Conducting On Site Safety Assessments Before Mobile Home AC Repairs

Conducting On Site Safety Assessments Before Mobile Home AC Repairs

Importance of Safety in Mobile Home HVAC Work

Understanding Mobile Home HVAC System Components is crucial for anyone involved in conducting on-site safety assessments before undertaking air conditioning repairs. A mobile home's HVAC system, though similar in function to those found in traditional homes, presents unique challenges due to its compact design and often limited access to certain components. Mobile home owners should consider financing options for HVAC upgrades mobile home hvac repair near me screen reader. Awareness of these intricacies not only enhances repair efficiency but also ensures the safety of both the technician and the occupants.


The heart of any mobile home's HVAC system is its air conditioning unit, which typically includes an outdoor condenser, an indoor evaporator coil, and a network of ducts that distribute cooled air throughout the space. However, due to the smaller size and specific layout constraints of mobile homes, these components are often more tightly packed and may require unconventional installation methods. Understanding these differences is vital when assessing the site for potential risks.


Before diving into repairs, conducting a thorough safety assessment is imperative. This process begins with ensuring that all electrical connections are secure and that there are no exposed wires or faulty outlets that could pose an electrocution hazard. Since mobile homes are sometimes older models with outdated electrical systems, this step cannot be overstated. Additionally, checking for refrigerant leaks is critical; not only do they affect the AC unit's efficiency, but they can also be hazardous to health.


Another aspect of pre-repair safety involves examining ductwork for signs of damage or blockage. In mobile homes, ducts are often routed through tight spaces such as floors or ceilings where they might be more susceptible to wear and tear. Ensuring these ducts are intact prevents energy loss and maintains indoor air quality.


Furthermore, technicians should verify that ventilation around the outdoor condenser unit is adequate. Obstructions like plants or debris can impede airflow and lead to overheating or mechanical failure. Given the limited space around most mobile homes, ensuring proper clearance is essential for safe operation.


Finally, it's important to assess environmental factors such as weather conditions before commencing work on a mobile home AC system. Extreme temperatures can affect both equipment performance and technician comfort/safety during repair tasks.


In conclusion, understanding mobile home HVAC components goes hand-in-hand with conducting comprehensive on-site safety assessments prior to AC repairs. By meticulously evaluating electrical systems, checking for leaks or blockages in ductwork, ensuring proper ventilation around units, and considering environmental conditions-technicians not only safeguard themselves but also enhance their ability to deliver effective solutions tailored specifically for mobile homes' unique needs.

Conducting on-site safety assessments before undertaking air conditioning repairs in mobile home environments is a critical step to ensure the safety of both the repair technicians and the residents. Mobile homes, due to their unique structural characteristics, present a distinct set of potential hazards that must be identified and managed effectively during maintenance operations.


Firstly, the structural integrity of mobile homes can vary significantly from traditional houses. Many mobile homes are built with lighter materials and may not always adhere to the same building codes as permanent structures. This can pose risks such as weak flooring or walls, which could collapse under pressure or weight during repairs. Therefore, it's essential for technicians to thoroughly assess the condition of these structures before beginning any work.


Electrical hazards are another significant concern in mobile home environments. The electrical systems in some older mobile homes may not have been updated or might be improperly installed, increasing the risk of electrical shocks or fires during AC repairs. Technicians should inspect wiring and outlets for signs of wear or damage and ensure that power supplies are turned off before starting any electrical work.


Moreover, many mobile homes are elevated on blocks or stilts, creating potential fall hazards. Technicians should use proper ladders and safety gear when accessing roofs or raised areas to prevent falls. Additionally, they should be aware of their surroundings at all times, especially when working near windows or edges where slips could occur.


Ventilation issues also merit attention during safety assessments. Mobile homes may have less effective ventilation systems compared to traditional homes, leading to increased risks from dust, mold, or other pollutants being released into living spaces during repairs. Ensuring that adequate ventilation is maintained throughout the repair process helps protect both workers and residents from respiratory issues.


Finally, environmental factors such as weather conditions can impact safety during AC repairs in mobile home settings. Strong winds or heavy rain can make it unsafe to conduct outdoor work on an AC unit situated on a roof or exterior wall. Planning repairs around favorable weather conditions minimizes these risks.


In conclusion, conducting thorough on-site safety assessments is crucial when preparing for air conditioning repairs in mobile home environments. By identifying potential hazards related to structural integrity, electrical systems, fall risks, poor ventilation, and environmental conditions beforehand, technicians can implement appropriate precautions and strategies ensuring a safe working environment while safeguarding the well-being of those residing within these unique dwellings.

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Essential Safety Gear and Equipment for Technicians

Conducting on-site safety assessments before delving into mobile home air conditioning (AC) repairs is an essential practice that ensures the safety of both technicians and residents. This careful approach not only mitigates potential hazards but also sets the foundation for efficient and effective repair work. To successfully carry out these assessments, a range of safety equipment and tools are required, each playing a crucial role in safeguarding against risks associated with AC systems.


