Exploring County Permit Applications for Mobile Homes

Exploring County Permit Applications for Mobile Homes

Overview of Common Repair Services for Mobile Home HVAC Systems

The installation of HVAC systems in mobile homes is a critical aspect that often gets overlooked during the permit application process. Exploring county permit applications for mobile homes reveals the importance of adhering to proper installation standards to ensure safety, efficiency, and comfort for residents.


Mobile homes, by their nature, require special attention due to their unique structural characteristics. Unlike traditional houses, they are built with different materials and design specifications that can impact how an HVAC system functions. Therefore, ensuring that these systems are correctly installed is pivotal for several reasons.


Firstly, safety is paramount. Professional inspection is necessary before installing a new HVAC unit mobile home hvac near me heat exchanger. Improperly installed HVAC systems can pose significant risks, including carbon monoxide leaks or electrical fires. When applying for a county permit to install such systems in mobile homes, it is crucial that all safety regulations and guidelines are strictly followed. This not only protects the occupants but also ensures compliance with local building codes designed to safeguard the community at large.


Secondly, efficiency is another vital factor. Mobile homes typically have less insulation compared to conventional houses, making them more susceptible to temperature fluctuations. A properly installed HVAC system can drastically improve energy efficiency by maintaining consistent indoor temperatures without overworking the unit. This not only reduces energy consumption but also lowers utility bills for homeowners-a critical consideration given the rising cost of living.


Comfort cannot be underestimated when discussing HVAC installations in mobile homes. Residents deserve a living environment where they can relax comfortably regardless of external weather conditions. Properly sized and installed HVAC systems help achieve this by providing adequate heating or cooling as needed throughout the year.


Furthermore, during the process of exploring county permit applications for mobile home installations, it becomes clear that education plays a key role in successful outcomes. Homeowners and contractors must be aware of specific requirements pertaining to mobile structures and work collaboratively with local authorities who issue permits.


In conclusion, while exploring county permit applications for mobile homes might seem like a bureaucratic hurdle at first glance, it serves an essential purpose in ensuring that HVAC systems are properly installed. By prioritizing safety, efficiency, and comfort through meticulous adherence to regulations during installation processes-and fostering collaboration between stakeholders-mobile home residents can enjoy enhanced quality of life while contributing positively toward wider community welfare goals.

When exploring the intricacies of county permit applications for mobile homes, one critical aspect that often demands attention is the HVAC (Heating, Ventilation, and Air Conditioning) requirements. Given the importance of maintaining a comfortable and safe living environment in mobile homes, counties have established specific guidelines to ensure these systems are up to standard. Understanding these requirements is essential for anyone looking to navigate the permitting process successfully.


At its core, the HVAC system in a mobile home must meet both safety and efficiency standards set by county regulations. These systems are crucial not only for providing comfort but also for ensuring proper air quality and energy efficiency within the dwelling. Consequently, counties typically require detailed documentation when applying for permits related to HVAC installations or upgrades.


Firstly, most counties mandate that any HVAC equipment installed in a mobile home meets certain energy efficiency ratings. This requirement is part of broader efforts to encourage sustainable building practices and reduce energy consumption. Applicants must often provide proof that their chosen equipment complies with these standards, usually through certifications or manufacturer specifications.


Safety considerations are another significant component of HVAC requirements in county permit applications. This includes ensuring that all installations comply with fire safety codes and that ventilation systems are adequate for preventing issues such as carbon monoxide buildup. Proper installation is key; therefore, many counties require that licensed professionals handle HVAC installations or inspections before granting permits.


In addition to equipment specifications and safety compliance, counties may also stipulate conditions regarding maintenance access and system placement within the mobile home property. For instance, there could be restrictions on where external units can be placed or how ductwork should be routed to minimize noise impact or ensure ease of servicing.


Furthermore, some counties might have unique climate considerations influencing their HVAC requirements. For example, regions prone to extreme temperatures could impose additional insulation criteria or mandate specialized heating or cooling solutions tailored to local environmental conditions.


Navigating these diverse requirements can be challenging; thus, it is often beneficial for applicants to consult with local building authorities early in the planning process. These officials can provide guidance on specific county regulations and help identify potential hurdles before they arise during an inspection.


In summary, understanding the overview of HVAC requirements in county permit applications involves recognizing the balance between safety standards and energy efficiency obligations while considering local climate influences. By addressing these elements thoroughly in a permit application for a mobile home, future homeowners can facilitate smoother approval processes and contribute positively towards sustainable living practices within their communities.

Understanding the Cost Breakdown of Mobile Home HVAC Repairs

 Understanding the Cost Breakdown of Mobile Home HVAC Repairs

When faced with the need for HVAC repairs in a mobile home, it's essential to choose a reliable service provider who can effectively address your needs without causing undue financial strain.. Understanding the cost breakdown of these repairs can be an enlightening process that not only helps in budgeting but also ensures you’re getting quality service.

Posted by on 2024-12-27

What to Consider When Budgeting for HVAC Upgrades in Mobile Homes

 What to Consider When Budgeting for HVAC Upgrades in Mobile Homes

When contemplating HVAC upgrades in mobile homes, the decision-making process can be complex and fraught with considerations that might not be immediately apparent.. While the initial impulse may be to rely solely on internet research or anecdotal advice from friends and family, there is immense value in consulting with professionals before making a final decision.

Posted by on 2024-12-27

How Licensing Affects Mobile Home HVAC Installation Costs

 How Licensing Affects Mobile Home HVAC Installation Costs

The installation of HVAC systems in mobile homes can be a complex process, influenced by various factors that vary significantly from one region to another.. One of the primary determinants in this equation is the licensing requirements that differ across states and municipalities, which can have a substantial impact on overall installation costs. Licensing regulations are designed to ensure that HVAC installations meet safety and quality standards.

Posted by on 2024-12-27

Steps to Accurately Estimate Labor Expenses for HVAC Repair Services

Navigating the permit application process for mobile homes can be a daunting task, especially when dealing with county regulations that vary widely across different jurisdictions. While the dream of placing a mobile home in a desired location is enticing, applicants often find themselves entangled in a web of bureaucratic challenges that can delay or even derail their plans. Understanding these common hurdles is essential for anyone looking to successfully secure a permit and move forward with their mobile home installation.


One of the primary challenges faced during the permit application process is understanding and complying with zoning regulations. Zoning laws dictate where mobile homes can be placed, and these rules differ significantly from one county to another. Applicants must thoroughly research and ensure that their intended site falls within an area zoned for mobile homes. This often involves deciphering complex legal language and potentially engaging with local planning boards or zoning officials to clarify any ambiguities.


Another significant obstacle is meeting building code requirements. Mobile homes must adhere to specific standards set forth by local building codes, which aim to ensure safety and structural integrity. These codes may cover everything from electrical wiring and plumbing systems to wind resistance and foundation specifications. Ensuring compliance often requires detailed plans, inspections, and sometimes modifications to the mobile home itself, which can be both time-consuming and costly.


The environmental impact assessment is another layer of complexity that can stymie the permit application process. Many counties require an evaluation of how the placement of a mobile home will affect local ecosystems, including considerations like water drainage, soil erosion, and habitat disruption for local wildlife. Conducting these assessments typically involves hiring environmental consultants or specialists who can provide the necessary reports and documentation.


Financial constraints also play a critical role in complicating the permit acquisition journey. Application fees can be substantial, particularly if multiple permits are required for aspects like electricity hookup or septic system installation. Additionally, unforeseen costs such as land surveys or engineering studies can quickly add up, putting pressure on applicants' budgets.


Lastly, navigating administrative inefficiencies presents its own set of difficulties. County offices responsible for processing permits may suffer from understaffing or outdated systems, leading to delays in review times and communication breakdowns between applicants and officials. This situation can create frustration as applicants await approvals that seem perpetually pending.


In conclusion, while obtaining a permit for placing a mobile home within county lines comes with its fair share of challenges, being well-informed about potential obstacles can better equip applicants to tackle them head-on. By thoroughly researching zoning laws, ensuring compliance with building codes, addressing environmental concerns proactively, budgeting appropriately for all possible costs, and maintaining patience amid bureaucratic processes, individuals stand a greater chance of smoothly navigating through this intricate procedure toward achieving their housing goals.

