerant flow indoor units can also be turned off individually in unused spaces.[citation needed] The lower start-up power of VRF's DC inverter compressors and their inherent DC power requirements also allow VRF solar-powered heat pumps to be run using DC-providing solar panels.

Ducted central systems

[edit]

Split-system central air conditioners consist of two heat exchangers, an outside unit (the condenser) from which heat is rejected to the environment and an internal heat exchanger (the evaporator, or Fan Coil Unit, FCU) with the piped refrigerant being circulated between the two. The FCU is then connected to the spaces to be cooled by ventilation ducts.[70] Floor standing air conditioners are similar to this type of air conditioner but sit within spaces that need cooling.

Central plant cooling

[edit]
See also: Chiller
Industrial air conditioners on top of the shopping mall Passage in Linz, Austria

Large central cooling plants may use intermediate coolant such as chilled water pumped into air handlers or fan coil units near or in the spaces to be cooled which then duct or deliver cold air into the spaces to be conditioned, rather than ducting cold air directly to these spaces from the plant, which is not done due to the low density and heat capacity of air, which would require impractically large ducts. The chilled water is cooled by chillers in the plant, which uses a refrigeration cycle to cool water, often transferring its heat to the atmosphere even in liquid-cooled chillers through the use of cooling towers. Chillers may be air- or liquid-cooled.[71][72]

Portable units

[edit]

A portable system has an indoor unit on wheels connected to an outdoor unit via flexible pipes, similar to a permanently fixed installed unit (such as a ductless split air conditioner).

Hose systems, which can be monoblock or air-to-air, are vented to the outside via air ducts. The monoblock type collects the water in a bucket or tray and stops when full. The air-to-air type re-evaporates the water, discharges it through the ducted hose, and can run continuously. Many but not all portable units draw indoor air and expel it outdoors through a single duct, negatively impacting their overall cooling efficiency.

Many portable air conditioners come with heat as well as a dehumidification function.[73]

Window unit and packaged terminal

[edit]
Through-the-wall PTAC units, University Motor Inn, Philadelphia
Main article: Packaged terminal air conditioner

The packaged terminal air conditioner (PTAC), through-the-wall, and window air conditioners are similar. These units are installed on a window frame or on a wall opening. The unit usually has an internal partition separating its indoor and outdoor sides, which contain the unit's condenser and evaporator, respectively. PTAC systems may be adapted to provide heating in cold weather, either directly by using an electric strip, gas, or other heaters, or by reversing the refrigerant flow to heat the interior and draw heat from the exterior air, converting the air conditioner into a heat pump. They may be installed in a wall opening with the help of a special sleeve on the wall and a custom grill that is flush with the wall and window air conditioners can also be installed in a window, but without a custom grill.[74]

Packaged air conditioner

[edit]

Packaged air conditioners (also known as self-contained units)[75][76] are central systems that integrate into a single housing all the components of a split central system, and deliver air, possibly through ducts, to the spaces to be cooled. Depending on their construction they may be outdoors or indoors, on roofs (rooftop units),[77][78] draw the air to be conditioned from inside or outside a building and be water or air-cooled. Often, outdoor units are air-cooled while indoor units are liquid-cooled using a cooling tower.[70][79][80][81][82][83]

Types of compressors

[edit]
 
Compressor types Common applications Typical capacity Efficiency Durability Repairability
Reciprocating Refrigerator, Walk-in freezer, portable air conditioners small – large very low (small capacity)

medium (large capacity)

 very low medium
Rotary vane Residential mini splits small low low easy
Scroll Commercial and central systems, VRF medium medium medium easy
Rotary screw Commercial chiller medium – large medium medium hard
Centrifugal Commercial chiller very large medium high hard
Maglev Centrifugal Commercial chiller very large high very high very hard

Reciprocating

[edit]
Main article: Reciprocating compressor

This compressor consists of a crankcase, crankshaft, piston rod, piston, piston ring, cylinder head and valves. [citation needed]