Foremost among the necessary equipment is personal protective gear. Items such as gloves, safety goggles, and steel-toed boots are indispensable. Gloves protect against sharp edges or electrical shocks when handling AC units, while goggles shield eyes from dust and debris during inspections or repairs. Steel-toed boots offer protection against heavy falling objects or accidental impacts, especially in cramped environments typical of mobile homes.


Electrical hazards pose significant risks during AC assessments; hence, voltage testers are vital tools for any technician's arsenal. These devices help determine whether circuits within an AC unit are live, preventing accidental electric shocks that could cause serious injury or even be life-threatening. Additionally, insulated tools should be used to further reduce the risk of electric shock when working around live wires.


Another critical component is a reliable ladder or step stool, which allows technicians to safely reach elevated components of an AC system. Mobile homes often have unique layouts that require accessing units in confined spaces or high locations. Ensuring that ladders are stable and appropriately sized for the task prevents falls-a leading cause of workplace injuries.


Fire extinguishers should always be on hand during these assessments as well. Given the electrical nature of AC systems, there's a potential for sparks to ignite flammable materials nearby. Having a fire extinguisher readily available enables immediate response to small fires before they escalate into more dangerous situations.


Moreover, proper ventilation is crucial when dealing with refrigerants used in AC systems since they can displace oxygen and create hazardous breathing conditions if leaked in enclosed spaces. Ventilation fans may be needed to ensure air circulates adequately during inspection and repair tasks.


Communication devices such as two-way radios can enhance safety by keeping technicians in contact with team members throughout their assessment process-especially important if issues arise that require immediate assistance or evacuation.


In conclusion, conducting on-site safety assessments before engaging in mobile home AC repairs involves careful consideration and preparation with appropriate safety equipment and tools. By equipping themselves properly-from personal protective gear to specialized instruments-technicians can minimize risks inherent in their work environment while maintaining focus on delivering quality service efficiently and safely. This proactive approach underscores not only professional responsibility but also the commitment to preserving health and well-being above all else.

Essential Safety Gear and Equipment for Technicians

Proper Procedures for Handling Refrigerants and Chemicals

Conducting on-site safety assessments before initiating mobile home air conditioning (AC) repairs is an essential practice that ensures both the safety of technicians and the protection of property. Given the unique characteristics and vulnerabilities of mobile homes, such assessments are crucial to identify potential hazards that could compromise repair operations or endanger lives. This step-by-step guide aims to provide a comprehensive approach to conducting thorough safety assessments, ensuring a secure working environment.


Step 1: Preliminary Research and Planning


Before setting foot on site, it's important to gather as much information as possible about the specific mobile home and its AC system. This includes reviewing any available blueprints, past maintenance records, and understanding local regulations that may affect safety protocols. Planning should also involve assembling the necessary tools and protective equipment needed for both assessment and subsequent repairs.


Step 2: Visual Inspection of the Site


Upon arrival, conduct a visual inspection of the surrounding area. Check for any immediate hazards such as unstable ground, overgrown vegetation, or nearby power lines that might interfere with repair activities. Additionally, assess weather conditions as extreme temperatures or inclement weather can significantly impact safety measures during repairs.


Step 3: Assessment of Structural Integrity


Mobile homes are susceptible to wear and tear due to their lightweight construction. Inspect the condition of the structure where the AC unit is installed. Look for signs of water damage, rust, or any structural weaknesses in walls or ceilings that could pose risks during repair tasks. Ensuring the integrity of these elements is vital before proceeding with technical work.


Step 4: Electrical Safety Evaluation


The electrical systems in mobile homes can be complex; therefore, it's imperative to perform a detailed assessment of electrical connections associated with the AC unit. Verify that all wires are properly insulated and that there are no exposed live parts which could lead to electric shock or fire hazards. It's advisable to turn off power at the main breaker before inspecting internal components.


Step 5: Airflow Obstruction Check


Inspect ventilation ducts for blockages caused by dust buildup or foreign objects. Proper airflow is crucial for effective AC operation; obstructions not only hamper efficiency but may also lead to overheating or mechanical failures during repairs. Ensure all vents are clear and functioning correctly.


Step 6: Hazardous Material Identification


Mobile homes may contain hazardous materials like asbestos in older units or refrigerants from outdated AC systems. Identifying these materials early allows you to take appropriate precautions such as using personal protective equipment (PPE) or engaging specialists for safe removal if necessary.


Step 7: Review Safety Protocols with Team


Finally, gather your team for a briefing on identified risks and review standard operating procedures tailored specifically for this job site. Discuss emergency response plans in case of unforeseen incidents during repairs. Ensuring everyone understands their roles enhances communication and coordination throughout the process.


