How Regular Lubrication of HVAC Parts Prevents Unnecessary Wear

airflow balancing

Heating, Ventilation, and Air Conditioning (HVAC) systems are indispensable in maintaining indoor comfort by regulating temperature and air quality. To ensure their efficient operation, regular maintenance is crucial. Among the various maintenance tasks, lubrication of specific components stands out as a fundamental practice that prevents unnecessary wear and prolongs the system's lifespan.


One of the most common components requiring lubrication within an HVAC system are the fan motors. These motors drive fans that circulate air through ducts and into living spaces. Over time, friction can develop between moving parts, leading to increased resistance and potential overheating. By routinely applying lubricant to fan motor bearings, this friction is minimized, allowing for smooth operation and reducing the risk of premature failure.


Poor airflow can indicate the need for HVAC repair services to ensure your home stays comfortable year-round..

Another critical component that requires lubrication is the blower shaft bearings. The blower is responsible for moving air across heating or cooling elements before it reaches occupied areas. The continuous rotation of blower shafts can generate significant wear if not properly lubricated. Regularly applying suitable lubricants helps maintain optimal performance by reducing noise levels and preventing excessive vibration caused by dry bearings.


Pumps within HVAC systems also benefit from routine lubrication. Whether they are circulating pumps in hydronic systems or pumps associated with chillers, these units often encounter heavy workloads. Lubricating pump bearings ensures that they operate efficiently without undue strain on their components. This not only extends the life of the pumps but also maintains energy efficiency by minimizing resistance.


Furthermore, dampers-used to regulate airflow within ductwork-also require attention when it comes to lubrication. Dampers play a vital role in controlling the distribution of air throughout different zones within a building; any stiffness or difficulty in movement could result in uneven temperature distribution or compromised indoor air quality. Applying lubricant to damper hinges assures effortless adjustments and precise control over airflow regulation.


Regular lubrication does more than just prevent mechanical failures; it enhances overall energy efficiency as well. When HVAC components operate smoothly without excess friction or resistance, less energy is required to achieve desired temperatures or airflow levels. This translates into reduced operational costs and lower environmental impact due to decreased energy consumption.


In conclusion, understanding which HVAC components require regular lubrication highlights its importance in preventing unnecessary wear and ensuring long-term functionality of these intricate systems. Fan motors, blower shafts, pumps, dampers-all these parts rely on effective lubrication for seamless operation without added stress on individual elements or overall system performance itself . By prioritizing this essential maintenance task through scheduled inspections by trained professionals , homeowners can enjoy reliable comfort while safeguarding their investment against costly repairs down line .

The Role of Lubrication in Reducing Friction and Wear —

In the intricate dance of mechanical systems, lubrication plays a silent yet pivotal role. Nowhere is this more evident than in heating, ventilation, and air conditioning (HVAC) systems, where regular lubrication acts as a guardian against the insidious forces of friction and wear. As HVAC units work tirelessly to maintain comfort within our homes and workplaces, understanding the significance of lubrication becomes crucial in ensuring their longevity and efficiency.


Friction is an inevitable byproduct of moving parts working together. In an HVAC system, components such as motors, fans, and bearings are constantly in motion. When these parts interact without adequate lubrication, friction increases exponentially. This heightened friction leads to excessive heat generation and material degradation-two culprits that can significantly shorten component lifespan. By applying appropriate lubricants at regular intervals, a protective film is created between moving surfaces, drastically reducing the direct contact that results in wear.


The benefits of regular lubrication extend beyond merely minimizing wear; they also encompass energy efficiency. A well-lubricated HVAC system requires less energy to operate because the components move smoothly against each other with minimal resistance. This reduction in energy consumption not only decreases operational costs but also lessens the environmental impact-a critical consideration in today's climate-conscious world.


Moreover, consistent lubrication maintenance helps prevent unexpected breakdowns that can disrupt service and lead to costly repairs or replacements. By reducing friction-induced damage, lubricants contribute to maintaining optimal performance levels over extended periods. This preventive approach ensures that smaller issues do not escalate into major problems requiring significant downtime for fixes.


Selecting the right lubricant for HVAC components is equally important as applying it regularly. Different parts may require specific types of lubricants based on factors such as temperature ranges and load conditions they encounter during operation. Choosing inappropriate lubricants could lead to adverse effects such as gumming or corrosion rather than providing protection.


In conclusion, regular lubrication serves as an indispensable shield against friction and wear within HVAC systems. It enhances component longevity, boosts energy efficiency, prevents interruptions due to equipment failures, and ultimately saves costs associated with repairs or replacements. Emphasizing routine maintenance through proper lubrication ensures that these complex systems continue functioning efficiently-upholding their vital role in creating comfortable living environments while standing resilient against time's relentless march.

How Proper Lubrication Extends the Lifespan of HVAC Parts

In the intricate dance of mechanical components that comprise an HVAC system, lubrication plays an unsung but crucial role. Much like oil in an engine, proper lubrication is essential for maintaining the longevity and efficiency of HVAC parts. Regular lubrication serves as a protective barrier, reducing friction and minimizing wear and tear on moving components. This practice not only enhances performance but also extends the lifespan of the system's parts, ensuring optimal operation and preventing unnecessary breakdowns.


At its core, an HVAC system relies on numerous moving parts working in harmony-from fans and motors to compressors and belts. These components are constantly interacting, generating heat and friction as they operate. Without adequate lubrication, this friction can lead to increased wear and tear, resulting in component degradation over time. Moreover, unlubricated parts have a higher tendency to seize or bind together, which can lead to unexpected failures or costly repairs.


Regular lubrication acts as a safeguard against such issues by creating a thin film that separates moving surfaces. This reduces direct contact between metal parts, diminishing friction levels significantly. Consequently, lubricated components experience less stress during operation, leading to smoother function and reduced energy consumption-a benefit that translates into lower utility bills.




How Regular Lubrication of HVAC Parts Prevents Unnecessary Wear - commercial HVAC services

  1. airflow balancing
  2. commercial HVAC services
  3. climate control systems

Furthermore, effective lubrication helps dissipate heat generated by friction. Excessive heat can exacerbate wear on HVAC components by altering their material properties or causing thermal expansion misalignments. By keeping temperature levels in check through regular lubrication practices, these adverse effects are mitigated.


In addition to enhancing performance and extending part life spans, regular lubrication contributes to quieter operation-a marked improvement for environments where noise reduction is paramount. Properly lubricated systems produce fewer squeaks and rattles since the movement is more fluid and uninterrupted.


It is important to note that not all lubricants are created equal; selecting the appropriate type based on manufacturer recommendations ensures compatibility with specific materials used within your HVAC system's design. Additionally, adhering to recommended maintenance schedules for applying lubricants is essential for achieving desired outcomes.


In conclusion, while often overlooked amidst broader maintenance tasks such as filter replacements or coil cleanings-proper lubrication stands out as one of those small yet impactful actions capable of prolonging an HVAC system's life span significantly when done consistently over time. By embracing this simple preventive measure today homeowners stand poised not just save money tomorrow but also enjoy uninterrupted comfort through every season ahead!

How Proper Lubrication Extends the Lifespan of HVAC Parts
Preventative Maintenance: Scheduling Regular Lubrication Sessions

Preventative Maintenance: Scheduling Regular Lubrication Sessions

Preventative maintenance is an essential component of ensuring the longevity and efficiency of HVAC systems. One critical aspect of this maintenance is scheduling regular lubrication sessions for the various moving parts within these systems. Just like any machinery, HVAC units rely on numerous components that work together to provide a comfortable indoor environment. By regularly lubricating these parts, unnecessary wear can be significantly reduced, leading to improved performance and extended system life.


HVAC systems are composed of several mechanical components such as fans, motors, bearings, and compressors. These parts are in constant motion when the system is operational, which naturally leads to friction. Over time, friction can cause significant wear and tear if not properly managed. Lubrication acts as a protective barrier between moving surfaces, minimizing friction and reducing the rate at which these components degrade.


One of the primary benefits of regular lubrication is enhanced efficiency. When HVAC parts move smoothly without excessive resistance caused by friction, they require less energy to operate effectively. This not only reduces wear but also lowers energy consumption, resulting in cost savings on utility bills for homeowners and businesses alike. Furthermore, a well-lubricated system operates more quietly and with fewer disruptions, contributing to a more comfortable indoor environment.


Another advantage of routine lubrication is its role in preventing unexpected breakdowns. Without adequate lubrication, HVAC components are more likely to overheat or become damaged under stress, leading to potential failures that can disrupt service at inconvenient times.

How Regular Lubrication of HVAC Parts Prevents Unnecessary Wear - climate control systems

    Scheduled lubrication sessions help identify early signs of wear before they develop into major issues that require costly repairs or replacements.


    Moreover, regular lubrication contributes to a longer lifespan for the entire HVAC system. By maintaining each component's optimal condition through proper care, including timely lubrication, property owners can maximize their investment in their heating and cooling infrastructure. This proactive approach helps avoid premature system replacements and extends the overall usability of the equipment.


    In conclusion, scheduling regular lubrication sessions as part of preventative maintenance plays an indispensable role in preserving the functionality and efficiency of HVAC systems. By reducing unnecessary wear through effective friction management, property owners can enjoy lower energy costs, fewer disruptions due to breakdowns, quieter operation, and an extended lifespan for their equipment. Embracing this simple yet impactful practice ensures that HVAC systems continue delivering comfort reliably while safeguarding against avoidable expenses associated with neglecting essential maintenance tasks.

    Signs of Insufficient Lubrication in HVAC Systems

    In the realm of HVAC systems, regular maintenance is paramount to ensure efficiency and longevity. One critical aspect of this maintenance is lubrication. Much like any machinery with moving parts, HVAC systems are susceptible to wear and tear if not properly lubricated. While many homeowners might overlook this detail, understanding the signs of insufficient lubrication can prevent costly repairs and ensure the system operates smoothly.


    First, let us delve into why lubrication is essential. The various components within an HVAC system-such as motors, fans, bearings, and belts-rely on seamless motion to function effectively. Lubrication reduces friction between these moving parts, thereby minimizing wear and extending their lifespan. Without adequate lubrication, these parts can grind against each other, leading to increased energy consumption and potential failure.


    One telltale sign of insufficient lubrication in an HVAC system is unusual noise. If you hear grinding or squeaking sounds emanating from your unit, it may indicate that metal components are rubbing together without the protective layer that lubrication provides. This friction not only causes noise but can lead to overheating and eventual damage.


    Another indicator is a noticeable decrease in efficiency or performance. When parts move less freely due to lack of proper lubrication, they require more energy to operate at the same level as before. This inefficiency often manifests as higher utility bills even when usage patterns remain unchanged.


    Visual inspection can also reveal signs of inadequate lubrication. If you notice visible wear on belts or rust forming around metal components, it could be a signal that they are not receiving sufficient lubricant protection. Additionally, excessive vibration during operation might suggest that some parts are struggling against increased resistance.