Scroll

[edit]
Main article: Scroll compressor

This compressor uses two interleaving scrolls to compress the refrigerant.[84] it consists of one fixed and one orbiting scrolls. This type of compressor is more efficient because it has 70 percent less moving parts than a reciprocating compressor. [citation needed]

Screw

[edit]
Main article: Rotary-screw compressor

This compressor use two very closely meshing spiral rotors to compress the gas. The gas enters at the suction side and moves through the threads as the screws rotate. The meshing rotors force the gas through the compressor, and the gas exits at the end of the screws. The working area is the inter-lobe volume between the male and female rotors. It is larger at the intake end, and decreases along the length of the rotors until the exhaust port. This change in volume is the compression. [citation needed]

Capacity modulation technologies

[edit]

There are several ways to modulate the cooling capacity in refrigeration or air conditioning and heating systems. The most common in air conditioning are: on-off cycling, hot gas bypass, use or not of liquid injection, manifold configurations of multiple compressors, mechanical modulation (also called digital), and inverter technology. [citation needed]

Hot gas bypass

[edit]

Hot gas bypass involves injecting a quantity of gas from discharge to the suction side. The compressor will keep operating at the same speed, but due to the bypass, the refrigerant mass flow circulating with the system is reduced, and thus the cooling capacity. This naturally causes the compressor to run uselessly during the periods when the bypass is operating. The turn down capacity varies between 0 and 100%.[85]

Manifold configurations

[edit]

Several compressors can be installed in the system to provide the peak cooling capacity. Each compressor can run or not in order to stage the cooling capacity of the unit. The turn down capacity is either 0/33/66 or 100% for a trio configuration and either 0/50 or 100% for a tandem.[citation needed]

Mechanically modulated compressor

[edit]

This internal mechanical capacity modulation is based on periodic compression process with a control valve, the two scroll set move apart stopping the compression for a given time period. This method varies refrigerant flow by changing the average time of compression, but not the actual speed of the motor. Despite an excellent turndown ratio – from 10 to 100% of the cooling capacity, mechanically modulated scrolls have high energy consumption as the motor continuously runs.[citation needed]

Variable-speed compressor

[edit]
Main article: Inverter compressor

This system uses a variable-frequency drive (also called an Inverter) to control the speed of the compressor. The refrigerant flow rate is changed by the change in the speed of the compressor. The turn down ratio depends on the system configuration and manufacturer. It modulates from 15 or 25% up to 100% at full capacity with a single inverter from 12 to 100% with a hybrid tandem. This method is the most efficient way to modulate an air conditioner's capacity. It is up to 58% more efficient than a fixed speed system.[citation needed]

Impact

[edit]

Health effects

[edit]
Rooftop condenser unit fitted on top of an Osaka Municipal Subway 10 series subway carriage. Air conditioning has become increasingly prevalent on public transport vehicles as a form of climate control, and to ensure passenger comfort and drivers' occupational safety and health.

In hot weather, air conditioning can prevent heat stroke, dehydration due to excessive sweating, electrolyte imbalance, kidney failure, and other issues due to hyperthermia.[8][86] Heat waves are the most lethal type of weather phenomenon in the United States.[87][88] A 2020 study found that areas with lower use of air conditioning correlated with higher rates of heat-related mortality and hospitalizations.[89] The August 2003 France heatwave resulted in approximately 15,000 deaths, where 80% of the victims were over 75 years old. In response, the French government required all retirement homes to have at least one air-conditioned room at 25 °C (77 °F) per floor during heatwaves.[8]