In conclusion, conducting a meticulous on-site safety assessment prior to undertaking AC repairs in mobile homes is indispensable for safeguarding personnel and property alike. By following this structured approach-ranging from preliminary research through comprehensive evaluations-you can mitigate risks effectively while maintaining operational efficiency throughout repair activities.

Electrical Safety Protocols for Mobile Home HVAC Work

In the realm of mobile home maintenance, ensuring safety during air conditioning repairs is paramount. Conducting on-site safety assessments before undertaking such repairs not only safeguards the technicians but also preserves the integrity of the mobile home environment. This process involves a meticulous approach to recording and analyzing safety data, which plays a critical role in identifying potential hazards and implementing preventive measures.


At the heart of these assessments lies a systematic collection of safety data. Technicians begin by surveying the site to identify any immediate risks, such as structural weaknesses or hazardous materials that could pose dangers during repair work. This initial evaluation is crucial as it sets the stage for a comprehensive risk assessment. Once potential hazards are identified, they are meticulously documented, forming the core dataset for further analysis.


The analysis of this safety data involves evaluating both quantitative and qualitative factors. Quantitative data might include measurements of structural stability or levels of harmful substances present in the environment, while qualitative insights could be drawn from previous incident reports or anecdotal evidence from past repairs at similar sites. Advanced analytical tools and methodologies play a vital role here, enabling technicians to predict possible outcomes and devise strategies to mitigate risks effectively.


Moreover, recording and analyzing this data fosters a culture of continuous improvement within maintenance teams. By maintaining detailed records of each assessment, companies can identify patterns or recurring issues that may necessitate changes in procedure or additional training for staff. This proactive approach not only enhances overall safety but also leads to more efficient repair processes by preemptively addressing challenges before they escalate into serious problems.


In summary, conducting on-site safety assessments before mobile home AC repairs is an essential practice rooted in thorough data collection and analysis. By diligently recording potential hazards and employing sophisticated analytical techniques, technicians can ensure both their own safety and that of their clients' homes. This commitment to careful planning and assessment exemplifies best practices in modern maintenance work, highlighting how strategic use of data can lead to safer and more effective service delivery.

Best Practices for Ensuring Structural Integrity During Installation and Maintenance

Implementing Safety Measures Based on Assessment Findings: Conducting On-Site Safety Assessments Before Mobile Home AC Repairs


In the realm of mobile home maintenance, air conditioning (AC) systems are pivotal for ensuring comfort during sweltering summer months. However, before any repair work commences, conducting a thorough on-site safety assessment is essential. This step is not merely a formality but a crucial part of safeguarding both the technicians and residents. Implementing safety measures based on these assessment findings ensures that potential hazards are addressed proactively, thereby minimizing risks associated with AC repairs.


The first stage in this process involves a comprehensive evaluation of the mobile home environment. Unlike traditional homes, mobile homes often present unique challenges due to their structural characteristics and space constraints. Technicians must examine the overall stability of the structure, paying close attention to any signs of wear or damage that could compromise safety during repairs. For instance, weak flooring or unstable support can pose significant risks when heavy equipment is involved.


Electrical assessments are equally vital. Mobile homes typically have different wiring setups compared to stationary houses, which might increase the likelihood of electrical issues when working with AC units. Technicians should meticulously inspect all electrical components for signs of corrosion, fraying wires, or outdated systems that could lead to shorts or fires during repair activities.


Furthermore, assessing ventilation and airflow within the mobile home is key to ensuring safe working conditions for technicians. Given the confined spaces often encountered in such environments, there's an increased risk of poor air circulation leading to overheating or exposure to refrigerant leaks-both potentially hazardous situations. Ensuring adequate ventilation minimizes these dangers and promotes a safer working atmosphere.


Once these assessments have been completed, implementing appropriate safety measures becomes paramount. This includes setting up secure working platforms if elevated areas need accessing and using appropriate personal protective equipment (PPE) such as gloves, goggles, and masks to protect against potential chemical exposure from refrigerants or insulation materials.


Additionally, technicians should communicate findings clearly with homeowners before proceeding with repairs. Educating residents about identified risks not only fosters transparency but also empowers them to take necessary precautions while repairs are ongoing-such as vacating certain areas temporarily or adjusting their routines around repair schedules.


In essence, conducting on-site safety assessments before undertaking mobile home AC repairs is an indispensable practice that serves multiple purposes: it protects those performing the work; it safeguards residents; and it upholds high standards of service quality by addressing potential issues upfront rather than reactively dealing with accidents after they occur.


By prioritizing these evaluations and subsequent implementations diligently-and viewing them as integral parts rather than ancillary tasks-the longevity and efficiency of both repair operations and mobile home AC systems can be significantly enhanced while maintaining utmost safety at every juncture.

