Evaluating Newer Options to Replace Electric Heaters

Evaluating Newer Options to Replace Electric Heaters

Importance of Safety in Mobile Home HVAC Work

Electric heaters have long been a staple in the heating solutions for mobile homes. However, as we move towards more sustainable and efficient living standards, it's essential to evaluate their limitations and challenges, particularly when considering newer options that may be better suited for modern needs.


One of the primary limitations of using electric heaters in mobile homes is their energy efficiency-or lack thereof. Electric heaters can consume a significant amount of electricity, leading to higher utility bills. This is especially concerning in regions where electricity costs are high or where the grid relies heavily on non-renewable sources, thereby increasing the carbon footprint associated with their use. Space constraints in mobile homes require innovative HVAC installation techniques Mobile Home Furnace Installation experience. Furthermore, mobile homes often lack the insulation found in traditional houses, which means more energy is required to maintain comfortable temperatures.


Another challenge is safety. Electric heaters can pose fire risks if not properly maintained or used incorrectly. In compact spaces like mobile homes, where space is at a premium and flammable materials may be nearby, this risk is magnified. The potential for accidents increases during peak usage times in winter months when demand on electrical systems can lead to overheating or circuit overloads.


Additionally, electric heaters often provide uneven heat distribution within a mobile home. They tend to focus warmth around their immediate vicinity while leaving other areas cold. This inconsistency can result in discomfort for occupants and necessitate additional heating devices or methods to achieve desired comfort levels throughout the entire home.


Moreover, electric heaters typically offer limited control over temperature settings compared to more modern heating solutions like programmable thermostats connected with central HVAC systems or smart home technology which allow users to tailor their environment precisely according to personal preferences and schedules.


Given these limitations and challenges, evaluating newer alternatives becomes crucial. Options such as heat pumps or propane-based systems might offer greater efficiency and cost-effectiveness over time while also enhancing safety features through advanced technology integrations.


In conclusion, while electric heaters have served as an accessible heating solution for many years within mobile homes, their drawbacks prompt an exploration of alternative options that align with current demands for sustainability, safety, comfort, and efficiency. As technology advances continue providing innovative solutions tailored specifically for small spaces like those found in mobile homes; it becomes increasingly important not only consider but actively pursue these newer alternatives that promise improved living conditions without compromising on environmental considerations or economic practicality.

Common Hazards Associated with Mobile Home HVAC Systems —

As the world continues to grapple with the challenges of climate change and rising energy costs, the demand for efficient and sustainable heating technologies has never been more pressing. Traditional electric heaters, long a staple in many households, are now being scrutinized for their inefficiency and environmental impact. In response, a variety of newer heating technologies and alternatives have emerged, promising not only to reduce energy consumption but also to provide a cleaner, greener way to maintain comfort in our homes.


One of the most promising advancements is the heat pump technology. Unlike conventional electric heaters that convert electricity directly into heat, heat pumps transfer heat from one place to another - much like a refrigerator works but in reverse. Air-source heat pumps extract warmth from the outside air even in cold temperatures and deliver it inside. Ground-source or geothermal heat pumps take advantage of the relatively constant temperature underground. These systems can be incredibly efficient; for every unit of electricity they use, they can produce several units of heat.


Another innovative solution gaining traction is infrared heating panels. These panels emit infrared rays that directly warm objects and people rather than heating the surrounding air. This method mimics how the sun heats surfaces on Earth and can create a comfortable environment while using less energy than traditional convection-based systems.


Biomass heating is also emerging as an attractive alternative for those looking to replace electric heaters with something more sustainable. Biomass boilers burn organic materials such as wood pellets or chips to generate heat. While this does release carbon dioxide, it is considered carbon-neutral because the plants absorbed CO2 during their growth phase. Moreover, biomass systems can often be integrated into existing radiators or underfloor heating systems with minimal modification.


Hydronic radiant floor systems present another modern option by circulating warm water through pipes beneath floor surfaces. This method provides uniform warmth throughout a space without creating drafts or hot spots common in rooms heated by forced-air systems.


Innovative hybrid systems are also making headway by combining different technologies for optimal efficiency and flexibility. For instance, some setups integrate solar thermal collectors with heat pumps or biomass boilers to leverage renewable resources whenever possible while having reliable backup options when needed.


The adoption of smart thermostats and home automation technologies further complements these innovations by providing precise control over heating schedules and allowing homeowners to optimize energy usage based on real-time data about occupancy patterns or weather forecasts.


While these newer options offer compelling benefits over traditional electric heaters - including lower operational costs, reduced environmental impact, improved indoor air quality - they may come with higher upfront installation expenses depending on specific circumstances like home insulation levels or local climate conditions.