Air conditioning (including filtration, humidification, cooling and disinfection) can be used to provide a clean, safe, hypoallergenic atmosphere in hospital operating rooms and other environments where proper atmosphere is critical to patient safety and well-being. It is sometimes recommended for home use by people with allergies, especially mold.[90][91] However, poorly maintained water cooling towers can promote the growth and spread of microorganisms such as Legionella pneumophila, the infectious agent responsible for Legionnaires' disease. As long as the cooling tower is kept clean (usually by means of a chlorine treatment), these health hazards can be avoided or reduced. The state of New York has codified requirements for registration, maintenance, and testing of cooling towers to protect against Legionella.[92]

Economic effects

[edit]

First designed to benefit targeted industries such as the press as well as large factories, the invention quickly spread to public agencies and administrations with studies with claims of increased productivity close to 24% in places equipped with air conditioning.[93]

Air conditioning caused various shifts in demography, notably that of the United States starting from the 1970s. In the US, the birth rate was lower in the spring than during other seasons until the 1970s but this difference then declined since then.[94] As of 2007, the Sun Belt contained 30% of the total US population while it was inhabited by 24% of Americans at the beginning of the 20th century.[95] Moreover, the summer mortality rate in the US, which had been higher in regions subject to a heat wave during the summer, also evened out.[7]

The spread of the use of air conditioning acts as a main driver for the growth of global demand of electricity.[96] According to a 2018 report from the International Energy Agency (IEA), it was revealed that the energy consumption for cooling in the United States, involving 328 million Americans, surpasses the combined energy consumption of 4.4 billion people in Africa, Latin America, the Middle East, and Asia (excluding China).[8] A 2020 survey found that an estimated 88% of all US households use AC, increasing to 93% when solely looking at homes built between 2010 and 2020.[97]

Environmental effects

[edit]
Air conditioner farm in the facade of a building in Singapore

Space cooling including air conditioning accounted globally for 2021 terawatt-hours of energy usage in 2016 with around 99% in the form of electricity, according to a 2018 report on air-conditioning efficiency by the International Energy Agency.[8] The report predicts an increase of electricity usage due to space cooling to around 6200 TWh by 2050,[8][98] and that with the progress currently seen, greenhouse gas emissions attributable to space cooling will double: 1,135 million tons (2016) to 2,070 million tons.[8] There is some push to increase the energy efficiency of air conditioners. United Nations Environment Programme (UNEP) and the IEA found that if air conditioners could be twice as effective as now, 460 billion tons of GHG could be cut over 40 years.[99] The UNEP and IEA also recommended legislation to decrease the use of hydrofluorocarbons, better building insulation, and more sustainable temperature-controlled food supply chains going forward.[99]

Refrigerants have also caused and continue to cause serious environmental issues, including ozone depletion and climate change, as several countries have not yet ratified the Kigali Amendment to reduce the consumption and production of hydrofluorocarbons.[100] CFCs and HCFCs refrigerants such as R-12 and R-22, respectively, used within air conditioners have caused damage to the ozone layer,[101] and hydrofluorocarbon refrigerants such as R-410A and R-404A, which were designed to replace CFCs and HCFCs, are instead exacerbating climate change.[102] Both issues happen due to the venting of refrigerant to the atmosphere, such as during repairs. HFO refrigerants, used in some if not most new equipment, solve both issues with an ozone damage potential (ODP) of zero and a much lower global warming potential (GWP) in the single or double digits vs. the three or four digits of hydrofluorocarbons.[103]

Hydrofluorocarbons would have raised global temperatures by around 0.3–0.5 °C (0.5–0.9 °F) by 2100 without the Kigali Amendment. With the Kigali Amendment, the increase of global temperatures by 2100 due to hydrofluorocarbons is predicted to be around 0.06 °C (0.1 °F).[104]

Alternatives to continual air conditioning include passive cooling, passive solar cooling, natural ventilation, operating shades to reduce solar gain, using trees, architectural shades, windows (and using window coatings) to reduce solar gain.[citation needed]

Social effects

[edit]