In today's rapidly advancing world, the significance of safety cannot be overstated, especially when it comes to conducting repairs on mobile home air conditioning units. Mobile homes present unique challenges due to their compact and often non-traditional construction. Therefore, it is crucial to ensure that repair teams are thoroughly trained and prepared for safe operations. One of the most important aspects of this preparation involves conducting on-site safety assessments before initiating any repair work.


The foundation for a successful and safe repair operation lies in comprehensive training programs that equip technicians with the necessary skills and knowledge. These programs should cover a wide range of topics, from understanding the specific intricacies of mobile home AC systems to mastering safety protocols and emergency response procedures. By investing in such training, companies not only enhance the proficiency of their repair teams but also significantly reduce the risk of accidents or mishaps during operations.


Once a team is well-trained, preparing them for on-site assessments becomes a critical step in ensuring safe operations. Before commencing any repair work, technicians should conduct thorough evaluations of the site conditions. This involves checking for potential hazards such as electrical issues, structural weaknesses in the mobile home, or even environmental factors like extreme weather conditions that could pose risks during repairs.


During these assessments, communication within the team plays a pivotal role. Each member must be aware of their responsibilities and understand how to effectively collaborate with others to maintain safety standards. Clear communication helps in identifying potential dangers early on and allows for prompt corrective actions before they escalate into serious problems.


Another vital component of on-site safety assessments is ensuring that all necessary tools and equipment are available and in proper working condition. Technicians should double-check their gear to avoid unexpected failures while working in potentially hazardous environments. Moreover, wearing appropriate personal protective equipment (PPE) such as gloves, goggles, or helmets can provide an additional layer of security against unforeseen incidents.


Furthermore, documentation is key when it comes to conducting safety assessments. Keeping detailed records of each assessment helps maintain accountability and allows for continuous improvement over time. It also serves as evidence that due diligence was performed prior to undertaking any repair activities.


Ultimately, prioritizing safety through rigorous training programs and meticulous on-site assessments fosters a culture where technicians feel confident yet cautious about their work environments. Such an approach not only safeguards individuals but also upholds company reputations by demonstrating commitment towards responsible business practices.


In conclusion, preparing repair teams through effective training combined with diligent on-site safety assessments before mobile home AC repairs ensures safe operations while minimizing risks associated with complex tasks involved therein-leading ultimately towards successful outcomes benefiting both workers' wellbeing along with customer satisfaction alike!

A DuPont R-134a refrigerant

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

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

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

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

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

History

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

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

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

Phasing out of CFCs

[edit]
See also: Montreal Protocol

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

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

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

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

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

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

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

Addressing greenhouse gases

[edit]

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

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

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

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

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

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

Requirements and desirable properties

[edit]

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

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

Common refrigerants

[edit]

Refrigerants with very low climate impact

[edit]

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

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

Most used

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

Banned / Phased out

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

Other

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

Refrigerant reclamation and disposal

[edit]
Main article: Refrigerant reclamation

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

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

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

Classification of refrigerants

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

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

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

R numbering system

[edit]

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

R-X1X2X3X4

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

Series

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

Ethane Derived Chains

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

Propane Derived Chains

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

Propene derivatives

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

Blends

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

Miscellaneous

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

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

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

Refrigerant safety

[edit]