Steps to Accurately Estimate Labor Expenses for HVAC Repair Services

Tools and Software for Estimating Labor Costs in Mobile Home HVAC Repairs

Navigating the world of local regulations can be a daunting task, especially when it comes to ensuring compliance with HVAC systems in mobile homes. Understanding and adhering to these regulations is crucial for homeowners and builders alike, as non-compliance can lead to costly fines and delays in project completion. This essay explores some essential tips for ensuring compliance with local HVAC regulations, particularly focusing on the process of applying for county permits for mobile homes.


First and foremost, it is vital to conduct thorough research on the specific HVAC regulations that apply in your county or municipality. These rules can vary significantly from one region to another, reflecting differences in climate, environmental concerns, and community standards. Start by visiting your local government's website or contacting their building department directly to gather detailed information about required permits and guidelines for mobile home installations. Many counties provide downloadable resources or guides that outline the necessary steps and requirements.


Once you have a clear understanding of the relevant regulations, it's important to hire qualified professionals who are experienced in working within your area's legal framework. Selecting licensed contractors who specialize in mobile home HVAC systems ensures that they are familiar with current codes and standards. These professionals can help guide you through the permit application process, ensuring all paperwork is completed accurately and submitted promptly.


Another key strategy is maintaining open communication with local authorities throughout your project. Establishing a relationship with county inspectors early on can be incredibly beneficial; they can offer valuable insights into common pitfalls and best practices for meeting compliance standards. Regular consultations with inspectors during different phases of installation allow you to address any issues proactively, avoiding last-minute surprises during final inspections.


In addition to working closely with professionals and inspectors, homeowners should ensure that all documentation related to their HVAC system is meticulously organized. This includes keeping copies of all permits, contracts, warranties, and inspection reports readily accessible. Having an organized file not only simplifies future inspections but also provides protection in case disputes arise regarding compliance issues.


Furthermore, staying informed about any updates or changes in local regulations is crucial for ongoing compliance. Regulatory environments are subject to change as new technologies emerge or as governments respond to environmental challenges. Subscribing to newsletters from relevant industry bodies or joining local trade associations can keep you updated on any such changes that may affect your mobile home's HVAC system.


Finally, consider investing in energy-efficient systems that meet both current standards and potential future requirements. Many counties are increasingly prioritizing sustainability initiatives; thus installing high-efficiency units could foster goodwill with regulatory bodies while also reducing energy costs over time.


In conclusion, successfully navigating county permit applications for mobile homes requires diligence in researching applicable regulations combined with strategic collaboration between qualified professionals and local authorities. By remaining proactive throughout this process-ensuring proper documentation management alongside continuous education-you will not only achieve compliance but also contribute positively towards building safe living environments aligned with community values.

Case Studies: Examples of Labor Cost Estimation in Various Repair Scenarios

Exploring the intricacies of county permit applications for mobile home HVAC systems provides a fascinating glimpse into the intersection of regulatory frameworks and modern living conveniences. Mobile homes, which offer affordable and flexible housing solutions for many, require specific considerations for heating, ventilation, and air conditioning (HVAC) systems. Understanding successful permit approvals in this context not only illuminates best practices but also highlights the collaboration necessary between homeowners, contractors, and local authorities.


At the heart of any successful permit approval process is thorough preparation. This begins with understanding the unique requirements set forth by local counties. Each jurisdiction may have its own set of codes and standards that dictate what is permissible. For example, some counties might emphasize energy efficiency due to environmental concerns, while others focus on safety standards related to installation practices. Homeowners must familiarize themselves with these regulations to ensure that their applications align with local expectations.


A key factor in obtaining a successful permit approval lies in detailed planning and documentation. Applicants should be prepared to provide comprehensive plans that include technical specifications of the proposed HVAC system. These documents often need to demonstrate compliance with specific building codes and safety standards. Moreover, detailing aspects like system capacity relative to home size can assure officials that the unit will operate efficiently without overtaxing electrical systems.


In addition to preparation and documentation, engaging qualified professionals plays a critical role in navigating the permitting landscape effectively. Hiring licensed contractors who are experienced with mobile home installations can significantly streamline the process. These professionals bring invaluable insights into code compliance and have established relationships with county officials who review applications.


Another element contributing to successful permit approvals is proactive communication with county authorities throughout the application process. Establishing an open line of communication can help clarify any ambiguities or address potential concerns before they become obstacles. It's beneficial for applicants to seek feedback from inspectors early on; this collaborative approach fosters trust and ensures that any adjustments needed are identified promptly.


Case studies where mobile home owners have achieved successful HVAC system permits reveal common themes: meticulous attention to detail, reliance on expert advice, proactive engagement with regulators, and adaptability in responding to feedback or changing requirements. For instance, one notable case involved a homeowner who preemptively addressed potential noise concerns associated with an external compressor unit by incorporating sound-dampening materials into their design plan-earning praise from both neighbors and county officials alike.


These success stories underscore a broader narrative about adaptability within regulatory frameworks-highlighting how innovative solutions can satisfy both personal needs and public standards simultaneously. They serve as exemplars for future applicants navigating similar pathways.


In conclusion, exploring case studies around successful permit approvals for mobile home HVAC systems offers valuable lessons about preparation diligence coupled with strategic collaboration among stakeholders involved in permitting processes at various levels-from individual homeowners up through government agencies tasked ensuring community welfare remains paramount amidst evolving technological landscapes inhabited increasingly by alternative housing models such as manufactured homes equipped advanced climate control technologies meeting ever-stringent efficiency mandates worldwide today more than ever before!

Tips for Managing and Reducing Labor Expenses Without Compromising Quality

Navigating the permit application process for mobile homes can often feel like a journey through uncharted territory, especially when dealing with the complexities of county regulations. For those embarking on this path, understanding the resources and support available is crucial to making the journey smoother and more manageable.


The first step in exploring county permit applications for mobile homes involves familiarizing oneself with local zoning laws and building codes. Each county has its own set of regulations that dictate where mobile homes can be placed and under what conditions they must operate. These guidelines are designed to ensure safety, environmental protection, and community standards are upheld. Therefore, reaching out to your county's planning or zoning department is an invaluable resource. These departments typically offer guidance documents or online portals where you can access necessary forms and checklists tailored specifically to mobile home permits.


Additionally, many counties provide workshops or informational sessions aimed at helping applicants understand the intricacies of the permitting process. Attending these sessions offers direct access to experts who can answer questions and clarify any ambiguities regarding application requirements or procedures.


Another beneficial resource is leveraging professional assistance from consultants or contractors who specialize in mobile home installations. These professionals are well-versed in local rules and can assist not only with submitting applications but also ensuring that all technical details meet regulatory standards. Their expertise can prevent costly delays or denials by spotting potential issues before submission.


For those seeking peer advice, engaging with online forums or local community groups dedicated to mobile home living can be incredibly supportive. These platforms allow individuals to share personal experiences, tips, and even provide recommendations for trusted contractors or consultants within your area.


Financial considerations should also not be overlooked in this process. Some counties may have programs offering financial assistance or reduced fee schedules for low-income applicants seeking permits for their mobile homes. It's worthwhile to inquire about these options early on as part of your initial research phase.


Finally, patience and persistence are key virtues throughout this endeavor. The permit application process can be lengthy, involving multiple rounds of reviews and possibly revisions based on feedback from county officials. Keeping organized records of all communications and documentation will help streamline interactions with authorities.


In conclusion, while navigating the permit application process for mobile homes might initially appear daunting due to varying county-specific regulations, there are numerous resources available to aid applicants along the way. By utilizing governmental guidance tools, seeking professional help when needed, connecting with community networks for shared insights, considering financial aid opportunities if applicable, and maintaining a methodical approach throughout the procedure-individuals can significantly enhance their chances of a smooth permitting experience leading them one step closer to settling into their new homes comfortably.

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Sick building syndrome
Specialty Environmental medicine, immunology Edit this on Wikidata

Sick building syndrome (SBS) is a condition in which people develop symptoms of illness or become infected with chronic disease from the building in which they work or reside.[1] In scientific literature, SBS is also known as building-related illness (BRI), building-related symptoms (BRS), or idiopathic environmental intolerance (IEI).