In conclusion, as we evaluate new options to replace electric heaters in our quest for sustainability and efficiency, it's clear that there are numerous viable alternatives available today ranging from cutting-edge technological solutions like heat pumps and infrared panels to more established methods like biomass boilers. Each offers its own set of advantages tailored toward different needs and preferences; thus careful consideration should be given when selecting which approach best fits individual requirements while contributing positively towards broader ecological goals.

Navigating Safety Standards for Mobile Home Heating and Cooling Systems

 Navigating Safety Standards for Mobile Home Heating and Cooling Systems

As we venture into the future of mobile home living, one aspect that deserves heightened attention is the safety of heating and cooling systems.. These components are essential for ensuring comfort in varying climates but pose significant safety risks if not properly managed.

Posted by on 2024-12-30

Innovative Solutions for Upgrading Outdated Mobile Home HVAC Systems

 Innovative Solutions for Upgrading Outdated Mobile Home HVAC Systems

Maintaining long-term efficiency and performance in mobile home HVAC systems, especially when dealing with outdated models, requires an innovative approach that combines both traditional maintenance practices and modern technological upgrades.. Mobile homes often present unique challenges due to space constraints and the original design of their heating, ventilation, and air conditioning systems.

Posted by on 2024-12-30

Top Safety Guidelines for Mobile Home HVAC Technicians on the Job

 Top Safety Guidelines for Mobile Home HVAC Technicians on the Job

In the high-stakes world of mobile home HVAC technicians, safety isn't just a guideline—it's a lifeline.. As these professionals navigate the complexities of heating, ventilation, and air conditioning systems within confined mobile homes, they must always be prepared for emergencies or accidents that can occur on the job.

Posted by on 2024-12-30

Essential Safety Gear and Equipment for Technicians

In recent years, the quest for more energy-efficient heating options has become increasingly critical as we strive to reduce our carbon footprint and minimize energy costs. The traditional electric heater, while convenient and widely used, is often criticized for its inefficiency in terms of energy consumption compared to newer and more sustainable heating systems. This essay aims to provide a comparative analysis of various modern heating options that could potentially replace electric heaters, focusing on their energy efficiency.


To begin with, heat pumps have emerged as a leading alternative due to their impressive energy efficiency. Unlike electric heaters that convert electricity directly into heat, heat pumps transfer heat from outside sources like air or ground into indoor spaces. This method can be up to three times more efficient than conventional electric heating because it merely moves heat rather than generating it from scratch. Air-source and ground-source (geothermal) heat pumps are the most common types, each offering different advantages based on climatic conditions and installation feasibility.


Another promising option is the use of solar thermal systems. These systems harness solar energy through collectors usually installed on rooftops, converting sunlight into usable thermal energy for space heating or water heating purposes. While the initial setup cost can be high, the operational costs are minimal since sunlight is free and abundant in many regions. However, their efficiency can vary significantly depending on geographic location and weather conditions; hence, they are best suited for areas with substantial sunshine throughout the year.


Biomass boilers represent another viable alternative by utilizing organic materials such as wood pellets or chips as fuel. These boilers have gained popularity due to their ability to utilize renewable resources while also providing a sustainable solution for waste management. With advancements in technology, biomass boilers have become more efficient and user-friendly. However, they require regular maintenance and a steady supply of biomass fuel which might not be feasible for all users.


Additionally, infrared heaters offer an innovative approach by directly warming objects and people rather than air in a room. This technology reduces unnecessary heating of empty spaces-a common issue with traditional electric heaters-thus enhancing overall energy efficiency. Infrared heaters can be particularly effective in well-insulated environments where radiant heat absorption is maximized.


Finally, district heating systems present an interesting community-based solution where centralized plants produce heat distributed via insulated pipes to multiple buildings within an area. By utilizing combined heat and power (CHP) plants or waste-to-energy facilities as sources of thermal energy production, district heating achieves higher efficiencies compared to individual building systems.


In conclusion, when evaluating newer options to replace electric heaters from an energy efficiency perspective, it's evident that several alternatives offer significant benefits over traditional methods. Heat pumps stand out due to their superior efficiency ratings; however other solutions like solar thermal systems, biomass boilers, infrared heaters-and even district heating networks-provide compelling choices depending on specific needs and circumstances such as geographical location or infrastructure availability. As we continue exploring these alternatives amidst growing environmental concerns and economic considerations alike; choosing wisely will ensure both sustainable practices today-and better prospects tomorrow-for future generations seeking warmth without compromise upon our planet's wellbeing overall!