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

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

See also

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

References

[edit]
  1. ^ United Nations Environment Programme (UNEP). "Update on New Refrigerants Designations and Safety Classifications" (PDF). ASHRAE. Retrieved 6 October 2024.
  2. ^ "Phaseout of Class II Ozone-Depleting Substances". US Environmental Protection Agency. 22 July 2015. Retrieved October 6, 2024.
  3. ^ "Protecting Our Climate by Reducing Use of HFCs". United States Environmental Protection Agency. 8 February 2021. Retrieved 6 October 2024.
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  5. ^ a b c "Finally, a replacement for R123?". Cooling Post. 17 October 2013.
  6. ^ https://asrjetsjournal.org/index.php/American_Scientific_Journal/article/download/3297/1244/
  7. ^ a b Tomczyk, John (1 May 2017). "What's the Latest with R-404A?". achrnews.com.
  8. ^ Molina, Mario J.; Rowland, F. S (28 June 1974). "Stratospheric sink for chlorofluoromethanes: chlorine catalysed destruction of ozone" (PDF). Nature. 249: 810–812. doi:10.1038/249810a0. Retrieved October 6, 2024.
  9. ^ National Research Council (1976). Halocarbons: Effects on Stratospheric Ozone. Washington, DC: The National Academies Press. doi:10.17226/19978. ISBN 978-0-309-02532-4. Retrieved October 6, 2024.
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  26. ^ Kontomaris, Konstantinos (2014). "HFO-1336mzz-Z: High Temperature Chemical Stability and Use as A Working Fluid in Organic Rankine Cycles". International Refrigeration and Air Conditioning Conference. Paper 1525
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  29. ^ "Carrier expands R1234ze chiller range". Cooling Post. 20 May 2020.
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  35. ^ Maté, John (2001). "Making a Difference: A Case Study of the Greenpeace Ozone Campaign". Review of European Community & International Environmental Law. 10 (2): 190–198. doi:10.1111/1467-9388.00275.
  36. ^ Benedick, Richard Elliot Ozone Diplomacy Cambridge, MA: Harvard University 1991.
  37. ^ Honeywell International, Inc. (2010-07-09). "Comment on EPA Proposed Rule Office of Air and Radiation Proposed Significant New Alternatives Policy (SNAP) Protection of Stratospheric Ozone: Listing of Substitutes for Ozone-Depleting Substances – Hydrocarbon Refrigerants" (PDF).
  38. ^ "Discurso de Frank Guggenheim no lançamento do Greenfreeze | Brasil". Greenpeace.org. Archived from the original on 24 September 2015. Retrieved 10 June 2015.
  39. ^ "Der Greenfreeze - endlich in den USA angekommen". Greenpeace.de (in German). 28 December 2011. Retrieved 10 June 2015.
  40. ^ "Complying With The Section 608 Refrigerant Recycling Rule | Ozone Layer Protection - Regulatory Programs". Epa.gov. 21 April 2015. Retrieved 10 June 2015.
  41. ^ a b "Greenfreeze: a Revolution in Domestic Refrigeration". ecomall.com. Retrieved 8 June 2015.
  42. ^ "Company background". Archived from the original on 2020-02-20. Retrieved 2021-03-15.
  43. ^ Safeguarding the ozone layer and the global climate System: issues related to Hydrofluorocarbons and Perfluorocarbons (Report). IPCC/TEAP. 2005.
  44. ^ Crowley, Thomas J. (2000). "Causes of Climate Change over the Past 1000 Years". Science. 289 (5477): 270–277. Bibcode:2000Sci...289..270C. doi:10.1126/science.289.5477.270. PMID 10894770.
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  46. ^ "PepsiCo Brings First Climate-Friendly Vending Machines to the U.S." phx.corporate-ir.net. Retrieved 8 June 2015.
  47. ^ "Climate-Friendly Greenfreezers Come to the United States". WNBC. 2 October 2008. Retrieved 8 June 2015.
  48. ^ Data, Reports and (7 August 2020). "Natural Refrigerants Market To Reach USD 2.88 Billion By 2027 | Reports and Data". GlobeNewswire News Room (Press release). Retrieved 17 December 2020.
  49. ^ Harris, Catharine. "Anti-inhalant Abuse Campaign Targets Building Codes: 'Huffing’ of Air Conditioning Refrigerant a Dangerous Risk." The Nation's Health. American Public Health Association, 2010. Web. 5 December 2010. https://www.thenationshealth.org/content/39/4/20
  50. ^ IPCC AR6 WG1 Ch7 2021
  51. ^ "GreenFreeze". Greenpeace.
  52. ^ "Significant New Alternatives Program: Substitutes in Household Refrigerators and Freezers". Epa.gov. 13 November 2014. Retrieved 4 June 2018.
  53. ^ Berwald, Juli (29 April 2019). "One overlooked way to fight climate change? Dispose of old CFCs". National Geographic - Environment. Archived from the original on April 29, 2019. Retrieved 30 April 2019.
  54. ^ Butler J. and Montzka S. (2020). "The NOAA Annual Greenhouse Gas Index (AGGI)". NOAA Global Monitoring Laboratory/Earth System Research Laboratories.
  55. ^ Environment, U. N. (31 October 2019). "New guidelines for air conditioners and refrigerators set to tackle climate change". UN Environment. Retrieved 30 March 2020.
  56. ^ Rosenthal, Elisabeth; Lehren, Andrew (20 June 2011). "Relief in Every Window, but Global Worry Too". The New York Times. Retrieved 21 June 2012.
  57. ^ a b Yadav et al 2022
  58. ^ a b c BSRIA 2020
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  60. ^ "European Commission on retrofit refrigerants for stationary applications" (PDF). Archived from the original on August 5, 2009. Retrieved 2010-10-29.cite web: CS1 maint: unfit URL (link)
  61. ^ "Protection of Stratospheric Ozone: Hydrocarbon Refrigerants" (PDF). Environment Protection Agency. Retrieved 5 August 2018.
  62. ^ ARB 2022
  63. ^ GM to Introduce HFO-1234yf AC Refrigerant in 2013 US Models
  64. ^ "The Coca-Cola Company Announces Adoption of HFC-Free Insulation in Refrigeration Units to Combat Global Warming". The Coca-Cola Company. 5 June 2006. Archived from the original on 1 November 2013. Retrieved 11 October 2007.
  65. ^ "Modine reinforces its CO2 research efforts". R744.com. 28 June 2007. Archived from the original on 10 February 2008.
  66. ^ Longo, Giovanni A.; Mancin, Simone; Righetti, Giulia; Zilio, Claudio (2015). "HFC32 vaporisation inside a Brazed Plate Heat Exchanger (BPHE): Experimental measurements and IR thermography analysis". International Journal of Refrigeration. 57: 77–86. doi:10.1016/j.ijrefrig.2015.04.017.
  67. ^ May 2010 TEAP XXI/9 Task Force Report
  68. ^ "Protecting Our Climate by Reducing Use of HFCs". US Environmental Protection Agency. 8 February 2021. Retrieved 25 August 2022.
  69. ^ "Background on HFCs and the AIM Act". www.usepa.gov. US EPA. March 2021. Retrieved 27 June 2024.
  70. ^ "1:Update on Ozone-Depleting Substances (ODSs) and Other Gases of Interest to the Montreal Protocol". Scientific assessment of ozone depletion: 2018 (PDF) (Global Ozone Research and Monitoring Project–Report No. 58 ed.). Geneva, Switzerland: World Meteorological Organization. 2018. p. 1.10. ISBN 978-1-7329317-1-8. Retrieved 22 November 2020.
  71. ^ [1] Chemours M099 as R22 Replacement
  72. ^ [2] Management of HCFC-123 through the Phaseout and Beyond | EPA | Published August 2020 | Retrieved Dec. 18, 2021
  73. ^ [3] Refrigerant R11 (R-11), Freon 11 (Freon R-11) Properties & Replacement
  74. ^ [4] R-454B XL41 refrigerant fact & info sheet
  75. ^ [5] R-454B emerges as a replacement for R-410A | ACHR News (Air Conditioning, Heating, Refrigeration News)
  76. ^ [6] Ccarrier introduces [R-454B] Puron Advance™ as the next generation refrigerant for ducted residential, light commercial products in North America | Indianapolis - 19 December 2018
  77. ^ [7] Johnson Controls selects R-454B as future refrigerant for new HVAC equipment | 27 May 2021
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  79. ^ [9] Opteon™ XP30 (R-514A) refrigerant
  80. ^ [10] Trane adopts new low GWP refrigerant R514A | 15 June 2016
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  82. ^ "Frequently Asked Questions on Section 608". Environment Protection Agency. Retrieved 20 December 2013.
  83. ^ "US hydrocarbons". Retrieved 5 August 2018.
  84. ^ "42 U.S. Code § 7671g - National recycling and emission reduction program". LII / Legal Information Institute.
  85. ^ ASHRAE; UNEP (Nov 2022). "Designation and Safety Classification of Refrigerants" (PDF). ASHRAE. Retrieved 1 July 2023.
  86. ^ "Update on New Refrigerants Designations and Safety Classifications" (PDF). American Society of Heating, Refrigerating and Air-Conditioning Engineers (ASHRAE). April 2020. Archived from the original (PDF) on February 13, 2023. Retrieved October 22, 2022.
 