The main identifying observation is an increased incidence of complaints of such symptoms as headache, eye, nose, and throat irritation, fatigue, dizziness, and nausea. The 1989 Oxford English Dictionary defines SBS in that way.[2] The World Health Organization created a 484-page tome on indoor air quality 1984, when SBS was attributed only to non-organic causes, and suggested that the book might form a basis for legislation or litigation.[3]

The outbreaks may or may not be a direct result of inadequate or inappropriate cleaning.[2] SBS has also been used to describe staff concerns in post-war buildings with faulty building aerodynamics, construction materials, construction process, and maintenance.[2] Some symptoms tend to increase in severity with the time people spend in the building, often improving or even disappearing when people are away from the building.[2][4] The term SBS is also used interchangeably with "building-related symptoms", which orients the name of the condition around patients' symptoms rather than a "sick" building.[5]

Attempts have been made to connect sick building syndrome to various causes, such as contaminants produced by outgassing of some building materials, volatile organic compounds (VOC), improper exhaust ventilation of ozone (produced by the operation of some office machines), light industrial chemicals used within, and insufficient fresh-air intake or air filtration (see "Minimum efficiency reporting value").[2] Sick building syndrome has also been attributed to heating, ventilation, and air conditioning (HVAC) systems, an attribution about which there are inconsistent findings.[6]

Signs and symptoms

[edit]
An air quality monitor

Human exposure to aerosols has a variety of adverse health effects.[7] Building occupants complain of symptoms such as sensory irritation of the eyes, nose, or throat; neurotoxic or general health problems; skin irritation; nonspecific hypersensitivity reactions; infectious diseases;[8] and odor and taste sensations.[9] Poor lighting has caused general malaise.[10]

Extrinsic allergic alveolitis has been associated with the presence of fungi and bacteria in the moist air of residential houses and commercial offices.[11] A study in 2017 correlated several inflammatory diseases of the respiratory tract with objective evidence of damp-caused damage in homes.[12]

The WHO has classified the reported symptoms into broad categories, including mucous-membrane irritation (eye, nose, and throat irritation), neurotoxic effects (headaches, fatigue, and irritability), asthma and asthma-like symptoms (chest tightness and wheezing), skin dryness and irritation, and gastrointestinal complaints.[13]

Several sick occupants may report individual symptoms that do not seem connected. The key to discovery is the increased incidence of illnesses in general with onset or exacerbation in a short period, usually weeks. In most cases, SBS symptoms are relieved soon after the occupants leave the particular room or zone.[14] However, there can be lingering effects of various neurotoxins, which may not clear up when the occupant leaves the building. In some cases, including those of sensitive people, there are long-term health effects.[15]

Cause

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ASHRAE has recognized that polluted urban air, designated within the United States Environmental Protection Agency (EPA)'s air quality ratings as unacceptable, requires the installation of treatment such as filtration for which the HVAC practitioners generally apply carbon-impregnated filters and their likes. Different toxins will aggravate the human body in different ways. Some people are more allergic to mold, while others are highly sensitive to dust. Inadequate ventilation will exaggerate small problems (such as deteriorating fiberglass insulation or cooking fumes) into a much more serious indoor air quality problem.[10]

Common products such as paint, insulation, rigid foam, particle board, plywood, duct liners, exhaust fumes and other chemical contaminants from indoor or outdoor sources, and biological contaminants can be trapped inside by the HVAC AC system. As this air is recycled using fan coils the overall oxygenation ratio drops and becomes harmful. When combined with other stress factors such as traffic noise and poor lighting, inhabitants of buildings located in a polluted urban area can quickly become ill as their immune system is overwhelmed.[10]

Certain VOCs, considered toxic chemical contaminants to humans, are used as adhesives in many common building construction products. These aromatic carbon rings / VOCs can cause acute and chronic health effects in the occupants of a building, including cancer, paralysis, lung failure, and others. Bacterial spores, fungal spores, mold spores, pollen, and viruses are types of biological contaminants and can all cause allergic reactions or illness described as SBS. In addition, pollution from outdoors, such as motor vehicle exhaust, can enter buildings, worsen indoor air quality, and increase the indoor concentration of carbon monoxide and carbon dioxide.[16] Adult SBS symptoms were associated with a history of allergic rhinitis, eczema and asthma.[17]

A 2015 study concerning the association of SBS and indoor air pollutants in office buildings in Iran found that, as carbon dioxide increased in a building, nausea, headaches, nasal irritation, dyspnea, and throat dryness also rose.[10] Some work conditions have been correlated with specific symptoms: brighter light, for example was significantly related to skin dryness, eye pain, and malaise.[10] Higher temperature is correlated with sneezing, skin redness, itchy eyes, and headache; lower relative humidity has been associated with sneezing, skin redness, and eye pain.[10]

In 1973, in response to the oil crisis and conservation concerns, ASHRAE Standards 62-73 and 62-81 reduced required ventilation from 10 cubic feet per minute (4.7 L/s) per person to 5 cubic feet per minute (2.4 L/s) per person, but this was found to be a contributing factor to sick building syndrome.[18] As of the 2016 revision, ASHRAE ventilation standards call for 5 to 10 cubic feet per minute of ventilation per occupant (depending on the occupancy type) in addition to ventilation based on the zone floor area delivered to the breathing zone.[19]

Workplace

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Excessive work stress or dissatisfaction, poor interpersonal relationships and poor communication are often seen to be associated with SBS, recent[when?] studies show that a combination of environmental sensitivity and stress can greatly contribute to sick building syndrome.[15][citation needed]

Greater effects were found with features of the psycho-social work environment including high job demands and low support. The report concluded that the physical environment of office buildings appears to be less important than features of the psycho-social work environment in explaining differences in the prevalence of symptoms. However, there is still a relationship between sick building syndrome and symptoms of workers regardless of workplace stress.[20]

Specific work-related stressors are related with specific SBS symptoms. Workload and work conflict are significantly associated with general symptoms (headache, abnormal tiredness, sensation of cold or nausea). While crowded workspaces and low work satisfaction are associated with upper respiratory symptoms.[21] Work productivity has been associated with ventilation rates, a contributing factor to SBS, and there's a significant increase in production as ventilation rates increase, by 1.7% for every two-fold increase of ventilation rate.[22] Printer effluent, released into the office air as ultra-fine particles (UFPs) as toner is burned during the printing process, may lead to certain SBS symptoms.[23][24] Printer effluent may contain a variety of toxins to which a subset of office workers are sensitive, triggering SBS symptoms.[25]

Specific careers are also associated with specific SBS symptoms. Transport, communication, healthcare, and social workers have highest prevalence of general symptoms. Skin symptoms such as eczema, itching, and rashes on hands and face are associated with technical work. Forestry, agriculture, and sales workers have the lowest rates of sick building syndrome symptoms.[26]

From the assessment done by Fisk and Mudarri, 21% of asthma cases in the United States were caused by wet environments with mold that exist in all indoor environments, such as schools, office buildings, houses and apartments. Fisk and Berkeley Laboratory colleagues also found that the exposure to the mold increases the chances of respiratory issues by 30 to 50 percent.[27] Additionally, studies showing that health effects with dampness and mold in indoor environments found that increased risk of adverse health effects occurs with dampness or visible mold environments.[28]

Milton et al. determined the cost of sick leave specific for one business was an estimated $480 per employee, and about five days of sick leave per year could be attributed to low ventilation rates. When comparing low ventilation rate areas of the building to higher ventilation rate areas, the relative risk of short-term sick leave was 1.53 times greater in the low ventilation areas.[29]

Home

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Sick building syndrome can be caused by one's home. Laminate flooring may release more SBS-causing chemicals than do stone, tile, and concrete floors.[17] Recent redecorating and new furnishings within the last year are associated with increased symptoms; so are dampness and related factors, having pets, and cockroaches.[17] Mosquitoes are related to more symptoms, but it is unclear whether the immediate cause of the symptoms is the mosquitoes or the repellents used against them.[17]

Mold

[edit]
Main article: Mold health issues

Sick building syndrome may be associated with indoor mold or mycotoxin contamination. However, the attribution of sick building syndrome to mold is controversial and supported by little evidence.[30][31][32]