Essential Safety Gear and Equipment for Technicians

Proper Procedures for Handling Refrigerants and Chemicals

When evaluating newer options to replace electric heaters, it is crucial to delve into the cost considerations associated with installation, operation, and maintenance. These three facets not only determine the immediate financial outlay but also influence long-term economic sustainability and environmental impacts.


Installation costs often serve as the initial barrier or gateway in adopting a new heating solution. Emerging technologies such as heat pumps, radiant floor heating, or solar thermal systems might require more sophisticated installation procedures compared to traditional electric heaters. This could involve specialized labor, specific infrastructural adjustments, or even significant architectural modifications. For instance, installing a geothermal heat pump may necessitate drilling which can drive up costs significantly more than simply replacing an electric wall heater. Hence, it is important for consumers and businesses alike to assess whether the upfront installation investment aligns with their budgetary constraints and long-term savings expectations.


Once installed, operational costs become a primary concern. Electric heaters are notorious for their high energy consumption which translates directly into elevated utility bills. Newer alternatives often boast better energy efficiency and lower operating expenses. Heat pumps, for example, utilize ambient air or ground temperatures to provide heating at a fraction of the electric cost required by resistance-based heaters. However, these savings can be influenced by factors such as climate conditions and electricity prices in different regions. Therefore, when considering replacements like high-efficiency gas furnaces or biomass boilers, one must evaluate not just their advertised efficiency but also how these systems perform under specific environmental circumstances.


Maintenance costs represent another critical aspect of evaluating replacement options for electric heaters. Traditional electric units generally have fewer mechanical parts leading to lower maintenance demands; however, they may still require regular checks for safety and performance optimization. Conversely, while more complex systems like solar thermal panels or hydronic heating might offer substantial energy efficiencies and operational savings over time, they could incur higher maintenance fees due to their complexity or reliance on external factors like weather conditions.


In conclusion, when contemplating newer options for replacing electric heaters-whether driven by environmental concerns or economic incentives-a comprehensive assessment of installation costs against potential operational savings and future maintenance expenses is essential. By carefully weighing these factors within the context of individual needs and regional characteristics, consumers can make informed decisions that balance initial investments with sustainable benefits over time.

Electrical Safety Protocols for Mobile Home HVAC Work

As concerns about climate change and environmental sustainability continue to rise, the quest for reducing carbon footprints has become a global imperative. One area ripe for innovation is home heating-specifically, the evaluation of newer options to replace electric heaters with more environmentally friendly solutions.


Electric heaters, while commonly used due to their convenience and availability, are not necessarily the most sustainable choice. They often rely on electricity generated from fossil fuels, which contributes significantly to carbon emissions. As such, there is an urgent need to explore alternative technologies that can provide efficient heating while minimizing environmental impact.


One promising solution is heat pump technology. Heat pumps operate by transferring heat from one place to another rather than generating it directly through electricity. This method is significantly more energy-efficient compared to traditional electric heaters. By utilizing ambient heat from the ground or air, heat pumps can reduce electricity consumption substantially. Moreover, when powered by renewable energy sources like solar or wind power, they offer an almost entirely carbon-neutral solution.


Another innovative option gaining traction is infrared heating panels. Unlike conventional heaters that warm up the air in a room, infrared panels directly heat objects and individuals within a space through radiation. This direct form of heating means less energy loss and quicker warmth delivery. Additionally, these panels can be integrated into smart home systems, allowing users to optimize their energy use further by programming and automating heating schedules according to occupancy patterns.


Biomass boilers present yet another alternative worth considering. These systems burn organic materials such as wood pellets or chips instead of relying on electricity or fossil fuels. Properly managed biomass resources are considered renewable because they can be replenished over time without depleting natural ecosystems drastically. While initial setup costs may be higher, biomass boilers can offer long-term savings and substantial reductions in carbon emissions compared to electric heaters.


However, transitioning from electric heaters to these newer options requires careful consideration of various factors such as installation costs, local climate conditions, availability of resources (like biomass), and infrastructure capabilities (such as access to renewable energy). Policymakers play a crucial role in facilitating this transition by providing incentives for adopting greener technologies and investing in research that further enhances their efficiency and affordability.


In conclusion, evaluating newer options for replacing electric heaters offers a tangible opportunity to reduce our carbon footprint significantly. While no single solution may fit all scenarios perfectly due to varying regional needs and constraints, embracing a mix of innovative technologies like heat pumps, infrared panels, and biomass boilers can pave the way towards more sustainable home heating practices. As we move forward into an era where environmental responsibility takes center stage globally-the choices we make today will indeed shape the world we leave for future generations tomorrow.

Best Practices for Ensuring Structural Integrity During Installation and Maintenance

In recent years, the quest to replace traditional electric heaters with more advanced heating systems has gained significant momentum. As the world becomes increasingly conscious of energy efficiency and sustainability, consumers are exploring modern alternatives that not only provide warmth but also enhance user experience through comfort, safety, and ease of use.