Socioeconomic groups with a household income below around $10,000 tend to have a low air conditioning adoption,[42] which worsens heat-related mortality.[7] The lack of cooling can be hazardous, as areas with lower use of air conditioning correlate with higher rates of heat-related mortality and hospitalizations.[89] Premature mortality in NYC is projected to grow between 47% and 95% in 30 years, with lower-income and vulnerable populations most at risk.[89] Studies on the correlation between heat-related mortality and hospitalizations and living in low socioeconomic locations can be traced in Phoenix, Arizona,[105] Hong Kong,[106] China,[106] Japan,[107] and Italy.[108][109] Additionally, costs concerning health care can act as another barrier, as the lack of private health insurance during a 2009 heat wave in Australia, was associated with heat-related hospitalization.[109]

Disparities in socioeconomic status and access to air conditioning are connected by some to institutionalized racism, which leads to the association of specific marginalized communities with lower economic status, poorer health, residing in hotter neighborhoods, engaging in physically demanding labor, and experiencing limited access to cooling technologies such as air conditioning.[109] A study overlooking Chicago, Illinois, Detroit, and Michigan found that black households were half as likely to have central air conditioning units when compared to their white counterparts.[110] Especially in cities, Redlining creates heat islands, increasing temperatures in certain parts of the city.[109] This is due to materials heat-absorbing building materials and pavements and lack of vegetation and shade coverage.[111] There have been initiatives that provide cooling solutions to low-income communities, such as public cooling spaces.[8][111]

Other techniques

[edit]

Buildings designed with passive air conditioning are generally less expensive to construct and maintain than buildings with conventional HVAC systems with lower energy demands.[112] While tens of air changes per hour, and cooling of tens of degrees, can be achieved with passive methods, site-specific microclimate must be taken into account, complicating building design.[12]

Many techniques can be used to increase comfort and reduce the temperature in buildings. These include evaporative cooling, selective shading, wind, thermal convection, and heat storage.[113]

Passive ventilation

[edit]
This section is an excerpt from Passive ventilation.[edit]
The ventilation system of a regular earthship
Dogtrot houses are designed to maximise natural ventilation.
A roof turbine ventilator, colloquially known as a 'Whirly Bird' is an application of wind driven ventilation.

Passive ventilation is the process of supplying air to and removing air from an indoor space without using mechanical systems. It refers to the flow of external air to an indoor space as a result of pressure differences arising from natural forces.

There are two types of natural ventilation occurring in buildings: wind driven ventilation and buoyancy-driven ventilation. Wind driven ventilation arises from the different pressures created by wind around a building or structure, and openings being formed on the perimeter which then permit flow through the building. Buoyancy-driven ventilation occurs as a result of the directional buoyancy force that results from temperature differences between the interior and exterior.[114]

Since the internal heat gains which create temperature differences between the interior and exterior are created by natural processes, including the heat from people, and wind effects are variable, naturally ventilated buildings are sometimes called "breathing buildings".

Passive cooling

[edit]
 
This section is an excerpt from Passive cooling.[edit]
A traditional Iranian solar cooling design using a wind tower

Passive cooling is a building design approach that focuses on heat gain control and heat dissipation in a building in order to improve the indoor thermal comfort with low or no energy consumption.[115][116] This approach works either by preventing heat from entering the interior (heat gain prevention) or by removing heat from the building (natural cooling).[117]

Natural cooling utilizes on-site energy, available from the natural environment, combined with the architectural design of building components (e.g. building envelope), rather than mechanical systems to dissipate heat.[118] Therefore, natural cooling depends not only on the architectural design of the building but on how the site's natural resources are used as heat sinks (i.e. everything that absorbs or dissipates heat). Examples of on-site heat sinks are the upper atmosphere (night sky), the outdoor air (wind), and the earth/soil.