Indoor temperature

[edit]
Main article: Room temperature § Health effects

Indoor temperature under 18 °C (64 °F) has been shown to be associated with increased respiratory and cardiovascular diseases, increased blood levels, and increased hospitalization.[33]

Diagnosis

[edit]

While sick building syndrome (SBS) encompasses a multitude of non-specific symptoms, building-related illness (BRI) comprises specific, diagnosable symptoms caused by certain agents (chemicals, bacteria, fungi, etc.). These can typically be identified, measured, and quantified.[34] There are usually four causal agents in BRi: immunologic, infectious, toxic, and irritant.[34] For instance, Legionnaire's disease, usually caused by Legionella pneumophila, involves a specific organism which could be ascertained through clinical findings as the source of contamination within a building.[34]

Prevention

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  • Reduction of time spent in the building
  • If living in the building, moving to a new place
  • Fixing any deteriorated paint or concrete deterioration
  • Regular inspections to indicate for presence of mold or other toxins
  • Adequate maintenance of all building mechanical systems
  • Toxin-absorbing plants, such as sansevieria[35][36][37][38][39][40][41][excessive citations]
  • Roof shingle non-pressure cleaning for removal of algae, mold, and Gloeocapsa magma
  • Using ozone to eliminate the many sources, such as VOCs, molds, mildews, bacteria, viruses, and even odors. However, numerous studies identify high-ozone shock treatment as ineffective despite commercial popularity and popular belief.
  • Replacement of water-stained ceiling tiles and carpeting
  • Only using paints, adhesives, solvents, and pesticides in well-ventilated areas or only using these pollutant sources during periods of non-occupancy
  • Increasing the number of air exchanges; the American Society of Heating, Refrigeration and Air-Conditioning Engineers recommend a minimum of 8.4 air exchanges per 24-hour period
  • Increased ventilation rates that are above the minimum guidelines[22]
  • Proper and frequent maintenance of HVAC systems
  • UV-C light in the HVAC plenum
  • Installation of HVAC air cleaning systems or devices to remove VOCs and bioeffluents (people odors)
  • Central vacuums that completely remove all particles from the house including the ultrafine particles (UFPs) which are less than 0.1 μm
  • Regular vacuuming with a HEPA filter vacuum cleaner to collect and retain 99.97% of particles down to and including 0.3 micrometers
  • Placing bedding in sunshine, which is related to a study done in a high-humidity area where damp bedding was common and associated with SBS[17]
  • Lighting in the workplace should be designed to give individuals control, and be natural when possible[42]
  • Relocating office printers outside the air conditioning boundary, perhaps to another building
  • Replacing current office printers with lower emission rate printers[43]
  • Identification and removal of products containing harmful ingredients

Management

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SBS, as a non-specific blanket term, does not have any specific cause or cure. Any known cure would be associated with the specific eventual disease that was cause by exposure to known contaminants. In all cases, alleviation consists of removing the affected person from the building associated. BRI, on the other hand, utilizes treatment appropriate for the contaminant identified within the building (e.g., antibiotics for Legionnaire's disease).[citation needed]

Improving the indoor air quality (IAQ) of a particular building can attenuate, or even eliminate, the continued exposure to toxins. However, a Cochrane review of 12 mold and dampness remediation studies in private homes, workplaces and schools by two independent authors were deemed to be very low to moderate quality of evidence in reducing adult asthma symptoms and results were inconsistent among children.[44] For the individual, the recovery may be a process involved with targeting the acute symptoms of a specific illness, as in the case of mold toxins.[45] Treating various building-related illnesses is vital to the overall understanding of SBS. Careful analysis by certified building professionals and physicians can help to identify the exact cause of the BRI, and help to illustrate a causal path to infection. With this knowledge one can, theoretically, remediate a building of contaminants and rebuild the structure with new materials. Office BRI may more likely than not be explained by three events: "Wide range in the threshold of response in any population (susceptibility), a spectrum of response to any given agent, or variability in exposure within large office buildings."[46]

Isolating any one of the three aspects of office BRI can be a great challenge, which is why those who find themselves with BRI should take three steps, history, examinations, and interventions. History describes the action of continually monitoring and recording the health of workers experiencing BRI, as well as obtaining records of previous building alterations or related activity. Examinations go hand in hand with monitoring employee health. This step is done by physically examining the entire workspace and evaluating possible threats to health status among employees. Interventions follow accordingly based on the results of the Examination and History report.[46]

Epidemiology

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Some studies have found that women have higher reports of SBS symptoms than men.[17][10] It is not entirely clear, however, if this is due to biological, social, or occupational factors.

A 2001 study published in the Journal Indoor Air, gathered 1464 office-working participants to increase the scientific understanding of gender differences under the Sick Building Syndrome phenomenon.[47] Using questionnaires, ergonomic investigations, building evaluations, as well as physical, biological, and chemical variables, the investigators obtained results that compare with past studies of SBS and gender. The study team found that across most test variables, prevalence rates were different in most areas, but there was also a deep stratification of working conditions between genders as well. For example, men's workplaces tend to be significantly larger and have all-around better job characteristics. Secondly, there was a noticeable difference in reporting rates, specifically that women have higher rates of reporting roughly 20% higher than men. This information was similar to that found in previous studies, thus indicating a potential difference in willingness to report.[47]

There might be a gender difference in reporting rates of sick building syndrome, because women tend to report more symptoms than men do. Along with this, some studies have found that women have a more responsive immune system and are more prone to mucosal dryness and facial erythema. Also, women are alleged by some to be more exposed to indoor environmental factors because they have a greater tendency to have clerical jobs, wherein they are exposed to unique office equipment and materials (example: blueprint machines, toner-based printers), whereas men often have jobs based outside of offices.[48]

History

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In the late 1970s, it was noted that nonspecific symptoms were reported by tenants in newly constructed homes, offices, and nurseries. In media it was called "office illness". The term "sick building syndrome" was coined by the WHO in 1986, when they also estimated that 10–30% of newly built office buildings in the West had indoor air problems. Early Danish and British studies reported symptoms.

Poor indoor environments attracted attention. The Swedish allergy study (SOU 1989:76) designated "sick building" as a cause of the allergy epidemic as was feared. In the 1990s, therefore, extensive research into "sick building" was carried out. Various physical and chemical factors in the buildings were examined on a broad front.

The problem was highlighted increasingly in media and was described as a "ticking time bomb". Many studies were performed in individual buildings.

In the 1990s "sick buildings" were contrasted against "healthy buildings". The chemical contents of building materials were highlighted. Many building material manufacturers were actively working to gain control of the chemical content and to replace criticized additives. The ventilation industry advocated above all more well-functioning ventilation. Others perceived ecological construction, natural materials, and simple techniques as a solution.

At the end of the 1990s came an increased distrust of the concept of "sick building". A dissertation at the Karolinska Institute in Stockholm 1999 questioned the methodology of previous research, and a Danish study from 2005 showed these flaws experimentally. It was suggested that sick building syndrome was not really a coherent syndrome and was not a disease to be individually diagnosed, but a collection of as many as a dozen semi-related diseases. In 2006 the Swedish National Board of Health and Welfare recommended in the medical journal Läkartidningen that "sick building syndrome" should not be used as a clinical diagnosis. Thereafter, it has become increasingly less common to use terms such as sick buildings and sick building syndrome in research. However, the concept remains alive in popular culture and is used to designate the set of symptoms related to poor home or work environment engineering. Sick building is therefore an expression used especially in the context of workplace health.

Sick building syndrome made a rapid journey from media to courtroom where professional engineers and architects became named defendants and were represented by their respective professional practice insurers. Proceedings invariably relied on expert witnesses, medical and technical experts along with building managers, contractors and manufacturers of finishes and furnishings, testifying as to cause and effect. Most of these actions resulted in sealed settlement agreements, none of these being dramatic. The insurers needed a defense based upon Standards of Professional Practice to meet a court decision that declared that in a modern, essentially sealed building, the HVAC systems must produce breathing air for suitable human consumption. ASHRAE (American Society of Heating, Refrigeration and Air Conditioning Engineers, currently with over 50,000 international members) undertook the task of codifying its indoor air quality (IAQ) standard.