Sources

[edit]

IPCC reports

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

Other

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

 

(Learn how and when to remove this message)
Refrigerant based Fan-Coil Unit. Other variants utilize a chilled, or heated water loop for space cooling, or heating, respectively.
 
 

A fan coil unit (FCU), also known as a Vertical Fan Coil Unit (VFCU), is a device consisting of a heat exchanger (coil) and a fan. FCUs are commonly used in HVAC systems of residential, commercial, and industrial buildings that use ducted split air conditioning or central plant cooling. FCUs are typically connected to ductwork and a thermostat to regulate the temperature of one or more spaces and to assist the main air handling unit for each space if used with chillers. The thermostat controls the fan speed and/or the flow of water or refrigerant to the heat exchanger using a control valve.

Due to their simplicity, flexibility, and easy maintenance, fan coil units can be more economical to install than ducted 100% fresh air systems (VAV) or central heating systems with air handling units or chilled beams. FCUs come in various configurations, including horizontal (ceiling-mounted) and vertical (floor-mounted), and can be used in a wide range of applications, from small residential units to large commercial and industrial buildings.

Noise output from FCUs, like any other form of air conditioning, depends on the design of the unit and the building materials surrounding it. Some FCUs offer noise levels as low as NR25 or NC25.

The output from an FCU can be established by looking at the temperature of the air entering the unit and the temperature of the air leaving the unit, coupled with the volume of air being moved through the unit. This is a simplistic statement, and there is further reading on sensible heat ratios and the specific heat capacity of air, both of which have an effect on thermal performance.

Design and operation

[edit]

Fan Coil Unit covers a range of products and will mean different things to users, specifiers, and installers in different countries and regions, particularly in relation to product size and output capability.

Fan Coil Unit falls principally into two main types: blow through and draw through. As the names suggest, in the first type the fans are fitted behind the heat exchanger, and in the other type the fans are fitted in front the coil such that they draw air through it. Draw through units are considered thermally superior, as ordinarily they make better use of the heat exchanger. However they are more expensive, as they require a chassis to hold the fans whereas a blow-through unit typically consists of a set of fans bolted straight to a coil.