Passive cooling is an important tool for design of buildings for climate change adaptation – reducing dependency on energy-intensive air conditioning in warming environments.[119][120]
A pair of short windcatchers (malqaf) used in traditional architecture; wind is forced down on the windward side and leaves on the leeward side (cross-ventilation). In the absence of wind, the circulation can be driven with evaporative cooling in the inlet (which is also designed to catch dust). In the center, a shuksheika (roof lantern vent), used to shade the qa'a below while allowing hot air rise out of it (stack effect).[11]

Daytime radiative cooling

[edit]
Passive daytime radiative cooling (PDRC) surfaces are high in solar reflectance and heat emittance, cooling with zero energy use or pollution.[121]

Passive daytime radiative cooling (PDRC) surfaces reflect incoming solar radiation and heat back into outer space through the infrared window for cooling during the daytime. Daytime radiative cooling became possible with the ability to suppress solar heating using photonic structures, which emerged through a study by Raman et al. (2014).[122] PDRCs can come in a variety of forms, including paint coatings and films, that are designed to be high in solar reflectance and thermal emittance.[121][123]

PDRC applications on building roofs and envelopes have demonstrated significant decreases in energy consumption and costs.[123] In suburban single-family residential areas, PDRC application on roofs can potentially lower energy costs by 26% to 46%.[124] PDRCs are predicted to show a market size of ~$27 billion for indoor space cooling by 2025 and have undergone a surge in research and development since the 2010s.[125][126]

Fans

[edit]
Main article: Ceiling fan

Hand fans have existed since prehistory. Large human-powered fans built into buildings include the punkah.

The 2nd-century Chinese inventor Ding Huan of the Han dynasty invented a rotary fan for air conditioning, with seven wheels 3 m (10 ft) in diameter and manually powered by prisoners.[127]: 99, 151, 233  In 747, Emperor Xuanzong (r. 712–762) of the Tang dynasty (618–907) had the Cool Hall (Liang Dian 涼殿) built in the imperial palace, which the Tang Yulin describes as having water-powered fan wheels for air conditioning as well as rising jet streams of water from fountains. During the subsequent Song dynasty (960–1279), written sources mentioned the air conditioning rotary fan as even more widely used.[127]: 134, 151 

Thermal buffering

[edit]

In areas that are cold at night or in winter, heat storage is used. Heat may be stored in earth or masonry; air is drawn past the masonry to heat or cool it.[13]

In areas that are below freezing at night in winter, snow and ice can be collected and stored in ice houses for later use in cooling.[13] This technique is over 3,700 years old in the Middle East.[128] Harvesting outdoor ice during winter and transporting and storing for use in summer was practiced by wealthy Europeans in the early 1600s,[15] and became popular in Europe and the Americas towards the end of the 1600s.[129] This practice was replaced by mechanical compression-cycle icemakers.

Evaporative cooling

[edit]
Main article: Evaporative cooler
An evaporative cooler

In dry, hot climates, the evaporative cooling effect may be used by placing water at the air intake, such that the draft draws air over water and then into the house. For this reason, it is sometimes said that the fountain, in the architecture of hot, arid climates, is like the fireplace in the architecture of cold climates.[11] Evaporative cooling also makes the air more humid, which can be beneficial in a dry desert climate.[130]

Evaporative coolers tend to feel as if they are not working during times of high humidity, when there is not much dry air with which the coolers can work to make the air as cool as possible for dwelling occupants. Unlike other types of air conditioners, evaporative coolers rely on the outside air to be channeled through cooler pads that cool the air before it reaches the inside of a house through its air duct system; this cooled outside air must be allowed to push the warmer air within the house out through an exhaust opening such as an open door or window.[131]

See also

[edit]
  • Air filter
  • Air purifier
  • Cleanroom
  • Crankcase heater
  • Energy recovery ventilation
  • Indoor air quality
  • Particulates