ASHRAE empirical research determined that "acceptability" was a function of outdoor (fresh air) ventilation rate and used carbon dioxide as an accurate measurement of occupant presence and activity. Building odors and contaminants would be suitably controlled by this dilution methodology. ASHRAE codified a level of 1,000 ppm of carbon dioxide and specified the use of widely available sense-and-control equipment to assure compliance. The 1989 issue of ASHRAE 62.1-1989 published the whys and wherefores and overrode the 1981 requirements that were aimed at a ventilation level of 5,000 ppm of carbon dioxide (the OSHA workplace limit), federally set to minimize HVAC system energy consumption. This apparently ended the SBS epidemic.

Over time, building materials changed with respect to emissions potential. Smoking vanished and dramatic improvements in ambient air quality, coupled with code compliant ventilation and maintenance, per ASHRAE standards have all contributed to the acceptability of the indoor air environment.[49][50]

See also

[edit]
  • Aerotoxic syndrome
  • Air purifier
  • Asthmagen
  • Cleanroom
  • Electromagnetic hypersensitivity
  • Havana syndrome
  • Healthy building
  • Indoor air quality
  • Lead paint
  • Multiple chemical sensitivity
  • NASA Clean Air Study
  • Nosocomial infection
  • Particulates
  • Power tools
  • Renovation
  • Somatization disorder
  • Fan death

References

[edit]
  1. ^ "Sick Building Syndrome" (PDF). World Health Organization. n.d.
  2. ^ a b c d e Passarelli, Guiseppe Ryan (2009). "Sick building syndrome: An overview to raise awareness". Journal of Building Appraisal. 5: 55–66. doi:10.1057/jba.2009.20.
  3. ^ European Centre for Environment and Health, WHO (1983). WHO guidelines for indoor air quality: selected pollutants (PDF). EURO Reports and Studies, no 78. Bonn Germany Office: WHO Regional Office for Europe (Copenhagen).
  4. ^ Stolwijk, J A (1991-11-01). "Sick-building syndrome". Environmental Health Perspectives. 95: 99–100. doi:10.1289/ehp.919599. ISSN 0091-6765. PMC 1568418. PMID 1821387.
  5. ^ Indoor Air Pollution: An Introduction for Health Professionals (PDF). Indoor Air Division (6609J): U.S. Environmental Protection Agency. c. 2015.cite book: CS1 maint: location (link)
  6. ^ Shahzad, Sally S.; Brennan, John; Theodossopoulos, Dimitris; Hughes, Ben; Calautit, John Kaiser (2016-04-06). "Building-Related Symptoms, Energy, and Thermal Control in the Workplace: Personal and Open Plan Offices". Sustainability. 8 (4): 331. doi:10.3390/su8040331. hdl:20.500.11820/03eb7043-814e-437d-b920-4a38bb88742c.
  7. ^ Sundell, J; Lindval, T; Berndt, S (1994). "Association between type of ventilation and airflow rates in office buildings and the risk of SBS-symptoms among occupants". Environ. Int. 20 (2): 239–251. Bibcode:1994EnInt..20..239S. doi:10.1016/0160-4120(94)90141-4.
  8. ^ Rylander, R (1997). "Investigation of the relationship between disease and airborne (1P3)-b-D-glucan in buildings". Med. Of Inflamm. 6 (4): 275–277. doi:10.1080/09629359791613. PMC 2365865. PMID 18472858.
  9. ^ Godish, Thad (2001). Indoor Environmental Quality. New York: CRC Press. pp. 196–197. ISBN 1-56670-402-2
  10. ^ a b c d e f g Jafari, Mohammad Javad; Khajevandi, Ali Asghar; Mousavi Najarkola, Seyed Ali; Yekaninejad, Mir Saeed; Pourhoseingholi, Mohammad Amin; Omidi, Leila; Kalantary, Saba (2015-01-01). "Association of Sick Building Syndrome with Indoor Air Parameters". Tanaffos. 14 (1): 55–62. ISSN 1735-0344. PMC 4515331. PMID 26221153.
  11. ^ Teculescu, D. B. (1998). "Sick Building Symptoms in office workers in northern France: a pilot study". Int. Arch. Occup. Environ. Health. 71 (5): 353–356. doi:10.1007/s004200050292. PMID 9749975. S2CID 25095874.
  12. ^ Pind C. Ahlroth (2017). "Patient-reported signs of dampness at home may be a risk factor for chronic rhinosinusitis: A cross-sectional study". Clinical & Experimental Allergy. 47 (11): 1383–1389. doi:10.1111/cea.12976. PMID 28695715. S2CID 40807627.
  13. ^ Apter, A (1994). "Epidemiology of the sick building syndrome". J. Allergy Clin. Immunol. 94 (2): 277–288. doi:10.1053/ai.1994.v94.a56006. PMID 8077580.
  14. ^ "Sick Building Syndrome". NSC.org. National Safety Council. 2009. Retrieved April 27, 2009.
  15. ^ a b Joshi, Sumedha M. (August 2008). "The sick building syndrome". Indian Journal of Occupational and Environmental Medicine. 12 (2): 61–64. doi:10.4103/0019-5278.43262. ISSN 0973-2284. PMC 2796751. PMID 20040980.
  16. ^ "Indoor Air Facts No.4: Sick Building Syndrome" (PDF). United States Environmental Protection Agency (EPA). 1991. Retrieved 2009-02-19.
  17. ^ a b c d e f Wang, Juan; Li, BaiZhan; Yang, Qin; Wang, Han; Norback, Dan; Sundell, Jan (2013-12-01). "Sick building syndrome among parents of preschool children in relation to home environment in Chongqing, China". Chinese Science Bulletin. 58 (34): 4267–4276. Bibcode:2013ChSBu..58.4267W. doi:10.1007/s11434-013-5814-2. ISSN 1001-6538.
  18. ^ Joshi S. M. (2008). "The sick building syndrome". Indian J. Occup. Environ. Med. 12 (2): 61–4. doi:10.4103/0019-5278.43262. PMC 2796751. PMID 20040980. in section 3 "Inadequate ventilation".
  19. ^ ANSI/ASHRAE Standard 62.1-2016.
  20. ^ Bauer R. M., Greve K. W., Besch E. L., Schramke C. J., Crouch J., Hicks A., Lyles W. B. (1992). "The role of psychological factors in the report of building-related symptoms in sick building syndrome". Journal of Consulting and Clinical Psychology. 60 (2): 213–219. doi:10.1037/0022-006x.60.2.213. PMID 1592950.cite journal: CS1 maint: multiple names: authors list (link)
  21. ^ Azuma K., Ikeda K., Kagi N., Yanagi U., Osawa H. (2014). "Prevalence and risk factors associated with nonspecific building-related symptoms in office employees in Japan: Relationships between work environment, Indoor Air Quality, and occupational stress". Indoor Air. 25 (5): 499–511. doi:10.1111/ina.12158. PMID 25244340.cite journal: CS1 maint: multiple names: authors list (link)
  22. ^ a b Wargocki P., Wyon D. P., Sundell J., Clausen G., Fanger P. O. (2000). "The Effects of Outdoor Air Supply Rate in an Office on Perceived Air Quality, Sick Building Syndrome (SBS) Symptoms and Productivity". Indoor Air. 10 (4): 222–236. Bibcode:2000InAir..10..222W. doi:10.1034/j.1600-0668.2000.010004222.x. PMID 11089327.cite journal: CS1 maint: multiple names: authors list (link)
  23. ^ Morimoto, Yasuo; Ogami, Akira; Kochi, Isamu; Uchiyama, Tetsuro; Ide, Reiko; Myojo, Toshihiko; Higashi, Toshiaki (2010). "[Continuing investigation of effect of toner and its by-product on human health and occupational health management of toner]". Sangyo Eiseigaku Zasshi = Journal of Occupational Health. 52 (5): 201–208. doi:10.1539/sangyoeisei.a10002. ISSN 1349-533X. PMID 20595787.
  24. ^ Pirela, Sandra Vanessa; Martin, John; Bello, Dhimiter; Demokritou, Philip (September 2017). "Nanoparticle exposures from nano-enabled toner-based printing equipment and human health: state of science and future research needs". Critical Reviews in Toxicology. 47 (8): 678–704. doi:10.1080/10408444.2017.1318354. ISSN 1547-6898. PMC 5857386. PMID 28524743.
  25. ^ McKone, Thomas, et al. "Indoor Pollutant Emissions from Electronic Office Equipment, California Air Resources Board Air Pollution Seminar Series". Presented January 7, 2009. https://www.arb.ca.gov/research/seminars/mckone/mckone.pdf Archived 2017-02-07 at the Wayback Machine
  26. ^ Norback D., Edling C. (1991). "Environmental, occupational, and personal factors related to the prevalence of sick building syndrome in the general population". Occupational and Environmental Medicine. 48 (7): 451–462. doi:10.1136/oem.48.7.451. PMC 1035398. PMID 1854648.
  27. ^ Weinhold, Bob (2007-06-01). "A Spreading Concern: Inhalational Health Effects of Mold". Environmental Health Perspectives. 115 (6): A300–A305. doi:10.1289/ehp.115-a300. PMC 1892134. PMID 17589582.
  28. ^ Mudarri, D.; Fisk, W. J. (June 2007). "Public health and economic impact of dampness and mold". Indoor Air. 17 (3): 226–235. Bibcode:2007InAir..17..226M. doi:10.1111/j.1600-0668.2007.00474.x. ISSN 0905-6947. PMID 17542835. S2CID 21709547.
  29. ^ Milton D. K., Glencross P. M., Walters M. D. (2000). "Risk of Sick Leave Associated with Outdoor Air Supply Rate, Humidification, and Occupant Complaints". Indoor Air. 10 (4): 212–221. Bibcode:2000InAir..10..212M. doi:10.1034/j.1600-0668.2000.010004212.x. PMID 11089326.cite journal: CS1 maint: multiple names: authors list (link)
  30. ^ Straus, David C. (2009). "Molds, mycotoxins, and sick building syndrome". Toxicology and Industrial Health. 25 (9–10): 617–635. Bibcode:2009ToxIH..25..617S. doi:10.1177/0748233709348287. PMID 19854820. S2CID 30720328.
  31. ^ Terr, Abba I. (2009). "Sick Building Syndrome: Is mould the cause?". Medical Mycology. 47: S217–S222. doi:10.1080/13693780802510216. PMID 19255924.
  32. ^ Norbäck, Dan; Zock, Jan-Paul; Plana, Estel; Heinrich, Joachim; Svanes, Cecilie; Sunyer, Jordi; Künzli, Nino; Villani, Simona; Olivieri, Mario; Soon, Argo; Jarvis, Deborah (2011-05-01). "Lung function decline in relation to mould and dampness in the home: the longitudinal European Community Respiratory Health Survey ECRHS II". Thorax. 66 (5): 396–401. doi:10.1136/thx.2010.146613. ISSN 0040-6376. PMID 21325663. S2CID 318027.
  33. ^ WHO Housing and health guidelines. World Health Organization. 2018. pp. 34, 47–48. ISBN 978-92-4-155037-6.
  34. ^ a b c Seltzer, J. M. (1994-08-01). "Building-related illnesses". The Journal of Allergy and Clinical Immunology. 94 (2 Pt 2): 351–361. doi:10.1016/0091-6749(94)90096-5. ISSN 0091-6749. PMID 8077589.
  35. ^ nasa techdoc 19930072988
  36. ^ "Sick Building Syndrome: How indoor plants can help clear the air | University of Technology Sydney".
  37. ^ Wolverton, B. C.; Johnson, Anne; Bounds, Keith (15 September 1989). Interior Landscape Plants for Indoor Air Pollution Abatement (PDF) (Report).
  38. ^ Joshi, S. M (2008). "The sick building syndrome". Indian Journal of Occupational and Environmental Medicine. 12 (2): 61–64. doi:10.4103/0019-5278.43262. PMC 2796751. PMID 20040980.
  39. ^ "Benefits of Office Plants – Tove Fjeld (Agri. Uni. Of Norway)". 2018-05-13.
  40. ^ "NASA: 18 Plants Purify Air, Sick Building Syndrome". 2016-09-20. Archived from the original on 2020-10-26.
  41. ^ "Sick Building Syndrome – How Plants Can Help".
  42. ^ How to deal with sick building syndrome: Guidance for employers, building owners and building managers. (1995). Sudbury: The Executive.
  43. ^ Scungio, Mauro; Vitanza, Tania; Stabile, Luca; Buonanno, Giorgio; Morawska, Lidia (2017-05-15). "Characterization of particle emission from laser printers" (PDF). Science of the Total Environment. 586: 623–630. Bibcode:2017ScTEn.586..623S. doi:10.1016/j.scitotenv.2017.02.030. ISSN 0048-9697. PMID 28196755.
  44. ^ Sauni, Riitta; Verbeek, Jos H; Uitti, Jukka; Jauhiainen, Merja; Kreiss, Kathleen; Sigsgaard, Torben (2015-02-25). Cochrane Acute Respiratory Infections Group (ed.). "Remediating buildings damaged by dampness and mould for preventing or reducing respiratory tract symptoms, infections and asthma". Cochrane Database of Systematic Reviews. 2015 (2): CD007897. doi:10.1002/14651858.CD007897.pub3. PMC 6769180. PMID 25715323.
  45. ^ Indoor Air Facts No. 4 (revised) Sick building syndrome. Available from: [1].
  46. ^ a b Menzies, Dick; Bourbeau, Jean (1997-11-20). "Building-Related Illnesses". New England Journal of Medicine. 337 (21): 1524–1531. doi:10.1056/NEJM199711203372107. ISSN 0028-4793. PMID 9366585.
  47. ^ a b Brasche, S.; Bullinger, M.; Morfeld, M.; Gebhardt, H. J.; Bischof, W. (2001-12-01). "Why do women suffer from sick building syndrome more often than men?--subjective higher sensitivity versus objective causes". Indoor Air. 11 (4): 217–222. Bibcode:2001InAir..11..217B. doi:10.1034/j.1600-0668.2001.110402.x. ISSN 0905-6947. PMID 11761596. S2CID 21579339.
  48. ^ Godish, Thad (2001). Indoor Environmental quality. New York: CRC Press. pp. 196–197. ISBN 1-56670-402-2
  49. ^ "Sick Building Syndrome – Fact Sheet" (PDF). United States Environmental Protection Agency. Retrieved 2013-06-06.
  50. ^ "Sick Building Syndrome". National Health Service, England. Retrieved 2013-06-06.