A fan coil unit may be concealed or exposed within the room or area that it serves.

An exposed fan coil unit may be wall-mounted, freestanding or ceiling mounted, and will typically include an appropriate enclosure to protect and conceal the fan coil unit itself, with return air grille and supply air diffuser set into that enclosure to distribute the air.

A concealed fan coil unit will typically be installed within an accessible ceiling void or services zone. The return air grille and supply air diffuser, typically set flush into the ceiling, will be ducted to and from the fan coil unit and thus allows a great degree of flexibility for locating the grilles to suit the ceiling layout and/or the partition layout within a space. It is quite common for the return air not to be ducted and to use the ceiling void as a return air plenum.

The coil receives hot or cold water from a central plant, and removes heat from or adds heat to the air through heat transfer. Traditionally fan coil units can contain their own internal thermostat, or can be wired to operate with a remote thermostat. However, and as is common in most modern buildings with a Building Energy Management System (BEMS), the control of the fan coil unit will be by a local digital controller or outstation (along with associated room temperature sensor and control valve actuators) linked to the BEMS via a communication network, and therefore adjustable and controllable from a central point, such as a supervisors head end computer.

Fan coil units circulate hot or cold water through a coil in order to condition a space. The unit gets its hot or cold water from a central plant, or mechanical room containing equipment for removing heat from the central building's closed-loop. The equipment used can consist of machines used to remove heat such as a chiller or a cooling tower and equipment for adding heat to the building's water such as a boiler or a commercial water heater.

Hydronic fan coil units can be generally divided into two types: Two-pipe fan coil units or four-pipe fan coil units. Two-pipe fan coil units have one supply and one return pipe. The supply pipe supplies either cold or hot water to the unit depending on the time of year. Four-pipe fan coil units have two supply pipes and two return pipes. This allows either hot or cold water to enter the unit at any given time. Since it is often necessary to heat and cool different areas of a building at the same time, due to differences in internal heat loss or heat gains, the four-pipe fan coil unit is most commonly used.

Fan coil units may be connected to piping networks using various topology designs, such as "direct return", "reverse return", or "series decoupled". See ASHRAE Handbook "2008 Systems & Equipment", Chapter 12.

Depending upon the selected chilled water temperatures and the relative humidity of the space, it's likely that the cooling coil will dehumidify the entering air stream, and as a by product of this process, it will at times produce a condensate which will need to be carried to drain. The fan coil unit will contain a purpose designed drip tray with drain connection for this purpose. The simplest means to drain the condensate from multiple fan coil units will be by a network of pipework laid to falls to a suitable point. Alternatively a condensate pump may be employed where space for such gravity pipework is limited.

The fan motors within a fan coil unit are responsible for regulating the desired heating and cooling output of the unit. Different manufacturers employ various methods for controlling the motor speed. Some utilize an AC transformer, adjusting the taps to modulate the power supplied to the fan motor. This adjustment is typically performed during the commissioning stage of building construction and remains fixed for the lifespan of the unit.

Alternatively, certain manufacturers employ custom-wound Permanent Split Capacitor (PSC) motors with speed taps in the windings. These taps are set to the desired speed levels for the specific design of the fan coil unit. To enable local control, a simple speed selector switch (Off-High-Medium-Low) is provided for the occupants of the room. This switch is often integrated into the room thermostat and can be manually set or automatically controlled by a digital room thermostat.

For automatic fan speed and temperature control, Building Energy Management Systems are employed. The fan motors commonly used in these units are typically AC Shaded Pole or Permanent Split Capacitor motors. Recent advancements include the use of brushless DC designs with electronic commutation. Compared to units equipped with asynchronous 3-speed motors, fan coil units utilizing brushless motors can reduce power consumption by up to 70%.[1]

Fan coil units linked to ducted split air conditioning units use refrigerant in the cooling coil instead of chilled coolant and linked to a large condenser unit instead of a chiller. They might also be linked to liquid-cooled condenser units which use an intermediate coolant to cool the condenser using cooling towers.

DC/EC motor powered units

[edit]

These motors are sometimes called DC motors, sometimes EC motors and occasionally DC/EC motors. DC stands for direct current and EC stands for electronically commutated.

DC motors allow the speed of the fans within a fan coil unit to be controlled by means of a 0-10 Volt input control signal to the motor/s, the transformers and speed switches associated with AC fan coils are not required. Up to a signal voltage of 2.5 Volts (which may vary with different fan/motor manufacturers) the fan will be in a stopped condition but as the signal voltage is increased, the fan will seamlessly increase in speed until the maximum is reached at a signal Voltage of 10 Volts. fan coils will generally operate between approximately 4 Volts and 7.5 Volts because below 4 Volts the air volumes are ineffective and above 7.5 Volts the fan coil is likely to be too noisy for most commercial applications.