    Regularly scheduled lubrication helps avoid these issues by ensuring all moving components have the necessary protective layer to reduce friction and prevent premature wear. By integrating this simple task into routine maintenance checks, homeowners can significantly lower repair costs over time while maintaining optimal system performance.


    Beyond preventing unnecessary wear and tear, consistent lubrication contributes to overall system reliability and safety. Overheated components due to friction can pose fire hazards-a risk easily mitigated by maintaining proper lubrication levels.


    In conclusion, recognizing the signs of insufficient lubrication in HVAC systems is crucial for anyone looking to preserve their investment's efficiency and extend its operational life span. By paying attention to auditory cues such as unusual noises or keeping an eye on performance metrics like energy bills or visual inspections for physical wear or rusting components-homeowners can proactively address potential issues before they escalate into significant problems requiring expensive repairs or replacements.
    Regularly lubricating your HVAC system's moving parts ensures smoother operation while preventing unnecessary strain on individual components-a practice that ultimately saves both time and money over long-term use while enhancing indoor comfort consistently throughout seasons year-round.

    Selecting the Right Lubricants for Different HVAC Parts

    In the intricate world of HVAC systems, each component, from compressors to fans and bearings, performs a crucial role in maintaining a comfortable and efficient environment within our homes and workplaces. However, like any complex machinery, these systems are susceptible to wear and tear over time. One of the most effective ways to mitigate this natural degradation is through regular lubrication of HVAC parts. Selecting the right lubricants for different HVAC components not only enhances their performance but also significantly extends their lifespan.


    Regular lubrication serves as a protective barrier between moving parts, reducing friction that can lead to excessive wear. In an HVAC system, components such as motors, fans, and bearings are in constant motion. Without adequate lubrication, these parts would grind against each other, generating heat and ultimately leading to mechanical failure. Proper lubrication minimizes this friction by providing a smooth film between surfaces, thereby ensuring seamless operation.


    Moreover, selecting the right type of lubricant for each specific part is essential. For instance, compressors require oil with specific viscosity ratings that can withstand high pressures and temperatures. On the other hand, fan bearings might need a lighter grease that ensures smooth rotation without adding unnecessary resistance. Each part has its unique operational demands; thus, understanding these requirements helps in choosing the appropriate lubricant that will offer optimal protection.


    The benefits of regular lubrication extend beyond mere prevention of wear. It also contributes to energy efficiency. When parts move effortlessly with minimal resistance due to proper lubrication, less energy is required for operation. This translates into lower operational costs and reduced stress on the system's power sources.


    Furthermore, well-lubricated components operate more quietly than those struggling under increased frictional forces. This reduction in noise pollution creates a more pleasant environment within buildings equipped with HVAC systems-a subtle yet valuable aspect often appreciated by occupants.




    How Regular Lubrication of HVAC Parts Prevents Unnecessary Wear - commercial HVAC services

    1. climate control systems
    2. climate control systems
    3. climate control systems

    Implementing a routine maintenance schedule that includes checking lubricant levels and applying fresh lubricants when necessary can prevent minor issues from escalating into costly repairs or replacements. Maintenance personnel should be trained not only in recognizing signs of inadequate lubrication but also in understanding which types of lubricants are best suited for various components within the system.


    In conclusion, regular lubrication is fundamental to preventing unnecessary wear in HVAC systems. By selecting the right lubricants tailored to each part's needs and maintaining consistent application schedules, businesses and homeowners alike can enjoy enhanced performance from their heating and cooling systems while simultaneously extending their service life-an investment well worth making for long-term efficiency and reliability.

     

    An air filter being cleaned
    Part of a series on
    Pollution
    Air pollution from a factory
    Air
    Biological
    Digital
    Electromagnetic
    Natural
    Noise
    Radiation
    Soil
    Solid waste
    Space
    Thermal
    Visual
    War
    Water
    Topics
    Misc
    Lists
    Categories
     

    Indoor air quality (IAQ) is the air quality within buildings and structures. Poor indoor air quality due to indoor air pollution is known to affect the health, comfort, and well-being of building occupants. It has also been linked to sick building syndrome, respiratory issues, reduced productivity, and impaired learning in schools. Common pollutants of indoor air include: secondhand tobacco smoke, air pollutants from indoor combustion, radon, molds and other allergens, carbon monoxide, volatile organic compounds, legionella and other bacteria, asbestos fibers, carbon dioxide,[1] ozone and particulates.

    Source control, filtration, and the use of ventilation to dilute contaminants are the primary methods for improving indoor air quality. Although ventilation is an integral component of maintaining good indoor air quality, it may not be satisfactory alone.[2] In scenarios where outdoor pollution would deteriorate indoor air quality, other treatment devices such as filtration may also be necessary.[3]

    IAQ is evaluated through collection of air samples, monitoring human exposure to pollutants, analysis of building surfaces, and computer modeling of air flow inside buildings. IAQ is part of indoor environmental quality (IEQ), along with other factors that exert an influence on physical and psychological aspects of life indoors (e.g., lighting, visual quality, acoustics, and thermal comfort).[4]

    Indoor air pollution is a major health hazard in developing countries and is commonly referred to as "household air pollution" in that context.[5] It is mostly relating to cooking and heating methods by burning biomass fuel, in the form of wood, charcoal, dung, and crop residue, in indoor environments that lack proper ventilation. Millions of people, primarily women and children, face serious health risks. In total, about three billion people in developing countries are affected by this problem. The World Health Organization (WHO) estimates that cooking-related indoor air pollution causes 3.8 million annual deaths.[6] The Global Burden of Disease study estimated the number of deaths in 2017 at 1.6 million.[7]

    Definition

    [edit]

    For health reasons it is crucial to breathe clean air, free from chemicals and toxicants as much as possible. It is estimated that humans spend approximately 90% of their lifetime indoors[8] and that indoor air pollution in some places can be much worse than that of the ambient air.[9][10]

    Various factors contribute to high concentrations of pollutants indoors, ranging from influx of pollutants from external sources, off-gassing by furniture, furnishings including carpets, indoor activities (cooking, cleaning, painting, smoking, etc. in homes to using office equipment in offices), thermal comfort parameters such as temperature, humidity, airflow and physio-chemical properties of the indoor air.[citation needed] Air pollutants can enter a building in many ways, including through open doors or windows. Poorly maintained air conditioners/ventilation systems can harbor mold, bacteria, and other contaminants, which are then circulated throughout indoor spaces, contributing to respiratory problems and allergies.

    There have been many debates among indoor air quality specialists about the proper definition of indoor air quality and specifically what constitutes "acceptable" indoor air quality.

    Health effects

    [edit]
    Share of deaths from indoor air pollution. Darker colors mean higher numbers.

    IAQ is significant for human health as humans spend a large proportion of their time in indoor environments. Americans and Europeans on average spend approximately 90% of their time indoors.[11][12]

    The World Health Organization (WHO) estimates that 3.2 million people die prematurely every year from illnesses attributed to indoor air pollution caused by indoor cooking, with over 237 thousand of these being children under 5. These include around an eighth of all global ischaemic heart disease, stroke, and lung cancer deaths. Overall the WHO estimated that poor indoor air quality resulted in the loss of 86 million healthy life years in 2019.[13]

    Studies in the UK and Europe show exposure to indoor air pollutants, chemicals and biological contamination can irritate the upper airway system, trigger or exacerbate asthma and other respiratory or cardiovascular conditions, and may even have carcinogenic effects.[14][15][16][17][18][19]

    Poor indoor air quality can cause sick building syndrome. Symptoms include burning of the eyes, scratchy throat, blocked nose, and headaches.[20]

    Common pollutants

    [edit]

    Generated by indoor combustion

    [edit]
    Main article: Household air pollution
    Further information: Energy poverty and cooking
    a 3-stone stove
    A traditional wood-fired 3-stone stove in Guatemala, which causes indoor air pollution

    Indoor combustion, such as for cooking or heating, is a major cause of indoor air pollution and causes significant health harms and premature deaths. Hydrocarbon fires cause air pollution. Pollution is caused by both biomass and fossil fuels of various types, but some forms of fuels are more harmful than others.

    Indoor fire can produce black carbon particles, nitrogen oxides, sulfur oxides, and mercury compounds, among other emissions.[21] Around 3 billion people cook over open fires or on rudimentary cook stoves. Cooking fuels are coal, wood, animal dung, and crop residues.[22] IAQ is a particular concern in low and middle-income countries where such practices are common.[23]

    Cooking using natural gas (also called fossil gas, methane gas or simply gas) is associated with poorer indoor air quality. Combustion of gas produces nitrogen dioxide and carbon monixide, and can lead to increased concentrations of nitrogen dioxide throughout the home environment which is linked to respiratory issues and diseases.[24][25]

    Carbon monoxide

    [edit]
    Main article: Carbon monoxide poisoning

    One of the most acutely toxic indoor air contaminants is carbon monoxide (CO), a colourless and odourless gas that is a by-product of incomplete combustion. Carbon monoxide may be emitted from tobacco smoke and generated from malfunctioning fuel burning stoves (wood, kerosene, natural gas, propane) and fuel burning heating systems (wood, oil, natural gas) and from blocked flues connected to these appliances.[26] In developed countries the main sources of indoor CO emission come from cooking and heating devices that burn fossil fuels and are faulty, incorrectly installed or poorly maintained.[27] Appliance malfunction may be due to faulty installation or lack of maintenance and proper use.[26] In low- and middle-income countries the most common sources of CO in homes are burning biomass fuels and cigarette smoke.[27]

    Health effects of CO poisoning may be acute or chronic and can occur unintentionally or intentionally (self-harm). By depriving the brain of oxygen, acute exposure to carbon monoxide may have effects on the neurological system (headache, nausea, dizziness, alteration in consciousness and subjective weakness), the cardiovascular and respiratory systems (myocardial infarction, shortness of breath, or rapid breathing, respiratory failure). Acute exposure can also lead to long-term neurological effects such as cognitive and behavioural changes. Severe CO poisoning may lead to unconsciousness, coma and death. Chronic exposure to low concentrations of carbon monoxide may lead to lethargy, headaches, nausea, flu-like symptoms and neuropsychological and cardiovascular issues.[28][26]

    The WHO recommended levels of indoor CO exposure in 24 hours is 4 mg/m3.[29] Acute exposure should not exceed 10 mg/m3 in 8 hours, 35 mg/m3 in one hour and 100 mg/m3 in 15 minutes.[27]

    Secondhand tobacco smoke

    [edit]
    Main article: Passive smoking

    Secondhand smoke is tobacco smoke which affects people other than the 'active' smoker. It is made up of the exhaled smoke (15%) and mostly of smoke coming from the burning end of the cigarette, known as sidestream smoke (85%).[30]

    Secondhand smoke contains more than 7000 chemicals, of which hundreds are harmful to health.[30] Secondhand tobacco smoke includes both a gaseous and a particulate materials which, with particular hazards arising from levels of carbon monoxide and very small particulates (fine particulate matter, especially PM2.5 and PM10) which get into the bronchioles and alveoles in the lung.[31] Inhaling secondhand smoke on multiple occasions can cause asthma, pneumonia, lung cancer, and sudden infant death syndrome, among other conditions.[32]