Further reading

[edit]
  • Martín-Gil J., Yanguas M. C., San José J. F., Rey-Martínez and Martín-Gil F. J. "Outcomes of research into a sick hospital". Hospital Management International, 1997, pp. 80–82. Sterling Publications Limited.
  • Åke Thörn, The Emergence and preservation of sick building syndrome, KI 1999.
  • Charlotte Brauer, The sick building syndrome revisited, Copenhagen 2005.
  • Michelle Murphy, Sick Building Syndrome and the Problem of Uncertainty, 2006.
  • Johan Carlson, "Gemensam förklaringsmodell för sjukdomar kopplade till inomhusmiljön finns inte" [Unified explanation for diseases related to indoor environment not found]. Läkartidningen 2006/12.
  • Bulletin of the Transilvania University of BraÅŸov, Series I: Engineering Sciences • Vol. 5 (54) No. 1 2012 "Impact of Indoor Environment Quality on Sick Building Syndrome in Indian Leed Certified Buildings". by Jagannathan Mohan
[edit]
  • Best Practices for Indoor Air Quality when Remodeling Your Home, US EPA
  • Renovation and Repair, Part of Indoor Air Quality Design Tools for Schools, US EPA
  • Addressing Indoor Environmental Concerns During Remodeling, US EPA
  • Dust FAQs, UK HSE Archived 2023-03-20 at the Wayback Machine
  • CCOHS: Welding - Fumes And Gases | Health Effect of Welding Fumes
 
 
 

 

 

Fenton, Missouri
City
Main Street in Fenton (February 2018)
Main Street in Fenton (February 2018)
Location within St. Louis County, Missouri
Location within St. Louis County, Missouri
Map
Interactive map outlining Fenton
Coordinates: 38°31′39″N 90°26′55″W / 38.52750°N 90.44861°W / 38.52750; -90.44861
Country United States
State Missouri
County St. Louis
Founded 1818
Incorporated 1948
Government
 
 • Mayor Bob Brasses
Area
[1]
 • Total
 6.59 sq mi (17.07 km2)
 • Land 6.27 sq mi (16.24 km2)
 • Water 0.32 sq mi (0.83 km2)
Elevation
[2]
 413 ft (126 m)
Population
 (2020)
 • Total
 3,989
 • Density 636.10/sq mi (245.58/km2)
Demonym(s) Fentonian, Fentonling
Time zone UTC-6 (Central (CST))
 • Summer (DST) UTC-5 (CDT)
Zip code
63026
Area code 636
FIPS code 29-23950
GNIS feature ID 2394757[2]
Website fentonmo.org
Bicycle party resting in Fenton, Missouri, September 12, 1897

Fenton is a city in St. Louis County, Missouri, United States, and a suburb of St. Louis County. The population was 3,989 at the 2020 census.