The 0-10 Volt signal voltage can be set via a simple potentiometer and left or the 0-10 Volt signal voltage can be delivered to the fan motors by the terminal controller on each of the Fan Coil Units. The former is very simple and cheap but the latter opens up the opportunity to continuously alter the fan speed depending on various external conditions/influences. These conditions/criteria could be the 'real time' demand for either heating or cooling, occupancy levels, window switches, time clocks or any number of other inputs from either the unit itself, the Building Management System or both.

The reason that these DC Fan Coil Units are, despite their apparent relative complexity, becoming more popular is their improved energy efficiency levels compared to their AC motor-driven counterparts of only a few years ago. A straight swap, AC to DC, will reduce electrical consumption by 50% but applying Demand and Occupancy dependent fan speed control can take the savings to as much as 80%. In areas of the world where there are legally enforceable energy efficiency requirements for fan coils (such as the UK), DC Fan Coil Units are rapidly becoming the only choice.

Areas of use

[edit]
 
 

In high-rise buildings, fan coils may be vertically stacked, located one above the other from floor to floor and all interconnected by the same piping loop.

Fan coil units are an excellent delivery mechanism for hydronic chiller boiler systems in large residential and light commercial applications. In these applications the fan coil units are mounted in bathroom ceilings and can be used to provide unlimited comfort zones - with the ability to turn off unused areas of the structure to save energy.

Installation

[edit]

In high-rise residential construction, typically each fan coil unit requires a rectangular through-penetration in the concrete slab on top of which it sits. Usually, there are either 2 or 4 pipes made of ABS, steel or copper that go through the floor. The pipes are usually insulated with refrigeration insulation, such as acrylonitrile butadiene/polyvinyl chloride (AB/PVC) flexible foam (Rubatex or Armaflex brands) on all pipes, or at least on the chilled water lines to prevent condensate from forming.

Unit ventilator

[edit]

A unit ventilator is a fan coil unit that is used mainly in classrooms, hotels, apartments and condominium applications. A unit ventilator can be a wall mounted or ceiling hung cabinet, and is designed to use a fan to blow outside air across a coil, thus conditioning and ventilating the space which it is serving.

European market

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The Fan Coil is composed of one quarter of 2-pipe-units and three quarters of 4-pipe-units, and the most sold products are "with casing" (35%), "without casing" (28%), "cassette" (18%) and "ducted" (16%).[2]

The market by region was split in 2010 as follows:

Region Sales Volume in units[2] Share
Benelux 33 725 2.6%
France 168 028 13.2%
Germany 63 256 5.0%
Greece 33 292 2.6%
Italy 409 830 32.1%
Poland 32 987 2.6%
Portugal 22 957 1.8%
Russia, Ukraine and CIS countries 87 054 6.8%
Scandinavia and Baltic countries 39 124 3.1%
Spain 91 575 7.2%
Turkey 70 682 5.5%
UK and Ireland 69 169 5.4%
Eastern Europe 153 847 12.1%

See also

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Wikimedia Commons has media related to Fan coil units.
  • Thermal insulation
  • HVAC
  • Construction
  • Intumescent
  • Firestop

References

[edit]
  1. ^ "Fan Coil Unit". Heinen & Hopman. Retrieved 2023-08-30.
  2. ^ a b "Home". Eurovent Market Intelligence.

 

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Driving Directions From Country Inn & Suites by Radisson, Tulsa, OK to Durham Supply Inc
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Reviews for Durham Supply Inc

Durham Supply Inc

Dennis Champion

(5)

Durham supply and Royal supply seems to find the most helpful and friendly people to work in their stores, we are based out of Kansas City out here for a few remodels and these guys treated us like we've gone there for years.

Durham Supply Inc

Gerald Clifford Brewster

(5)

We will see, the storm door I bought says on the tag it's 36x80, but it's 34x80. If they return it.......they had no problems returning it. And it was no fault of there's, you measure a mobile home door different than a standard door!

Durham Supply Inc

Ethel Schiller

(5)

This place is really neat, if they don't have it they can order it from another of their stores and have it there overnight in most cases. Even hard to find items for a trailer! I definitely recommend this place to everyone! O and the prices is awesome too!

Durham Supply Inc

B Mann

(5)

I was in need of some items for a double wide that I am remodeling and this place is the only place in town that had what I needed ( I didn't even try the other rude place )while I was there I learned the other place that was in Tulsa that also sold mobile home supplies went out of business (no wonder the last time I was in there they were VERY RUDE and high priced) I like the way Dunham does business they answered all my questions and got me the supplies I needed, very friendly, I will be back to purchase the rest of my items when the time comes.

Durham Supply Inc

Ty Spears

(5)

Bought a door/storm door combo. Turns out it was the wrong size. They swapped it out, quick and easy no problems. Very helpful in explaining the size differences from standard door sizes.

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