    Thirdhand smoke (THS) refers to chemicals that settle on objects and bodies indoors after smoking. Exposure to thirdhand smoke can happen even after the actual cigarette smoke is not present anymore and affect those entering the indoor environment much later. Toxic substances of THS can react with other chemicals in the air and produce new toxic chemicals that are otherwise not present in cigarettes.[33]

    The only certain method to improve indoor air quality as regards secondhand smoke is to eliminate smoking indoors.[34] Indoor e-cigarette use also increases home particulate matter concentrations.[35]

    Particulates

    [edit]

    Atmospheric particulate matter, also known as particulates, can be found indoors and can affect the health of occupants. Indoor particulate matter can come from different indoor sources or be created as secondary aerosols through indoor gas-to-particle reactions. They can also be outdoor particles that enter indoors. These indoor particles vary widely in size, ranging from nanomet (nanoparticles/ultrafine particles emitted from combustion sources) to micromet (resuspensed dust).[36] Particulate matter can also be produced through cooking activities. Frying produces higher concentrations than boiling or grilling and cooking meat produces higher concentrations than cooking vegetables.[37] Preparing a Thanksgiving dinner can produce very high concentrations of particulate matter, exceeding 300 μg/m3.[38]

    Particulates can penetrate deep into the lungs and brain from blood streams, causing health problems such as heart disease, lung disease, cancer and preterm birth.[39]

    Generated from building materials, furnishing and consumer products

    [edit]
    See also: Building materials and Red List building materials

    Volatile organic compounds

    [edit]

    Volatile organic compounds (VOCs) include a variety of chemicals, some of which may have short- and long-term adverse health effects. There are numerous sources of VOCs indoors, which means that their concentrations are consistently higher indoors (up to ten times higher) than outdoors.[40] Some VOCs are emitted directly indoors, and some are formed through the subsequent chemical reactions that can occur in the gas-phase, or on surfaces.[41][42] VOCs presenting health hazards include benzene, formaldehyde, tetrachloroethylene and trichloroethylene.[43]

    VOCs are emitted by thousands of indoor products. Examples include: paints, varnishes, waxes and lacquers, paint strippers, cleaning and personal care products, pesticides, building materials and furnishings, office equipment such as copiers and printers, correction fluids and carbonless copy paper, graphics and craft materials including glues and adhesives, permanent markers, and photographic solutions.[44] Chlorinated drinking water releases chloroform when hot water is used in the home. Benzene is emitted from fuel stored in attached garages.

    Human activities such as cooking and cleaning can also emit VOCs.[45][46] Cooking can release long-chain aldehydes and alkanes when oil is heated and terpenes can be released when spices are prepared and/or cooked.[45] Leaks of natural gas from cooking appliances have been linked to elevated levels of VOCs including benzene in homes in the USA.[47] Cleaning products contain a range of VOCs, including monoterpenes, sesquiterpenes, alcohols and esters. Once released into the air, VOCs can undergo reactions with ozone and hydroxyl radicals to produce other VOCs, such as formaldehyde.[46]

    Health effects include eye, nose, and throat irritation; headaches, loss of coordination, nausea; and damage to the liver, kidney, and central nervous system.[48]

    Testing emissions from building materials used indoors has become increasingly common for floor coverings, paints, and many other important indoor building materials and finishes.[49] Indoor materials such as gypsum boards or carpet act as VOC 'sinks', by trapping VOC vapors for extended periods of time, and releasing them by outgassing. The VOCs can also undergo transformation at the surface through interaction with ozone.[42] In both cases, these delayed emissions can result in chronic and low-level exposures to VOCs.[50]

    Several initiatives aim to reduce indoor air contamination by limiting VOC emissions from products. There are regulations in France and in Germany, and numerous voluntary ecolabels and rating systems containing low VOC emissions criteria such as EMICODE,[51] M1,[52] Blue Angel[53] and Indoor Air Comfort[54] in Europe, as well as California Standard CDPH Section 01350[55] and several others in the US. Due to these initiatives an increasing number of low-emitting products became available to purchase.

    At least 18 microbial VOCs (MVOCs) have been characterised[56][57] including 1-octen-3-ol (mushroom alcohol), 3-Methylfuran, 2-pentanol, 2-hexanone, 2-heptanone, 3-octanone, 3-octanol, 2-octen-1-ol, 1-octene, 2-pentanone, 2-nonanone, borneol, geosmin, 1-butanol, 3-methyl-1-butanol, 3-methyl-2-butanol, and thujopsene. The last four are products of Stachybotrys chartarum, which has been linked with sick building syndrome.[56]

    Asbestos fibers

    [edit]

    Many common building materials used before 1975 contain asbestos, such as some floor tiles, ceiling tiles, shingles, fireproofing, heating systems, pipe wrap, taping muds, mastics, and other insulation materials. Normally, significant releases of asbestos fiber do not occur unless the building materials are disturbed, such as by cutting, sanding, drilling, or building remodelling. Removal of asbestos-containing materials is not always optimal because the fibers can be spread into the air during the removal process. A management program for intact asbestos-containing materials is often recommended instead.

    When asbestos-containing material is damaged or disintegrates, microscopic fibers are dispersed into the air. Inhalation of asbestos fibers over long exposure times is associated with increased incidence of lung cancer, mesothelioma, and asbestosis. The risk of lung cancer from inhaling asbestos fibers is significantly greater for smokers. The symptoms of disease do not usually appear until about 20 to 30 years after the first exposure to asbestos.

    Although all asbestos is hazardous, products that are friable, e.g. sprayed coatings and insulation, pose a significantly higher hazard as they are more likely to release fibers to the air.[58]

    Microplastics

    [edit]
    Main article: Microplastics
    See also: Renovation and Particulates

    Microplastic is a type of airborne particulates and is found to prevail in air.[59][60][61][62] A 2017 study found indoor airborne microfiber concentrations between 1.0 and 60.0 microfibers per cubic meter (33% of which were found to be microplastics).[63] Airborne microplastic dust can be produced during renovation, building, bridge and road reconstruction projects[64] and the use of power tools.[65]

    Ozone

    [edit]
    See also: Ground-level ozone

    Indoors ozone (O3) is produced by certain high-voltage electric devices (such as air ionizers), and as a by-product of other types of pollution. It appears in lower concentrations indoors than outdoors, usually at 0.2-0.7 of the outdoor concentration.[66] Typically, most ozone is lost to surface reactions indoors, rather than to reactions in air, due to the large surface to volume ratios found indoors.[67]

    Outdoor air used for ventilation may have sufficient ozone to react with common indoor pollutants as well as skin oils and other common indoor air chemicals or surfaces. Particular concern is warranted when using "green" cleaning products based on citrus or terpene extracts, because these chemicals react very quickly with ozone to form toxic and irritating chemicals[46] as well as fine and ultrafine particles.[68] Ventilation with outdoor air containing elevated ozone concentrations may complicate remediation attempts.[69]

    The WHO standard for ozone concentration is 60 μg/m3 for long-term exposure and 100 μg/m3 as the maximum average over an 8-hour period.[29] The EPA standard for ozone concentration is 0.07 ppm average over an 8-hour period.[70]

    Biological agents

    [edit]

    Mold and other allergens

    [edit]
    Main articles: Indoor mold and Mold health issues

    Occupants in buildings can be exposed to fungal spores, cell fragments, or mycotoxins which can arise from a host of means, but there are two common classes: (a) excess moisture induced growth of mold colonies and (b) natural substances released into the air such as animal dander and plant pollen.[71]

    While mold growth is associated with high moisture levels,[72] it is likely to grow when a combination of favorable conditions arises. As well as high moisture levels, these conditions include suitable temperatures, pH and nutrient sources.[73] Mold grows primarily on surfaces, and it reproduces by releasing spores, which can travel and settle in different locations. When these spores experience appropriate conditions, they can germinate and lead to mycelium growth.[74] Different mold species favor different environmental conditions to germinate and grow, some being more hydrophilic (growing at higher levels of relative humidity) and other more xerophilic (growing at levels of relative humidity as low as 75–80%).[74][75]

    Mold growth can be inhibited by keeping surfaces at conditions that are further from condensation, with relative humidity levels below 75%. This usually translates to a relative humidity of indoor air below 60%, in agreement with the guidelines for thermal comfort that recommend a relative humidity between 40 and 60 %. Moisture buildup in buildings may arise from water penetrating areas of the building envelope or fabric, from plumbing leaks, rainwater or groundwater penetration, or from condensation due to improper ventilation, insufficient heating or poor thermal quality of the building envelope.[76] Even something as simple as drying clothes indoors on radiators can increase the risk of mold growth, if the humidity produced is not able to escape the building via ventilation.[77]

    Mold predominantly affects the airways and lungs. Known effects of mold on health include asthma development and exacerbation,[78] with children and elderly at greater risk of more severe health impacts.[79] Infants in homes with mold have a much greater risk of developing asthma and allergic rhinitis.[80][71] More than half of adult workers in moldy or humid buildings suffer from nasal or sinus symptoms due to mold exposure.[71] Some varieties of mold contain toxic compounds (mycotoxins). However, exposure to hazardous levels of mycotoxin via inhalation is not possible in most cases, as toxins are produced by the fungal body and are not at significant levels in the released spores.

    Legionella

    [edit]

    Legionnaires' disease is caused by a waterborne bacterium Legionella that grows best in slow-moving or still, warm water. The primary route of exposure is through the creation of an aerosol effect, most commonly from evaporative cooling towers or showerheads. A common source of Legionella in commercial buildings is from poorly placed or maintained evaporative cooling towers, which often release water in an aerosol which may enter nearby ventilation intakes. Outbreaks in medical facilities and nursing homes, where patients are immuno-suppressed and immuno-weak, are the most commonly reported cases of Legionellosis. More than one case has involved outdoor fountains at public attractions. The presence of Legionella in commercial building water supplies is highly under-reported, as healthy people require heavy exposure to acquire infection.

    Legionella testing typically involves collecting water samples and surface swabs from evaporative cooling basins, shower heads, faucets/taps, and other locations where warm water collects. The samples are then cultured and colony forming units (cfu) of Legionella are quantified as cfu/liter.

    Legionella is a parasite of protozoans such as amoeba, and thus requires conditions suitable for both organisms. The bacterium forms a biofilm which is resistant to chemical and antimicrobial treatments, including chlorine. Remediation for Legionella outbreaks in commercial buildings vary, but often include very hot water flushes (160 °F (71 °C)), sterilisation of standing water in evaporative cooling basins, replacement of shower heads, and, in some cases, flushes of heavy metal salts. Preventive measures include adjusting normal hot water levels to allow for 120 °F (49 °C) at the tap, evaluating facility design layout, removing faucet aerators, and periodic testing in suspect areas.