History

[edit]

Due to its proximity to fertile land and the Meramec River, the Fenton area has been inhabited for over 900 years. The earliest proof of ancient dwellers was excavated from the "Fenton Mounds", two conical earthen burial mounds located near the southwestern border of Fenton. Diagnostic pottery shards from the mounds indicate they date from the Mississippian times, A.D. 1050 - 1400.[3] In 2001, the mounds were leveled, by developer Gary Grewe, for construction of a Walmart Supercenter.[4]

The Fenton territory was occupied by Native Americans and early settlers in the 1770s. William Lindsay Long founded the city of Fenton on March 23, 1818. The original eight-square-block area is now referred to as "Old Towne Fenton". The city remained unincorporated for the next 130 years. Garrett Hitzert was the city's first mayor after incorporation in 1948, and his leadership helped build the foundation that much of the city's ongoing prosperity has been based on. He conceived of Fenton's expansive commercial business and industrial district that is a centerpiece of the city's fiscal success.[5]

Geography

[edit]

Fenton is located approximately two miles south of I-44 along the west bank of the Meramec River. The intersection of Missouri routes 30 and 141 lies just to the west.[6]

According to the United States Census Bureau, the city has a total area of 6.38 square miles (16.52 km2), of which 6.05 square miles (15.67 km2) is land and 0.33 square miles (0.85 km2) is water.[7]

Demographics

[edit]
Historical population
Census Pop. Note
1900 160  
1910 172   7.5%
1920 146   −15.1%
1930 237   62.3%
1940 171   −27.8%
1950 207   21.1%
1960 1,059   411.6%
1970 2,275   114.8%
1980 2,417   6.2%
1990 3,346   38.4%
2000 4,360   30.3%
2010 4,022   −7.8%
2020 3,989   −0.8%
U.S. Decennial Census
2011 estimate

2010 census

[edit]

As of the census[8] of 2010, there were 4,022 people, 1,549 households, and 1,176 families living in the city. The population density was 664.8 inhabitants per square mile (256.7/km2). There were 1,611 housing units at an average density of 266.3 per square mile (102.8/km2). The racial makeup of the city was 95.5% White, 0.4% African American, 0.2% Native American, 2.1% Asian, 0.2% Pacific Islander, 0.3% from other races, and 1.3% from two or more races. Hispanic or Latino of any race were 1.9% of the population.

There were 1,549 households, of which 31.2% had children under the age of 18 living with them, 65.8% were married couples living together, 7.6% had a female householder with no husband present, 2.6% had a male householder with no wife present, and 24.1% were non-families. 19.2% of all households were made up of individuals, and 7.2% had someone living alone who was 65 years of age or older. The average household size was 2.56 and the average family size was 2.94.

The median age in the city was 46.7 years. 21.5% of residents were under the age of 18; 6.5% were between the ages of 18 and 24; 19% were from 25 to 44; 37.3% were from 45 to 64; and 16% were 65 years of age or older. The gender makeup of the city was 48.8% male and 51.2% female.

2000 census

[edit]

As of the census of 2000, there were 4,360 people, 1,587 households, and 1,239 families living in the city. The population density was 710.7 inhabitants per square mile (274.4/km2). There were 1,631 housing units at an average density of 265.9 per square mile (102.7/km2). The racial makeup of the city was 97.98% White, 0.39% African American, 0.16% Native American, 0.94% Asian, 0.18% from other races, and 0.34% from two or more races. Hispanic or Latino of any race were 0.80% of the population.

There were 1,587 households, out of which 35.2% had children under the age of 18 living with them, 68.7% were married couples living together, 6.7% had a female householder with no husband present, and 21.9% were non-families. 18.1% of all households were made up of individuals, and 5.7% had someone living alone who was 65 years of age or older. The average household size was 2.72 and the average family size was 3.11.

In the city, the population was spread out, with 25.5% under the age of 18, 7.5% from 18 to 24, 26.8% from 25 to 44, 29.1% from 45 to 64, and 11.1% who were 65 years of age or older. The median age was 40 years. For every 100 females, there were 96.5 males. For every 100 females age 18 and over, there were 92.0 males.

The median income for a household in the city was $74,708, and the median income for a family was $80,536. Males had a median income of $56,425 versus $34,514 for females. The per capita income for the city was $29,658. About 0.6% of families and 2.1% of the population were below the poverty line, including 1.8% of those under age 18 and 3.8% of those age 65 or over.

Economy

[edit]

Major corporations in the city include Tacony Corporation and Nooter Eriksen Corporation (makers of industrial equipment), Sachs Electric, UniGroup (owners of United Van Lines and Mayflower Transit, Wolff Shoe, Maritz, Fabick Caterpillar, and 8th Avenue Food & Provisions. Retail Technology Group, a major national point-of-sale supplier, is based in Fenton. Fenton contains a large industrial park and a newly developed logistics park located on the former Chrysler Assembly site.[citation needed]

Chrysler

[edit]
Main article: Saint Louis Assembly

The former Chrysler North and South assembly plants were located on North Highway Drive in Fenton. Opened in 1959 and easily visible from Interstate 44, the Chrysler plant was a cornerstone of the Fenton economy for decades. A residential area was even built near the plant with street names like Fury, Imperial, Dart, and Valiant. In its later years, the South plant assembled Chrysler minivans such as the Chrysler Town & Country and the Dodge Grand Caravan, while the North plant assembled the Dodge Ram truck. The South plant ceased operations in 2008, while the North plant shut down for good in July 2009. In 2013 the site was considered as a possible location for a new stadium for the St. Louis Rams if renovations to the Edward Jones Dome did not materialize.[9] In 2014 a local St. Louis real estate developer purchased the empty 300-acre lot to develop 240 acres of offices, businesses, and industrial buildings, with the remaining 60 acres primarily designated for retail use.[10]

Athletics

[edit]

The immediate Fenton area is home to some of the most prestigious youth soccer clubs in the nation. The St. Louis Soccer Park abuts the Fenton city limits. It hosts multiple professional and semi-professional soccer matches. St. Louis Soccer Park has hosted several United States qualifier games for both the 1988 Summer Olympics and the 1990 FIFA World Cup. The Saint Louis FC of the USL Championship play their home games at St. Louis Soccer Park. St. Louis Soccer Park is home to SLSG, a soccer academy founded and coached by Scott Gallagher. In 2012, the U18 team from SLSG played a match against the US Soccer U18 team. Fenton itself is home to the Fenton Athletic Association. Ice hockey is also a popular sport in Fenton. The Fenton Forum is home to the Rockwood Summit Falcons ice hockey team as well as the Affton Americans youth and Tier II ice hockey clubs for many home games. Every year, the Missouri Fall Face-Off NCAA lacrosse competition takes place in Fenton.