References

[edit]
  1. ^ "Air Con". Cambridge Dictionary. Archived from the original on May 3, 2022. Retrieved January 6, 2023.
  2. ^ Dissertation Abstracts International: The humanities and social sciences. A. University Microfilms. 2005. p. 3600.
  3. ^ 1993 ASHRAE Handbook: Fundamentals. ASHRAE. 1993. ISBN 978-0-910110-97-6.
  4. ^ Enteria, Napoleon; Sawachi, Takao; Saito, Kiyoshi (January 31, 2023). Variable Refrigerant Flow Systems: Advances and Applications of VRF. Springer Nature. p. 46. ISBN 978-981-19-6833-4.
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  8. ^ a b c d e f g h i j International Energy Agency (May 15, 2018). The Future of Cooling - Opportunities for energy-efficient air conditioning (PDF) (Report). Archived (PDF) from the original on June 26, 2024. Retrieved July 1, 2024.
  9. ^ Laub, Julian M. (1963). Air Conditioning & Heating Practice. Holt, Rinehart and Winston. p. 367. ISBN 978-0-03-011225-6.
  10. ^ "Air-conditioning found at 'oldest city in the world'". The Independent. June 24, 2000. Archived from the original on December 8, 2023. Retrieved December 9, 2023.
  11. ^ a b c Mohamed, Mady A.A. (January 2010). Lehmann, S.; Waer, H.A.; Al-Qawasmi, J. (eds.). Traditional Ways of Dealing with Climate in Egypt. The Seventh International Conference of Sustainable Architecture and Urban Development (SAUD 2010). Amman, Jordan: The Center for the Study of Architecture in Arab Region (CSAAR Press). pp. 247–266. Archived from the original on May 13, 2021. Retrieved May 12, 2021.
  12. ^ a b c Ford, Brian (September 2001). "Passive downdraught evaporative cooling: principles and practice". Architectural Research Quarterly. 5 (3): 271–280. doi:10.1017/S1359135501001312.
  13. ^ a b c Attia, Shady; Herde, André de (June 22–24, 2009). Designing the Malqaf for Summer Cooling in Low-Rise Housing, an Experimental Study. 26th Conference on Passive and Low Energy Architecture (PLEA2009). Quebec City. Archived from the original on May 13, 2021. Retrieved May 12, 2021.
  14. ^ US EPA, OAR (October 17, 2014). "Heating, Ventilation and Air-Conditioning Systems, Part of Indoor Air Quality Design Tools for Schools". epa.gov. Archived from the original on July 5, 2022. Retrieved July 5, 2022.
  15. ^ a b c Shachtman, Tom (1999). "Winter in Summer". Absolute zero and the conquest of cold. Boston: Houghton Mifflin Harcourt. ISBN 978-0395938881. OCLC 421754998. Archived from the original on May 13, 2021. Retrieved May 12, 2021.
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[edit]
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  • U.S. patent 808,897 Carrier's original patent
  • U.S. patent 1,172,429
  • U.S. patent 2,363,294
  • Scientific American, "Artificial Cold", 28 August 1880, p. 138
  • Scientific American, "The Presidential Cold Air Machine", 6 August 1881, p. 84
 
 
 
 

 

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Driving Directions in Arapahoe County

Driving Directions From King Soopers Pharmacy to Royal Supply South
Driving Directions From VRCC Veterinary Specialty and Emergency Hospital to Royal Supply South
Driving Directions From Littleton to Royal Supply South

Mobile Home Hvac Service

Mobile home supply store

Air conditioning repair service

Air conditioning store

Driving Directions From Wings Over the Rockies Air & Space Museum to Royal Supply South
Driving Directions From Cherry Creek State Park to Royal Supply South
Driving Directions From Denver Museum of Nature & Science to Royal Supply South
Driving Directions From Museum of Outdoor Arts to Royal Supply South
Driving Directions From Plains Conservation Center (Visitor Center) to Royal Supply South
Driving Directions From The Aurora Highlands North Sculpture to Royal Supply South

Mobile Home Furnace Installation

Mobile Home Air Conditioning Installation Services

Mobile Home Hvac Repair

Mobile Home Hvac Service

Mobile home supply store

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