    Other bacteria

    [edit]
    Airborne bacteria

    There are many bacteria of health significance found in indoor air and on indoor surfaces. The role of microbes in the indoor environment is increasingly studied using modern gene-based analysis of environmental samples. Currently, efforts are under way to link microbial ecologists and indoor air scientists to forge new methods for analysis and to better interpret the results.[81]

    A large fraction of the bacteria found in indoor air and dust are shed from humans. Among the most important bacteria known to occur in indoor air are Mycobacterium tuberculosis, Staphylococcus aureus, Streptococcus pneumoniae.[citation needed]

    Virus

    [edit]
    Ninth floor layout of the Metropole Hotel in Hong Kong, showing where an outbreak of the severe acute respiratory syndrome (SARS) occurred

    Viruses can also be a concern for indoor air quality. During the 2002–2004 SARS outbreak, virus-laden aerosols were found to have seeped into bathrooms from the bathroom floor drains, exacerbated by the draw of bathroom exhaust fans, resulting in the rapid spread of SARS in Amoy Gardens in Hong Kong.[82][83] Elsewhere in Hong Kong, SARS CoV RNA was found on the carpet and in the air intake vents of the Metropole Hotel, which showed that secondary environmental contamination could generate infectious aerosols and resulted in superspreading events.[84]

    Carbon dioxide

    [edit]

    Humans are the main indoor source of carbon dioxide (CO2) in most buildings. Indoor CO2 levels are an indicator of the adequacy of outdoor air ventilation relative to indoor occupant density and metabolic activity.

    Indoor CO2 levels above 500 ppm can lead to higher blood pressure and heart rate, and increased peripheral blood circulation.[85] With CO2 concentrations above 1000 ppm cognitive performance might be affected, especially when doing complex tasks, making decision making and problem solving slower but not less accurate.[86][87] However, evidence on the health effects of CO2 at lower concentrations is conflicting and it is difficult to link CO2 to health impacts at exposures below 5000 ppm – reported health outcomes may be due to the presence of human bioeffluents, and other indoor air pollutants related to inadequate ventilation.[88]

    Indoor carbon dioxide concentrations can be used to evaluate the quality of a room or a building's ventilation.[89] To eliminate most complaints caused by CO2, the total indoor CO2 level should be reduced to a difference of no greater than 700 ppm above outdoor levels.[90] The National Institute for Occupational Safety and Health (NIOSH) considers that indoor air concentrations of carbon dioxide that exceed 1000 ppm are a marker suggesting inadequate ventilation.[91] The UK standards for schools say that carbon dioxide levels of 800 ppm or lower indicate that the room is well-ventilated.[92] Regulations and standards from around the world show that CO2 levels below 1000 ppm represent good IAQ, between 1000 and 1500 ppm represent moderate IAQ and greater than 1500 ppm represent poor IAQ.[88]

    Carbon dioxide concentrations in closed or confined rooms can increase to 1,000 ppm within 45 minutes of enclosure. For example, in a 3.5-by-4-metre (11 ft × 13 ft) sized office, atmospheric carbon dioxide increased from 500 ppm to over 1,000 ppm within 45 minutes of ventilation cessation and closure of windows and doors.[93]

    Radon

    [edit]
    Main article: Radon

    Radon is an invisible, radioactive atomic gas that results from the radioactive decay of radium, which may be found in rock formations beneath buildings or in certain building materials themselves.

    Radon is probably the most pervasive serious hazard for indoor air in the United States and Europe. It is a major cause of lung cancer, responsible for 3–14% of cases in countries, leading to tens of thousands of deaths.[94]

    Radon gas enters buildings as a soil gas. As it is a heavy gas it will tend to accumulate at the lowest level. Radon may also be introduced into a building through drinking water particularly from bathroom showers. Building materials can be a rare source of radon, but little testing is carried out for stone, rock or tile products brought into building sites; radon accumulation is greatest for well insulated homes.[95] There are simple do-it-yourself kits for radon gas testing, but a licensed professional can also check homes.

    The half-life for radon is 3.8 days, indicating that once the source is removed, the hazard will be greatly reduced within a few weeks. Radon mitigation methods include sealing concrete slab floors, basement foundations, water drainage systems, or by increasing ventilation.[96] They are usually cost effective and can greatly reduce or even eliminate the contamination and the associated health risks.[citation needed]

    Radon is measured in picocuries per liter of air (pCi/L) or becquerel per cubic meter (Bq m-3). Both are measurements of radioactivity. The World Health Organization (WHO) sets the ideal indoor radon levels at 100 Bq/m-3.[97] In the United States, it is recommend to fix homes with radon levels at or above 4 pCi/L. At the same time it is also recommends that people think about fixing their homes for radon levels between 2 pCi/L and 4 pCi/L.[98] In the United Kingdom the ideal is presence of radon indoors is 100 Bq/m-3. Action needs to be taken in homes with 200 Bq/m−3 or more.[99]

    Interactive maps of radon affected areas are available for various regions and countries of the world.[100][101][102]

    IAQ and climate change

    [edit]
    See also: Effects of climate change on human health

    Indoor air quality is linked inextricably to outdoor air quality. The Intergovernmental Panel on Climate Change (IPCC) has varying scenarios that predict how the climate will change in the future.[103] Climate change can affect indoor air quality by increasing the level of outdoor air pollutants such as ozone and particulate matter, for example through emissions from wildfires caused by extreme heat and drought.[104][105] Numerous predictions for how indoor air pollutants will change have been made,[106][107][108][109] and models have attempted to predict how the forecasted IPCC scenarios will vary indoor air quality and indoor comfort parameters such as humidity and temperature.[110]

    The net-zero challenge requires significant changes in the performance of both new and retrofitted buildings. However, increased energy efficient housing will trap pollutants inside, whether produced indoors or outdoors, and lead to an increase in human exposure.[111][112]

    Indoor air quality standards and monitoring

    [edit]

    Quality guidelines and standards

    [edit]

    For occupational exposure, there are standards, which cover a wide range of chemicals, and applied to healthy adults who are exposed over time at workplaces (usually industrial environments).These are published by organisations such as Occupational Safety and Health Administration (OSHA), the National Institute for Occupational Safety and Health (NIOSH), the UK Health and Safety Executive (HSE).

    There is no consensus globally about indoor air quality standards, or health-based guidelines. However, there are regulations from some individual countries and from health organisations. For example, the World Health Organization (WHO) has published health-based global air quality guidelines for the general population that are applicable both to outdoor and indoor air,[29] as well as the WHO IAQ guidelines for selected compounds,[113] whereas the UK Health Security Agency published IAQ guidelines for selected VOCs.[114] The Scientific and Technical Committee (STC34) of the International Society of Indoor Air Quality and Climate (ISIAQ) created an open database that collects indoor environmental quality guidelines worldwide.[115] The database is focused on indoor air quality (IAQ), but is currently extended to include standards, regulations, and guidelines related to ventilation, comfort, acoustics, and lighting.[116][117]

    Real-time monitoring

    [edit]

    Since indoor air pollutants can adversely affect human health, it is important to have real-time indoor air quality assessment/monitoring system that can help not only in the improvement of indoor air quality but also help in detection of leaks, spills in a work environment and boost energy efficiency of buildings by providing real-time feedback to the heating, ventilation, and air conditioning (HVAC) system(s).[118] Additionally, there have been enough studies that highlight the correlation between poor indoor air quality and loss of performance and productivity of workers in an office setting.[119]  

    Combining the Internet of Things (IoT) technology with real-time IAQ monitoring systems has  tremendously gained momentum and popularity as interventions can be done based on the real-time sensor data and thus help in the IAQ improvement.[120]   

    Improvement measures

    [edit]
    See also: Air purifier, Air conditioner, Air filter, Cleanroom, Particulates § Controlling technologies and measures, Pollution control, and Ventilation (architecture)
    Further information: Fan (machine), Dehumidifier, and Heater

    Indoor air quality can be addressed, achieved or maintained during the design of new buildings or as mitigating measures in existing buildings. A hierarchy of measures has been proposed by the Institute of Air Quality Management. It emphasises removing pollutant sources, reducing emissions from any remaining sources, disrupting pathways between sources and the people exposed, protecting people from exposure to pollutants, and removing people from areas with poor air quality.[121]

    A report assisted by the Institute for Occupational Safety and Health of the German Social Accident Insurance can support in the systematic investigation of individual health problems arising at indoor workplaces, and in the identification of practical solutions.[122]

    Source control

    [edit]

    HVAC design

    [edit]
    Main articles: HVAC, Air handler, and Ventilation (architecture)

    Environmentally sustainable design concepts include aspects of commercial and residential heating, ventilation and air-conditioning (HVAC) technologies. Among several considerations, one of the topics attended to is the issue of indoor air quality throughout the design and construction stages of a building's life.[citation needed]

    One technique to reduce energy consumption while maintaining adequate air quality, is demand-controlled ventilation. Instead of setting throughput at a fixed air replacement rate, carbon dioxide sensors are used to control the rate dynamically, based on the emissions of actual building occupants.[citation needed]

    One way of quantitatively ensuring the health of indoor air is by the frequency of effective turnover of interior air by replacement with outside air. In the UK, for example, classrooms are required to have 2.5 outdoor air changes per hour. In halls, gym, dining, and physiotherapy spaces, the ventilation should be sufficient to limit carbon dioxide to 1,500 ppm. In the US, ventilation in classrooms is based on the amount of outdoor air per occupant plus the amount of outdoor air per unit of floor area, not air changes per hour. Since carbon dioxide indoors comes from occupants and outdoor air, the adequacy of ventilation per occupant is indicated by the concentration indoors minus the concentration outdoors. The value of 615 ppm above the outdoor concentration indicates approximately 15 cubic feet per minute of outdoor air per adult occupant doing sedentary office work where outdoor air contains over 400 ppm[123] (global average as of 2023). In classrooms, the requirements in the ASHRAE standard 62.1, Ventilation for Acceptable Indoor Air Quality, would typically result in about 3 air changes per hour, depending on the occupant density. As the occupants are not the only source of pollutants, outdoor air ventilation may need to be higher when unusual or strong sources of pollution exist indoors.

    When outdoor air is polluted, bringing in more outdoor air can actually worsen the overall quality of the indoor air and exacerbate some occupant symptoms related to outdoor air pollution. Generally, outdoor country air is better than indoor city air.[citation needed]

    The use of air filters can trap some of the air pollutants. Portable room air cleaners with HEPA filters can be used if ventilation is poor or outside air has high level of PM 2.5.[122] Air filters are used to reduce the amount of dust that reaches the wet coils.[citation needed] Dust can serve as food to grow molds on the wet coils and ducts and can reduce the efficiency of the coils.[citation needed]

    The use of trickle vents on windows is also valuable to maintain constant ventilation. They can help prevent mold and allergen build up in the home or workplace. They can also reduce the spread of some respiratory infections.[124]

    Moisture management and humidity control requires operating HVAC systems as designed. Moisture management and humidity control may conflict with efforts to conserve energy. For example, moisture management and humidity control requires systems to be set to supply make-up air at lower temperatures (design levels), instead of the higher temperatures sometimes used to conserve energy in cooling-dominated climate conditions. However, for most of the US and many parts of Europe and Japan, during the majority of hours of the year, outdoor air temperatures are cool enough that the air does not need further cooling to provide thermal comfort indoors.[citation needed] However, high humidity outdoors creates the need for careful attention to humidity levels indoors. High humidity give rise to mold growth and moisture indoors is associated with a higher prevalence of occupant respiratory problems.[citation needed]

    The "dew point temperature" is an absolute measure of the moisture in air. Some facilities are being designed with dew points in the lower 50s °F, and some in the upper and lower 40s °F.[citation needed] Some facilities are being designed using desiccant wheels with gas-fired heaters to dry out the wheel enough to get the required dew points.[citation needed] On those systems, after the moisture is removed from the make-up air, a cooling coil is used to lower the temperature to the desired level.[citation needed]

    Commercial buildings, and sometimes residential, are often kept under slightly positive air pressure relative to the outdoors to reduce infiltration. Limiting infiltration helps with moisture management and humidity control.