Parks

[edit]

Fenton is called the "City of Parks" owing to its extensive park and recreation system. The City has seven fully developed parks on 350-plus acres, including soccer fields, ball diamonds, sand volleyball courts, basketball courts, tennis courts, playgrounds, fishing ponds, and approximately three miles of bike/pedestrian paths through the City. The parks include: Fenton City Park, Bud Weil Memorial Park, Fenton Meramec Greenway, Olde Towne Plaza Riverside Park, Valiant Park, and Westside Park. Plans are being developed for the former Fabick property in the heart of the City. These plans include trails and some passive uses.[11]

Heroes Memorial

[edit]

In the spring of 2004 the Mayor of Fenton, Dennis J. Hancock, and the members of the Park Board (Board Chair Glen Scholle and members Jeff Bodi, Charles Jahneke, Mike Lucas, Steve Covault, Gregg Cleveland, Diana Biras and Nannette Clark) determined that their city should build a memorial to the victims of the terrorist attacks on September 11, 2001. It was also determined that the memorial would honor police, firefighters, EMS personnel, and all veterans.

Education

[edit]

The City of Fenton is served by the Rockwood, Northwest, and Lindbergh school districts. Rockwood Summit High School is located in Fenton and is the primary high school for area students. One private school, St. Paul Catholic School, is located in Fenton.[12] Two others, Our Savior Lutheran School and Heritage Classical Christian Academy, are located adjacent to the city limits. The Meramec Valley Branch of the St. Louis County Library system is in Fenton,[13] although a new, larger facility is open just outside the city limits.[14]

Notable people

[edit]
  • Josh Arnold, host on The Bob & Tom Show
  • Brian Boehringer, former pitcher for the New York Yankees and San Francisco Giants
  • Nicole Galloway, State Auditor of Missouri
  • Joyce Meyer, Christian author and speaker
  • Jackson Rutledge, pitcher for the Washington Nationals
  • Ken Schrader, NASCAR driver
  • Mike Wallace, stock car racing driver
  • Brandon Williams, NFL defensive lineman

References

[edit]
  1. ^ "ArcGIS REST Services Directory". United States Census Bureau. Retrieved August 28, 2022.
  2. ^ a b U.S. Geological Survey Geographic Names Information System: Fenton, Missouri
  3. ^ "2008 Bioarchaeological Analysis of the Fenton Mounds," Wescott, Daniel J., Missouri Archaeologist 68[permanent dead link]
  4. ^ "Grave Losses: Lax laws and uncaring bureaucrats cause Missouri to erase another prehistoric mound" Batz, Jeannette. Riverfront Times. October 31, 2001
  5. ^ "A Brief History of Fenton." Fenton Historical Society.[permanent dead link]
  6. ^ Missouri Atlas & Gazetteer, DeLorme, 1st ed., 1998, p. 41 ISBN 0899332242
  7. ^ "US Gazetteer files 2010". United States Census Bureau. Archived from the original on January 25, 2012. Retrieved July 8, 2012.
  8. ^ "U.S. Census website". United States Census Bureau. Retrieved July 8, 2012.
  9. ^ Hunn, David (July 23, 2012). "A new stadium for the St. Louis Rams?". Stltoday. Retrieved January 13, 2013.
  10. ^ "Plans set for new development on Fenton Chrysler plant". FOX2now.com. June 25, 2015. Retrieved April 25, 2016.
  11. ^ "Fenton Area Chamber of Commerce - Parks Department". www.fentonmochamber.com. Archived from the original on April 14, 2016. Retrieved June 23, 2016.
  12. ^ "St. Paul Catholic School". Retrieved December 6, 2018.
  13. ^ "Meramec Valley Branch Archived 2009-08-26 at the Wayback Machine." St. Louis County Library. Retrieved on August 18, 2009.
  14. ^ "Meramec Valley Branch - St Louis County Library". Retrieved December 6, 2018.
[edit]
  • City of Fenton official website
  • Fenton Historical Society
  • Fenton-Missouri.html City Data
  • Fenton Area Chamber of Commerce
 

 

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Things To Do in Jefferson County

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Cliff Cave County Park

4.7 (1989)
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Jefferson County Area Tourism Council

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Gardens of Jefferson County

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Rockford Park

4.3 (599)
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Jefferson Landing State Historic Site

4.5 (95)
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Visit Jefferson County PA

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Driving Directions in Jefferson County

Driving Directions From Lowe's Home Improvement to Royal Supply Inc
Driving Directions From Tower Music to Royal Supply Inc
Driving Directions From AT&T Store to Royal Supply Inc
Driving Directions From JCPenney to Royal Supply Inc

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https://www.google.com/maps/dir/Trade+N+Games/Royal+Supply+Inc/@38.4982993,-90.4738443,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJKclDFWzQ2IcRuKznKAwT9bg!2m2!1d-90.4738443!2d38.4982993!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e2

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https://www.google.com/maps/dir/Gravois+Bluffs+Plaza/Royal+Supply+Inc/@38.5067342,-90.4441552,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJe7gFtuDP2IcRQ6812ggIauY!2m2!1d-90.4441552!2d38.5067342!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e3

https://www.google.com/maps/dir/Barnes+%26+Noble/Royal+Supply+Inc/@38.511952,-90.4473798,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJzUt_YtnP2IcRlUmrKk17V-0!2m2!1d-90.4473798!2d38.511952!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e0

Driving Directions From Jefferson County Historical Village to Royal Supply Inc
Driving Directions From Jefferson County Convention & Visitors Bureau to Royal Supply Inc
Driving Directions From Visit Jefferson County PA to Royal Supply Inc
Driving Directions From Jefferson County Museum to Royal Supply Inc
Driving Directions From Cliff Cave County Park to Royal Supply Inc
Driving Directions From Jefferson Historical Museum to Royal Supply Inc

https://www.google.com/maps/dir/Gardens+of+Jefferson+County/Royal+Supply+Inc/@38.7357841,-85.386436,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-85.386436!2d38.7357841!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e0

https://www.google.com/maps/dir/Visit+Jefferson+County+PA/Royal+Supply+Inc/@41.1600033,-79.0785874,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-79.0785874!2d41.1600033!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e2

https://www.google.com/maps/dir/Jefferson+County+Convention+%26+Visitors+Bureau/Royal+Supply+Inc/@39.3197279,-77.7603271,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-77.7603271!2d39.3197279!1m5!1m1!1sChIJQUY-I2XQ2IcReCWJfc6UEZo!2m2!1d-90.480394!2d38.4956035!3e1

Reviews for Royal Supply Inc

Royal Supply Inc

Toney Dunaway

(5)

This is another amazing place where we will do much more business. They are not tyrannical about the totally useless face diapers, they have a great selection of stock, they have very knowledgeable staff, very friendly staff. We got the plumbing items we really needed and will be getting more plumbing items. They also have central units, thermostats, caulking, sealants, doors, seems everything you need for a mobile home. We've found a local treasure and will be bringing much more business. Their store is clean and tidy as well!

Royal Supply Inc

Gidget McCarthy

(5)

Very knowledgeable, friendly, helpful and don't make you feel like you're inconveniencing them. They seem willing to take all the time you need. As if you're the only thing they have to do that day. The store is clean, organized and not cluttered, symmetrical at that. Cuz I'm even and symmetricals biggest fan. It was a pleasure doing business with them and their prices are definitely reasonable. So, I'll be doing business with them in the future no doubt.

Royal Supply Inc

Terry Self

(1)

Horrible workmanship, horrible customer service, don't show up when they say they are. Ghosted. Was supposed to come back on Monday, no call no show. Called Tuesday and Wednesday, left messages both days. Nothing. Kinked my line, crooked to the pad and house, didn't put disconnect back on, left the trash.....

Royal Supply Inc

Ae Webb

(5)

Royal installed a new furnace and air conditioner just before we got our used mobile home. Recently, the furnace stopped lighting. Jared (sp?) made THREE trips to get it back to good. He was so gracious and kind. Fortunately for us it was still under warranty. BTW, those three trips were from Fenton, Missouri to Belleville, Illinois! Thanks again, Jared!

Royal Supply Inc

bill slayton

(1)

Went to get a deadbolt what they had was one I was told I'd have take it apart to lengthen and I said I wasn't buying something new and have to work on it. Thing of it is I didn't know if it was so that it could be lengthened said I didn't wanna buy something new I had to work on just to fit my door. He got all mad and slung the whole box with part across the room. A real business man. I guess the owner approves of his employees doing as such.

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