    Dilution of indoor pollutants with outdoor air is effective to the extent that outdoor air is free of harmful pollutants. Ozone in outdoor air occurs indoors at reduced concentrations because ozone is highly reactive with many chemicals found indoors. The products of the reactions between ozone and many common indoor pollutants include organic compounds that may be more odorous, irritating, or toxic than those from which they are formed. These products of ozone chemistry include formaldehyde, higher molecular weight aldehydes, acidic aerosols, and fine and ultrafine particles, among others. The higher the outdoor ventilation rate, the higher the indoor ozone concentration and the more likely the reactions will occur, but even at low levels, the reactions will take place. This suggests that ozone should be removed from ventilation air, especially in areas where outdoor ozone levels are frequently high.

    Effect of indoor plants

    [edit]
    Spider plants (Chlorophytum comosum) absorb some airborne contaminants.

    Houseplants together with the medium in which they are grown can reduce components of indoor air pollution, particularly volatile organic compounds (VOC) such as benzene, toluene, and xylene. Plants remove CO2 and release oxygen and water, although the quantitative impact for house plants is small. The interest in using potted plants for removing VOCs was sparked by a 1989 NASA study conducted in sealed chambers designed to replicate the environment on space stations. However, these results suffered from poor replication[125] and are not applicable to typical buildings, where outdoor-to-indoor air exchange already removes VOCs at a rate that could only be matched by the placement of 10–1000 plants/m2 of a building's floor space.[126]

    Plants also appear to reduce airborne microbes and molds, and to increase humidity.[127] However, the increased humidity can itself lead to increased levels of mold and even VOCs.[128]

    Since extremely high humidity is associated with increased mold growth, allergic responses, and respiratory responses, the presence of additional moisture from houseplants may not be desirable in all indoor settings if watering is done inappropriately.[129]

    Institutional programs

    [edit]
    EPA graphic about asthma triggers

    The topic of IAQ has become popular due to the greater awareness of health problems caused by mold and triggers to asthma and allergies.

    In the US, the Environmental Protection Agency (EPA) has developed an "IAQ Tools for Schools" program to help improve the indoor environmental conditions in educational institutions. The National Institute for Occupational Safety and Health conducts Health Hazard Evaluations (HHEs) in workplaces at the request of employees, authorized representative of employees, or employers, to determine whether any substance normally found in the place of employment has potentially toxic effects, including indoor air quality.[130]

    A variety of scientists work in the field of indoor air quality, including chemists, physicists, mechanical engineers, biologists, bacteriologists, epidemiologists, and computer scientists. Some of these professionals are certified by organizations such as the American Industrial Hygiene Association, the American Indoor Air Quality Council and the Indoor Environmental Air Quality Council.

    In the UK, under the Department for Environment Food and Rural Affairs, the Air Quality Expert Group considers current knowledge on indoor air quality and provides advice to government and devolved administration ministers.[131]

    At the international level, the International Society of Indoor Air Quality and Climate (ISIAQ), formed in 1991, organizes two major conferences, the Indoor Air and the Healthy Buildings series.[132]

    See also

    [edit]

    References

    [edit]
    1. ^ Carroll, GT; Kirschman, DL; Mammana, A (2022). "Increased CO2 levels in the operating room correlate with the number of healthcare workers present: an imperative for intentional crowd control". Patient Safety in Surgery. 16 (35): 35. doi:10.1186/s13037-022-00343-8. PMC 9672642. PMID 36397098.
    2. ^ ANSI/ASHRAE Standard 62.1, Ventilation for Acceptable Indoor Air Quality, ASHRAE, Inc., Atlanta, GA, US
    3. ^ Belias, Evangelos; Licina, Dusan (2022). "Outdoor PM2. 5 air filtration: optimising indoor air quality and energy". Building & Cities. 3 (1): 186–203. doi:10.5334/bc.153.
    4. ^ KMC Controls (September 24, 2015). "What's Your IQ on IAQ and IEQ?". Archived from the original on April 12, 2021. Retrieved April 12, 2021.[unreliable source?]
    5. ^ Bruce, N; Perez-Padilla, R; Albalak, R (2000). "Indoor air pollution in developing countries: a major environmental and public health challenge". Bulletin of the World Health Organization. 78 (9): 1078–92. PMC 2560841. PMID 11019457.
    6. ^ "Household air pollution and health: fact sheet". WHO. May 8, 2018. Archived from the original on November 12, 2021. Retrieved November 21, 2020.
    7. ^ Ritchie, Hannah; Roser, Max (2019). "Access to Energy". Our World in Data. Archived from the original on November 1, 2021. Retrieved April 1, 2021. According to the Global Burden of Disease study 1.6 million people died prematurely in 2017 as a result of indoor air pollution ... But it's worth noting that the WHO publishes a substantially larger number of indoor air pollution deaths..
    8. ^ Klepeis, Neil E; Nelson, William C; Ott, Wayne R; Robinson, John P; Tsang, Andy M; Switzer, Paul; Behar, Joseph V; Hern, Stephen C; Engelmann, William H (July 2001). "The National Human Activity Pattern Survey (NHAPS): a resource for assessing exposure to environmental pollutants". Journal of Exposure Science & Environmental Epidemiology. 11 (3): 231–252. Bibcode:2001JESEE..11..231K. doi:10.1038/sj.jea.7500165. PMID 11477521. S2CID 22445147. Archived from the original on March 28, 2023. Retrieved March 30, 2024.
    9. ^ U.S. Environmental Protection Agency. Office equipment: design, indoor air emissions, and pollution prevention opportunities. Air and Energy Engineering Research Laboratory, Research Triangle Park, 1995.
    10. ^ U.S. Environmental Protection Agency. Unfinished business: a comparative assessment of environmental problems, EPA-230/2-87-025a-e (NTIS PB88-127030). Office of Policy, Planning and Evaluation, Washington, DC, 1987.
    11. ^ Klepeis, Neil E; Nelson, William C; Ott, Wayne R; Robinson, John P; Tsang, Andy M; Switzer, Paul; Behar, Joseph V; Hern, Stephen C; Engelmann, William H (July 1, 2001). "The National Human Activity Pattern Survey (NHAPS): a resource for assessing exposure to environmental pollutants". Journal of Exposure Science & Environmental Epidemiology. 11 (3): 231–252. Bibcode:2001JESEE..11..231K. doi:10.1038/sj.jea.7500165. ISSN 1559-0631. PMID 11477521. Archived from the original on November 13, 2023. Retrieved November 13, 2023.
    12. ^ "Combined or multiple exposure to health stressors in indoor built environments: an evidence-based review prepared for the WHO training workshop "Multiple environmental exposures and risks": 16–18 October 2013, Bonn, Germany". World Health Organization. Regional Office for Europe. 2014. Archived from the original on November 6, 2023. Retrieved April 10, 2024.
    13. ^ "Household air pollution". World Health Organization. December 15, 2023. Archived from the original on November 12, 2021. Retrieved April 10, 2024.
    14. ^ Clark, Sierra N.; Lam, Holly C. Y.; Goode, Emma-Jane; Marczylo, Emma L.; Exley, Karen S.; Dimitroulopoulou, Sani (August 2, 2023). "The Burden of Respiratory Disease from Formaldehyde, Damp and Mould in English Housing". Environments. 10 (8): 136. doi:10.3390/environments10080136. ISSN 2076-3298.
    15. ^ "Chief Medical Officer (CMO): annual reports". GOV.UK. November 16, 2023. Retrieved May 5, 2024.
    16. ^ "Project information | Indoor air quality at home | Quality standards | NICE". www.nice.org.uk. Retrieved May 5, 2024.
    17. ^ "The inside story: Health effects of indoor air quality on children and young people". RCPCH. Retrieved May 5, 2024.
    18. ^ Halios, Christos H.; Landeg-Cox, Charlotte; Lowther, Scott D.; Middleton, Alice; Marczylo, Tim; Dimitroulopoulou, Sani (September 15, 2022). "Chemicals in European residences – Part I: A review of emissions, concentrations and health effects of volatile organic compounds (VOCs)". Science of the Total Environment. 839: 156201. Bibcode:2022ScTEn.83956201H. doi:10.1016/j.scitotenv.2022.156201. ISSN 0048-9697. PMID 35623519.
    19. ^ "Literature review on chemical pollutants in indoor air in public settings for children and overview of their health effects with a focus on schools, kindergartens and day-care centres". www.who.int. Retrieved May 5, 2024.
    20. ^ Burge, P S (February 2004). "Sick building syndrome". Occupational and Environmental Medicine. 61 (2): 185–190. doi:10.1136/oem.2003.008813. PMC 1740708. PMID 14739390.
    21. ^ Apte, K; Salvi, S (2016). "Household air pollution and its effects on health". F1000Research. 5: 2593. doi:10.12688/f1000research.7552.1. PMC 5089137. PMID 27853506. Burning of natural gas not only produces a variety of gases such as sulfur oxides, mercury compounds, and particulate matter but also leads to the production of nitrogen oxides, primarily nitrogen dioxide...The burning of biomass fuel or any other fossil fuel increases the concentration of black carbon in the air
    22. ^ "Improved Clean Cookstoves". Project Drawdown. February 7, 2020. Archived from the original on December 15, 2021. Retrieved December 5, 2020.
    23. ^ WHO indoor air quality guidelines: household fuel combustion. Geneva: World Health Organization. 2014. ISBN 978-92-4-154888-5.
    24. ^ "Clearing the Air: Gas Cooking and Pollution in European Homes". CLASP. November 8, 2023. Retrieved May 5, 2024.
    25. ^ Seals, Brady; Krasner, Andee. "Gas Stoves: Health and Air Quality Impacts and Solutions". RMI. Retrieved May 5, 2024.
    26. ^ a b c Myers, Isabella (February 2022). The efficient operation of regulation and legislation: An holistic approach to understanding the effect of Carbon Monoxide on mortality (PDF). CO Research Trust.
    27. ^ a b c Penney, David; Benignus, Vernon; Kephalopoulos, Stylianos; Kotzias, Dimitrios; Kleinman, Michael; Verrier, Agnes (2010), "Carbon monoxide", WHO Guidelines for Indoor Air Quality: Selected Pollutants, World Health Organization, ISBN 978-92-890-0213-4, OCLC 696099951, archived from the original on March 8, 2021, retrieved March 18, 2024
    28. ^ "Carbon monoxide: toxicological overview". UK Health Security Agency. May 24, 2022. Retrieved April 17, 2024.
    29. ^ a b c WHO global air quality guidelines: particulate matter (PM2.5 and PM10), ozone, nitrogen dioxide, sulfur dioxide and carbon monoxide (PDF). World Health Organization. 2021. hdl:10665/345329. ISBN 978-92-4-003422-8.[page needed]
    30. ^ a b Soleimani, Farshid; Dobaradaran, Sina; De-la-Torre, Gabriel E.; Schmidt, Torsten C.; Saeedi, Reza (March 2022). "Content of toxic components of cigarette, cigarette smoke vs cigarette butts: A comprehensive systematic review". Science of the Total Environment. 813: 152667. Bibcode:2022ScTEn.81352667S. doi:10.1016/j.scitotenv.2021.152667. PMID 34963586.
    31. ^ "Considering smoking as an air pollution problem for environmental health | Environmental Performance Index". Archived from the original on September 25, 2018. Retrieved March 21, 2018.
    32. ^ Arfaeinia, Hossein; Ghaemi, Maryam; Jahantigh, Anis; Soleimani, Farshid; Hashemi, Hassan (June 12, 2023). "Secondhand and thirdhand smoke: a review on chemical contents, exposure routes, and protective strategies". Environmental Science and Pollution Research. 30 (32): 78017–78029. Bibcode:2023ESPR...3078017A. doi:10.1007/s11356-023-28128-1. PMC 10258487. PMID 37306877.
    33. ^ Arfaeinia, Hossein; Ghaemi, Maryam; Jahantigh, Anis; Soleimani, Farshid; Hashemi, Hassan (June 12, 2023). "Secondhand and thirdhand smoke: a review on chemical contents, exposure routes, and protective strategies". Environmental Science and Pollution Research. 30 (32): 78017–78029. Bibcode:2023ESPR...3078017A. doi:10.1007/s11356-023-28128-1. ISSN 1614-7499. PMC 10258487. PMID 37306877.
    34. ^ Health, CDC's Office on Smoking and (May 9, 2018). "Smoking and Tobacco Use; Fact Sheet; Secondhand Smoke". Smoking and Tobacco Use. Archived from the original on December 15, 2021. Retrieved January 14, 2019.
    35. ^ Fernández, E; Ballbè, M; Sureda, X; Fu, M; Saltó, E; Martínez-Sánchez, JM (December 2015). "Particulate Matter from Electronic Cigarettes and Conventional Cigarettes: a Systematic Review and Observational Study". Current Environmental Health Reports. 2 (4): 423–9. Bibcode:2015CEHR....2..423F. doi:10.1007/s40572-015-0072-x. PMID 26452675.
    36. ^ Vu, Tuan V.; Harrison, Roy M. (May 8, 2019). "Chemical and Physical Properties of Indoor Aerosols". In Harrison, R. M.; Hester, R. E. (eds.). Indoor Air Pollution. The Royal Society of Chemistry (published 2019). ISBN 978-1-78801-803-6.
    37. ^ Abdullahi, Karimatu L.; Delgado-Saborit, Juana Maria; Harrison, Roy M. (February 13, 2013). "Emissions and indoor concentrations of particulate matter and its specific chemical components from cooking: A review". Atmospheric Environment. 71: 260–294. Bibcode:2013AtmEn..71..260A. doi:10.1016/j.atmosenv.2013.01.061. Archived from the original on May 21, 2023. Retrieved April 11, 2024.
    38. ^ Patel, Sameer; Sankhyan, Sumit; Boedicker, Erin K.; DeCarlo, Peter F.; Farmer, Delphine K.; Goldstein, Allen H.; Katz, Erin F.; Nazaroff, William W; Tian, Yilin; Vanhanen, Joonas; Vance, Marina E. (June 16, 2020). "Indoor Particulate Matter during HOMEChem: Concentrations, Size Distributions, and Exposures". Environmental Science & Technology. 54 (12): 7107–7116. Bibcode:2020EnST...54.7107P. doi:10.1021/acs.est.0c00740. ISSN 0013-936X. PMID 32391692. Archived from the original on April 28, 2023. Retrieved April 11, 2024.
    39. ^ Thangavel, Prakash; Park, Duckshin; Lee, Young-Chul (June 19, 2022). "Recent Insights into Particulate Matter (PM2.5)-Mediated Toxicity in Humans: An Overview". International Journal of Environmental Research and Public Health. 19 (12): 7511. doi:10.3390/ijerph19127511. ISSN 1660-4601. PMC 9223652. PMID 35742761.
    40. ^ You, Bo; Zhou, Wei; Li, Junyao; Li, Zhijie; Sun, Yele (November 4, 2022). "A review of indoor Gaseous organic compounds and human chemical Exposure: Insights from Real-time measurements". Environment International. 170: 107611. Bibcode:2022EnInt.17007611Y. doi:10.1016/j.envint.2022.107611. PMID 36335895.
    41. ^ Weschler, Charles J.; Carslaw, Nicola (March 6, 2018). "Indoor Chemistry". Environmental Science & Technology. 52 (5): 2419–2428. Bibcode:2018EnST...52.2419W. doi:10.1021/acs.est.7b06387. ISSN 0013-936X. PMID 29402076. Archived from the original on November 15, 2023. Retrieved April 11, 2024.
    42. ^ a b Carter, Toby J.; Poppendieck, Dustin G.; Shaw, David; Carslaw, Nicola (January 16, 2023). "A Modelling Study of Indoor Air Chemistry: The Surface Interactions of Ozone and Hydrogen Peroxide". Atmospheric Environment. 297: 119598. Bibcode:2023AtmEn.29719598C. doi:10.1016/j.atmosenv.2023.119598.
    43. ^ Tsai, Wen-Tien (March 26, 2019). "An overview of health hazards of volatile organic compounds regulated as indoor air pollutants". Reviews on Environmental Health. 34 (1): 81–89. doi:10.1515/reveh-2018-0046. PMID 30854833.
    44. ^ "U.S. EPA IAQ – Organic chemicals". Epa.gov. August 5, 2010. Archived from the original on September 9, 2015. Retrieved March 2, 2012.
    45. ^ a b Davies, Helen L.; O'Leary, Catherine; Dillon, Terry; Shaw, David R.; Shaw, Marvin; Mehra, Archit; Phillips, Gavin; Carslaw, Nicola (August 14, 2023). "A measurement and modelling investigation of the indoor air chemistry following cooking activities". Environmental Science: Processes & Impacts. 25 (9): 1532–1548. doi:10.1039/D3EM00167A. ISSN 2050-7887. PMID 37609942.
    46. ^ a b c Harding-Smith, Ellen; Shaw, David R.; Shaw, Marvin; Dillon, Terry J.; Carslaw, Nicola (January 23, 2024). "Does green mean clean? Volatile organic emissions from regular versus green cleaning products". Environmental Science: Processes & Impacts. 26 (2): 436–450. doi:10.1039/D3EM00439B. ISSN 2050-7887. PMID 38258874.
    47. ^ Lebel, Eric D.; Michanowicz, Drew R.; Bilsback, Kelsey R.; Hill, Lee Ann L.; Goldman, Jackson S. W.; Domen, Jeremy K.; Jaeger, Jessie M.; Ruiz, Angélica; Shonkoff, Seth B. C. (November 15, 2022). "Composition, Emissions, and Air Quality Impacts of Hazardous Air Pollutants in Unburned Natural Gas from Residential Stoves in California". Environmental Science & Technology. 56 (22): 15828–15838. Bibcode:2022EnST...5615828L. doi:10.1021/acs.est.2c02581. ISSN 0013-936X. PMC 9671046. PMID 36263944.
    48. ^ "Volatile Organic Compounds' Impact on Indoor Air Quality". United States Environmental Protection Agency. August 18, 2014. Retrieved May 23, 2024.
    49. ^ "About VOCs". January 21, 2013. Archived from the original on January 21, 2013. Retrieved September 16, 2019.
    50. ^ Oanh, Nguyen Thi Kim; Hung, Yung-Tse (2005). "Indoor Air Pollution Control". Advanced Air and Noise Pollution Control. Handbook of Environmental Engineering. Vol. 2. pp. 237–272. doi:10.1007/978-1-59259-779-6_7. ISBN 978-1-58829-359-6.
    51. ^ "Emicode". Eurofins.com. Archived from the original on September 24, 2015. Retrieved March 2, 2012.
    52. ^ "M1". Eurofins.com. Archived from the original on September 24, 2015. Retrieved March 2, 2012.
    53. ^ "Blue Angel". Eurofins.com. Archived from the original on September 24, 2015. Retrieved March 2, 2012.
    54. ^ "Indoor Air Comfort". Indoor Air Comfort. Archived from the original on February 1, 2011. Retrieved March 2, 2012.
    55. ^ "CDPH Section 01350". Eurofins.com. Archived from the original on September 24, 2015. Retrieved March 2, 2012.
    56. ^ a b "Smelly Moldy Houses". Archived from the original on December 15, 2021. Retrieved August 2, 2014.
    57. ^ Meruva, N. K.; Penn, J. M.; Farthing, D. E. (November 2004). "Rapid identification of microbial VOCs from tobacco molds using closed-loop stripping and gas chromatography/time-of-flight mass spectrometry". J Ind Microbiol Biotechnol. 31 (10): 482–8. doi:10.1007/s10295-004-0175-0. PMID 15517467. S2CID 32543591.
    58. ^ "Atmospheric carbon dioxide passes 400 ppm everywhere". Physics Today (6): 8170. 2016. Bibcode:2016PhT..2016f8170.. doi:10.1063/pt.5.029904.
    59. ^ Xie Y, Li Y, Feng Y, Cheng W, Wang Y (April 2022). "Inhalable microplastics prevails in air: Exploring the size detection limit". Environ Int. 162: 107151. Bibcode:2022EnInt.16207151X. doi:10.1016/j.envint.2022.107151. PMID 35228011.
    60. ^ Liu C, Li J, Zhang Y, Wang L, Deng J, Gao Y, Yu L, Zhang J, Sun H (July 2019). "Widespread distribution of PET and PC microplastics in dust in urban China and their estimated human exposure". Environ Int. 128: 116–124. Bibcode:2019EnInt.128..116L. doi:10.1016/j.envint.2019.04.024. PMID 31039519.
    61. ^ Yuk, Hyeonseong; Jo, Ho Hyeon; Nam, Jihee; Kim, Young Uk; Kim, Sumin (2022). "Microplastic: A particulate matter(PM) generated by deterioration of building materials". Journal of Hazardous Materials. 437. Elsevier BV: 129290. Bibcode:2022JHzM..43729290Y. doi:10.1016/j.jhazmat.2022.129290. ISSN 0304-3894. PMID 35753297.
    62. ^ Eberhard, Tiffany; Casillas, Gaston; Zarus, Gregory M.; Barr, Dana Boyd (January 6, 2024). "Systematic review of microplastics and nanoplastics in indoor and outdoor air: identifying a framework and data needs for quantifying human inhalation exposures" (PDF). Journal of Exposure Science & Environmental Epidemiology. 34 (2). Springer Science and Business Media LLC: 185–196. doi:10.1038/s41370-023-00634-x. ISSN 1559-0631. Retrieved December 19, 2024. MPs have been found in water and soil, and recent research is exposing the vast amount of them in ambient and indoor air.
    63. ^ Gasperi, Johnny; Wright, Stephanie L.; Dris, Rachid; Collard, France; Mandin, Corinne; Guerrouache, Mohamed; Langlois, Valérie; Kelly, Frank J.; Tassin, Bruno (2018). "Microplastics in air: Are we breathing it in?" (PDF). Current Opinion in Environmental Science & Health. 1: 1–5. Bibcode:2018COESH...1....1G. doi:10.1016/j.coesh.2017.10.002. S2CID 133750509. Archived (PDF) from the original on March 6, 2020. Retrieved July 11, 2019.
    64. ^ Prasittisopin, Lapyote; Ferdous, Wahid; Kamchoom, Viroon (2023). "Microplastics in construction and built environment". Developments in the Built Environment. 15. Elsevier BV. doi:10.1016/j.dibe.2023.100188. ISSN 2666-1659.
    65. ^ Galloway, Nanette LoBiondo (September 13, 2024). "Ventnor introduces ordinance to control microplastics contamination". DownBeach. Retrieved October 2, 2024.
    66. ^ Weschler, Charles J. (December 2000). "Ozone in Indoor Environments: Concentration and Chemistry: Ozone in Indoor Environments". Indoor Air. 10 (4): 269–288. doi:10.1034/j.1600-0668.2000.010004269.x. PMID 11089331. Archived from the original on April 15, 2024. Retrieved April 11, 2024.
    67. ^ Weschler, Charles J.; Nazaroff, William W (February 22, 2023). "Human skin oil: a major ozone reactant indoors". Environmental Science: Atmospheres. 3 (4): 640–661. doi:10.1039/D3EA00008G. ISSN 2634-3606. Archived from the original on April 15, 2024. Retrieved April 11, 2024.
    68. ^ Kumar, Prashant; Kalaiarasan, Gopinath; Porter, Alexandra E.; Pinna, Alessandra; KÅ‚osowski, MichaÅ‚ M.; Demokritou, Philip; Chung, Kian Fan; Pain, Christopher; Arvind, D. K.; Arcucci, Rossella; Adcock, Ian M.; Dilliway, Claire (February 20, 2021). "An overview of methods of fine and ultrafine particle collection for physicochemical characterisation and toxicity assessments". Science of the Total Environment. 756: 143553. Bibcode:2021ScTEn.75643553K. doi:10.1016/j.scitotenv.2020.143553. hdl:10044/1/84518. PMID 33239200. S2CID 227176222.
    69. ^ Apte, M. G.; Buchanan, I. S. H.; Mendell, M. J. (April 2008). "Outdoor ozone and building-related symptoms in the BASE study". Indoor Air. 18 (2): 156–170. Bibcode:2008InAir..18..156A. doi:10.1111/j.1600-0668.2008.00521.x. PMID 18333994.
    70. ^ "Eight-hour Average Ozone Concentrations | Ground-level Ozone | New England | US EPA". United States Environmental Protection Agency. Archived from the original on December 15, 2021. Retrieved September 16, 2019.
    71. ^ a b c Park, J. H.; Cox-Ganser, J. M. (2011). "Meta-Mold exposure and respiratory health in damp indoor environments". Frontiers in Bioscience. 3 (2): 757–771. doi:10.2741/e284. PMID 21196349.
    72. ^ "CDC – Mold – General Information – Facts About Mold and Dampness". December 4, 2018. Archived from the original on December 16, 2019. Retrieved June 23, 2017.
    73. ^ Singh, Dr Jagjit; Singh, Jagjit, eds. (1994). Building Mycology (1 ed.). Taylor & Francis. doi:10.4324/9780203974735. ISBN 978-1-135-82462-4.
    74. ^ a b Clarke, J.A; Johnstone, C.M; Kelly, N.J; McLean, R.C; anderson, J.A; Rowan, N.J; Smith, J.E (January 20, 1999). "A technique for the prediction of the conditions leading to mould growth in buildings". Building and Environment. 34 (4): 515–521. Bibcode:1999BuEnv..34..515C. doi:10.1016/S0360-1323(98)00023-7. Archived from the original on October 26, 2022. Retrieved April 10, 2024.
    75. ^ Vereecken, Evy; Roels, Staf (November 15, 2011). "Review of mould prediction models and their influence on mould risk evaluation". Building and Environment. 51: 296–310. doi:10.1016/j.buildenv.2011.11.003. Archived from the original on March 2, 2024. Retrieved April 11, 2024.
    76. ^ BS 5250:2021 - Management of moisture in buildings. Code of practice. British Standards Institution (BSI). October 31, 2021. ISBN 978-0-539-18975-9.
    77. ^ Madgwick, Della; Wood, Hannah (August 8, 2016). "The problem of clothes drying in new homes in the UK". Structural Survey. 34 (4/5): 320–330. doi:10.1108/SS-10-2015-0048. ISSN 0263-080X. Archived from the original on May 7, 2021. Retrieved April 11, 2024.
    78. ^ May, Neil; McGilligan, Charles; Ucci, Marcella (2017). "Health and Moisture in Buildings" (PDF). UK Centre for Moisture in Buildings. Archived (PDF) from the original on April 11, 2024. Retrieved April 11, 2024.
    79. ^ "Understanding and addressing the health risks of damp and mould in the home". GOV.UK. September 7, 2023. Archived from the original on April 10, 2024. Retrieved April 11, 2024.
    80. ^ Clark, Sierra N.; Lam, Holly C. Y.; Goode, Emma-Jane; Marczylo, Emma L.; Exley, Karen S.; Dimitroulopoulou, Sani (August 2, 2023). "The Burden of Respiratory Disease from Formaldehyde, Damp and Mould in English Housing". Environments. 10 (8): 136. doi:10.3390/environments10080136. ISSN 2076-3298.
    81. ^ Microbiology of the Indoor Environment Archived July 23, 2011, at the Wayback Machine, microbe.net
    82. ^ http://www.info.gov.hk/info/sars/pdf/amoy_e.pdf
    83. ^ https://www.info.gov.hk/info/sars/graphics/amoyannex.jpg
    84. ^ "Progress in Global Surveillance and Response Capacity 10 Years after Severe Acute Respiratory Syndrome". environmental contamination with SARS CoV RNA was identified on the carpet in front of the index case-patient's room and 3 nearby rooms (and on their door frames but not inside the rooms) and in the air intake vents near the centrally located elevators ... secondary infections occurred not in guest rooms but in the common areas of the ninth floor, such as the corridor or elevator hall. These areas could have been contaminated through body fluids (e.g., vomitus, expectorated sputum), respiratory droplets, or suspended small-particle aerosols generated by the index case-patient; other guests were then infected by fomites or aerosols while passing through these same areas. Efficient spread of SARS CoV through small-particle aerosols was observed in several superspreading events in health care settings, during an airplane flight, and in an apartment complex (12–14,16–19). This process of environmental contamination that generated infectious aerosols likely best explains the pattern of disease transmission at the Hotel Metropole.
    85. ^ Azuma, Kenichi; Kagi, Naoki; Yanagi, U.; Osawa, Haruki (December 2018). "Effects of low-level inhalation exposure to carbon dioxide in indoor environments: A short review on human health and psychomotor performance". Environment International. 121 (Pt 1): 51–56. Bibcode:2018EnInt.121...51A. doi:10.1016/j.envint.2018.08.059. PMID 30172928.
    86. ^ Du, Bowen; Tandoc, Michael (June 19, 2020). "Indoor CO2 concentrations and cognitive function: A critical review". International Journal of Indoor Environment and Health. 30 (6): 1067–1082. Bibcode:2020InAir..30.1067D. doi:10.1111/ina.12706. PMID 32557862. S2CID 219915861.
    87. ^ Fan, Yuejie; Cao, Xiaodong; Zhang, Jie; Lai, Dayi; Pang, Liping (June 1, 2023). "Short-term exposure to indoor carbon dioxide and cognitive task performance: A systematic review and meta-analysis". Building and Environment. 237: 110331. Bibcode:2023BuEnv.23710331F. doi:10.1016/j.buildenv.2023.110331.
    88. ^ a b Lowther, Scott D.; Dimitroulopoulou, Sani; Foxall, Kerry; Shrubsole, Clive; Cheek, Emily; Gadeberg, Britta; Sepai, Ovnair (November 16, 2021). "Low Level Carbon Dioxide Indoors—A Pollution Indicator or a Pollutant? A Health-Based Perspective". Environments. 8 (11): 125. doi:10.3390/environments8110125. ISSN 2076-3298.
    89. ^ Persily, Andrew (July 2022). "Development and application of an indoor carbon dioxide metric". Indoor Air. 32 (7): e13059. doi:10.1111/ina.13059. PMID 35904382.
    90. ^ "Indoor Environmental Quality: HVAC Management | NIOSH | CDC". www.cdc.gov. February 25, 2022. Archived from the original on April 1, 2022. Retrieved April 1, 2022.
    91. ^ Indoor Environmental Quality: Building Ventilation Archived January 20, 2022, at the Wayback Machine. National Institute for Occupational Safety and Health. Accessed October 8, 2008.
    92. ^ "SAMHE - Schools' Air quality Monitoring for Health and Education". samhe.org.uk. Archived from the original on March 18, 2024. Retrieved March 18, 2024.
    93. ^ "Document Display | NEPIS | US EPA". nepis.epa.gov. Archived from the original on November 16, 2023. Retrieved October 19, 2023.
    94. ^ Zeeb & Shannoun 2009, p. 3.
    95. ^ C.Michael Hogan and Sjaak Slanina. 2010, Air pollution. Encyclopedia of Earth Archived October 12, 2006, at the Wayback Machine. eds. Sidney Draggan and Cutler Cleveland. National Council for Science and the Environment. Washington DC
    96. ^ "Radon Mitigation Methods". Radon Solution—Raising Radon Awareness. Archived from the original on December 15, 2008. Retrieved December 2, 2008.
    97. ^ Zeeb & Shannoun 2009, p. [page needed].
    98. ^ "Basic radon facts" (PDF). US Environmental Protection Agency. Archived (PDF) from the original on January 13, 2022. Retrieved September 18, 2018. Public Domain This article incorporates text from this source, which is in the public domain.
    99. ^ "Radon Action Level and Target Level". UKradon. Archived from the original on March 18, 2024. Retrieved March 18, 2024.
    100. ^ "Radon Zone Map (with State Information)". U.S. Environmental Protection Agency. Archived from the original on April 1, 2023. Retrieved April 10, 2024.
    101. ^ "UK maps of radon". UKradon. Archived from the original on March 7, 2024. Retrieved April 10, 2024.
    102. ^ "Radon map of Australia". Australian Radiation Protection and Nuclear Safety Agency (ARPANSA). Archived from the original on March 20, 2024. Retrieved April 10, 2024.
    103. ^ "Climate Change 2021: The Physical Science Basis". Intergovernmental Panel on Climate Change. Archived (PDF) from the original on May 26, 2023. Retrieved April 15, 2024.
    104. ^ Chen, Guochao; Qiu, Minghao; Wang, Peng; Zhang, Yuqiang; Shindell, Drew; Zhang, Hongliang (July 19, 2024). "Continuous wildfires threaten public and ecosystem health under climate change across continents". Frontiers of Environmental Science & Engineering. 18 (10). doi:10.1007/s11783-024-1890-6. ISSN 2095-2201.
    105. ^ Gherasim, Alina; Lee, Alison G.; Bernstein, Jonathan A. (November 14, 2023). "Impact of Climate Change on Indoor Air Quality". Immunology and Allergy Clinics of North America. 44 (1): 55–73. doi:10.1016/j.iac.2023.09.001. PMID 37973260. Archived from the original on November 15, 2023. Retrieved April 15, 2024.
    106. ^ Lacressonnière, Gwendoline; Watson, Laura; Gauss, Michael; Engardt, Magnuz; Andersson, Camilla; Beekmann, Matthias; Colette, Augustin; Foret, Gilles; Josse, Béatrice; Marécal, Virginie; Nyiri, Agnes; Siour, Guillaume; Sobolowski, Stefan; Vautard, Robert (February 1, 2017). "Particulate matter air pollution in Europe in a +2 °C warming world". Atmospheric Environment. 154: 129–140. Bibcode:2017AtmEn.154..129L. doi:10.1016/j.atmosenv.2017.01.037. Archived from the original on November 17, 2023. Retrieved April 15, 2024.
    107. ^ Lee, J; Lewis, A; Monks, P; Jacob, M; Hamilton, J; Hopkins, J; Watson, N; Saxton, J; Ennis, C; Carpenter, L (September 26, 2006). "Ozone photochemistry and elevated isoprene during the UK heatwave of august 2003". Atmospheric Environment. 40 (39): 7598–7613. Bibcode:2006AtmEn..40.7598L. doi:10.1016/j.atmosenv.2006.06.057. Archived from the original on October 26, 2022. Retrieved April 15, 2024.
    108. ^ Salthammer, Tunga; Schieweck, Alexandra; Gu, Jianwei; Ameri, Shaghayegh; Uhde, Erik (August 7, 2018). "Future trends in ambient air pollution and climate in Germany – Implications for the indoor environment". Building and Environment. 143: 661–670. Bibcode:2018BuEnv.143..661S. doi:10.1016/j.buildenv.2018.07.050.
    109. ^ Zhong, L.; Lee, C.-S.; Haghighat, F. (December 1, 2016). "Indoor ozone and climate change". Sustainable Cities and Society. 28: 466–472. doi:10.1016/j.scs.2016.08.020. Archived from the original on November 28, 2022. Retrieved April 15, 2024.
    110. ^ Zhao, Jiangyue; Uhde, Erik; Salthammer, Tunga; Antretter, Florian; Shaw, David; Carslaw, Nicola; Schieweck, Alexandra (December 9, 2023). "Long-term prediction of the effects of climate change on indoor climate and air quality". Environmental Research. 243: 117804. doi:10.1016/j.envres.2023.117804. PMID 38042519.
    111. ^ Niculita-Hirzel, Hélène (March 16, 2022). "Latest Trends in Pollutant Accumulations at Threatening Levels in Energy-Efficient Residential Buildings with and without Mechanical Ventilation: A Review". International Journal of Environmental Research and Public Health. 19 (6): 3538. doi:10.3390/ijerph19063538. ISSN 1660-4601. PMC 8951331. PMID 35329223.
    112. ^ UK Health Security Agency (2024) [1 September 2012]. "Chapter 5: Impact of climate change policies on indoor environmental quality and health in UK housing". Health Effects of Climate Change (HECC) in the UK: 2023 report (published January 15, 2024).
    113. ^ World Health Organization, ed. (2010). Who guidelines for indoor air quality: selected pollutants. Copenhagen: WHO. ISBN 978-92-890-0213-4. OCLC 696099951.
    114. ^ "Air quality: UK guidelines for volatile organic compounds in indoor spaces". Public Health England. September 13, 2019. Retrieved April 17, 2024.
    115. ^ "Home - IEQ Guidelines". ieqguidelines.org. Retrieved April 17, 2024.
    116. ^ Toyinbo, Oluyemi; Hägerhed, Linda; Dimitroulopoulou, Sani; Dudzinska, Marzenna; Emmerich, Steven; Hemming, David; Park, Ju-Hyeong; Haverinen-Shaughnessy, Ulla; the Scientific Technical Committee 34 of the International Society of Indoor Air Quality, Climate (April 19, 2022). "Open database for international and national indoor environmental quality guidelines". Indoor Air. 32 (4): e13028. doi:10.1111/ina.13028. ISSN 0905-6947. PMC 11099937. PMID 35481936.cite journal: CS1 maint: numeric names: authors list (link)
    117. ^ Dimitroulopoulou, Sani; DudziÅ„ska, Marzenna R.; Gunnarsen, Lars; Hägerhed, Linda; Maula, Henna; Singh, Raja; Toyinbo, Oluyemi; Haverinen-Shaughnessy, Ulla (August 4, 2023). "Indoor air quality guidelines from across the world: An appraisal considering energy saving, health, productivity, and comfort". Environment International. 178: 108127. Bibcode:2023EnInt.17808127D. doi:10.1016/j.envint.2023.108127. PMID 37544267.
    118. ^ Pitarma, Rui; Marques, Gonçalo; Ferreira, Bárbara Roque (February 2017). "Monitoring Indoor Air Quality for Enhanced Occupational Health". Journal of Medical Systems. 41 (2): 23. doi:10.1007/s10916-016-0667-2. PMID 28000117. S2CID 7372403.
    119. ^ Wyon, D. P. (August 2004). "The effects of indoor air quality on performance and productivity: The effects of IAQ on performance and productivity". Indoor Air. 14: 92–101. doi:10.1111/j.1600-0668.2004.00278.x. PMID 15330777.
    120. ^ Son, Young Joo; Pope, Zachary C.; Pantelic, Jovan (September 2023). "Perceived air quality and satisfaction during implementation of an automated indoor air quality monitoring and control system". Building and Environment. 243: 110713. Bibcode:2023BuEnv.24310713S. doi:10.1016/j.buildenv.2023.110713.
    121. ^ IAQM (2021). Indoor Air Quality Guidance: Assessment, Monitoring, Modelling and Mitigation (PDF) (Version 0.1 ed.). London: Institute of Air Quality Management.
    122. ^ a b Institute for Occupational Safety and Health of the German Social Accident Insurance. "Indoor workplaces – Recommended procedure for the investigation of working environment". Archived from the original on November 3, 2021. Retrieved June 10, 2020.
    123. ^ "Climate Change: Atmospheric Carbon Dioxide | NOAA Climate.gov". www.climate.gov. April 9, 2024. Retrieved May 6, 2024.
    124. ^ "Ventilation to reduce the spread of respiratory infections, including COVID-19". GOV.UK. August 2, 2022. Archived from the original on January 18, 2024. Retrieved April 15, 2024.
    125. ^ Dela Cruz, Majbrit; Christensen, Jan H.; Thomsen, Jane Dyrhauge; Müller, Renate (December 2014). "Can ornamental potted plants remove volatile organic compounds from indoor air? — a review". Environmental Science and Pollution Research. 21 (24): 13909–13928. Bibcode:2014ESPR...2113909D. doi:10.1007/s11356-014-3240-x. PMID 25056742. S2CID 207272189.
    126. ^ Cummings, Bryan E.; Waring, Michael S. (March 2020). "Potted plants do not improve indoor air quality: a review and analysis of reported VOC removal efficiencies". Journal of Exposure Science & Environmental Epidemiology. 30 (2): 253–261. Bibcode:2020JESEE..30..253C. doi:10.1038/s41370-019-0175-9. PMID 31695112. S2CID 207911697.
    127. ^ Wolverton, B. C.; Wolverton, J. D. (1996). "Interior plants: their influence on airborne microbes inside energy-efficient buildings". Journal of the Mississippi Academy of Sciences. 41 (2): 100–105.
    128. ^ US EPA, OAR (July 16, 2013). "Mold". US EPA. Archived from the original on May 18, 2020. Retrieved September 16, 2019.
    129. ^ Institute of Medicine (US) Committee on Damp Indoor Spaces and Health (2004). Damp Indoor Spaces and Health. National Academies Press. ISBN 978-0-309-09193-0. PMID 25009878. Archived from the original on January 19, 2023. Retrieved March 30, 2024.[page needed]
    130. ^ "Indoor Environmental Quality". Washington, DC: US National Institute for Occupational Safety and Health. Archived from the original on December 3, 2013. Retrieved May 17, 2013.
    131. ^ Lewis, Alastair C; Allan, James; Carslaw, David; Carruthers, David; Fuller, Gary; Harrison, Roy; Heal, Mathew; Nemitz, Eiko; Reeves, Claire (2022). Indoor Air Quality (PDF) (Report). Air Quality Expert Group. doi:10.5281/zenodo.6523605. Archived (PDF) from the original on June 5, 2023. Retrieved April 15, 2024.
    132. ^ "Isiaq.Org". International Society of Indoor Air Quality and Climate. Archived from the original on January 21, 2022. Retrieved March 2, 2012.

    Sources

    [edit]
    Monographs
    Articles, radio segments, web pages

    Further reading

    [edit]
    [edit]
     
     
     
     
     

     

    Photo
    Photo
    Photo

    Things To Do in Baldwin County

    Photo

    Dinosaurs In The Woods -- Brontosaurus

    4.4 (368)
    Photo

    Alligator Alley

    4.8 (2582)
    Photo

    Wade Ward Nature Park

    4.4 (139)
    View GBP

    Frequently Asked Questions

    Regular lubrication is essential for HVAC components because it reduces friction between moving parts, which minimizes wear and tear. This helps in maintaining the efficiency and longevity of the system by preventing premature breakdowns and costly repairs.
    Key HVAC parts that typically require lubrication include fan motors, bearings, and blower shafts. The frequency of lubrication depends on the manufacturers recommendations but generally should be done at least once a year during routine maintenance to ensure optimal performance.
    Neglecting regular lubrication can lead to increased friction among moving parts, resulting in overheating, accelerated wear, higher energy consumption, mechanical failure, and ultimately more frequent repairs or replacements. This neglect can significantly reduce both system efficiency and lifespan.