Comfort is a critical factor that users consider when evaluating modern heating systems. Unlike conventional electric heaters that often produce uneven heat distribution and dry air, newer options such as hydronic heating and radiant floor systems offer a more consistent and natural warmth. These systems work by circulating warm water or utilizing infrared technology to heat spaces evenly, creating an environment where every corner of a room feels just right. Furthermore, many advanced systems come equipped with smart thermostats that allow users to customize temperature settings based on their preferences or even schedule heating cycles to align with their daily routines. This level of personalization ensures optimal comfort tailored to individual needs.


Safety is another paramount concern when choosing a replacement for electric heaters. Traditional electric heaters can pose various risks, including overheating, electrical faults, and fire hazards if not used properly. In contrast, modern heating solutions have been designed with enhanced safety features to mitigate such dangers. For instance, hydronic systems reduce the risk of burns since they do not rely on exposed elements or high surface temperatures. Additionally, many contemporary models incorporate automatic shut-off mechanisms and child-lock functions to prevent accidents and ensure peace of mind for families.


Ease of use is equally essential in evaluating new heating options. As technology evolves, so does the expectation for intuitive interfaces and seamless integration into everyday life. Modern heating systems often feature user-friendly controls that can be managed through smartphone apps or voice-activated devices like smart home assistants. This connectivity allows users to adjust settings remotely-turning on the heat before arriving home from work or lowering it while away on vacation-all with a few taps on their phone or simple voice commands. Such convenience not only improves user experience but also promotes energy saving by enabling precise control over energy consumption.


In conclusion, as homeowners consider replacing outdated electric heaters with newer options, focusing on user experience aspects like comfort, safety, and ease of use becomes crucial. Modern heating systems offer significant advantages in these areas by providing consistent warmth without compromising on safety or convenience. By embracing these innovative solutions, consumers can enjoy enhanced living environments that cater to their specific needs while also contributing to broader goals of sustainability and energy efficiency.

For the Lego series, see Lego Modular Buildings.
Prefabricated house in Valencia, Spain.

A modular building is a prefabricated building that consists of repeated sections called modules.[1] Modularity involves constructing sections away from the building site, then delivering them to the intended site. Installation of the prefabricated sections is completed on site. Prefabricated sections are sometimes placed using a crane. The modules can be placed side-by-side, end-to-end, or stacked, allowing for a variety of configurations and styles. After placement, the modules are joined together using inter-module connections, also known as inter-connections. The inter-connections tie the individual modules together to form the overall building structure.[2]

Uses

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Modular home prefab sections to be placed on the foundation

Modular buildings may be used for long-term, temporary or permanent facilities, such as construction camps, schools and classrooms, civilian and military housing, and industrial facilities. Modular buildings are used in remote and rural areas where conventional construction may not be reasonable or possible, for example, the Halley VI accommodation pods used for a BAS Antarctic expedition.[3] Other uses have included churches, health care facilities, sales and retail offices, fast food restaurants and cruise ship construction. They can also be used in areas that have weather concerns, such as hurricanes. Modular buildings are often used to provide temporary facilities, including toilets and ablutions at events. The portability of the buildings makes them popular with hire companies and clients alike. The use of modular buildings enables events to be held at locations where existing facilities are unavailable, or unable to support the number of event attendees.

Construction process

[edit]

Construction is offsite, using lean manufacturing techniques to prefabricate single or multi-story buildings in deliverable module sections. Often, modules are based around standard 20 foot containers, using the same dimensions, structures, building and stacking/placing techniques, but with smooth (instead of corrugated) walls, glossy white paint, and provisions for windows, power, potable water, sewage lines, telecommunications and air conditioning. Permanent Modular Construction (PMC) buildings are manufactured in a controlled setting and can be constructed of wood, steel, or concrete. Modular components are typically constructed indoors on assembly lines. Modules' construction may take as little as ten days but more often one to three months. PMC modules can be integrated into site built projects or stand alone and can be delivered with MEP, fixtures and interior finishes.

The buildings are 60% to 90% completed offsite in a factory-controlled environment, and transported and assembled at the final building site. This can comprise the entire building or be components or subassemblies of larger structures. In many cases, modular contractors work with traditional general contractors to exploit the resources and advantages of each type of construction. Completed modules are transported to the building site and assembled by a crane.[4] Placement of the modules may take from several hours to several days. Off-site construction running in parallel to site preparation providing a shorter time to project completion is one of the common selling points of modular construction. Modular construction timeline

Permanent modular buildings are built to meet or exceed the same building codes and standards as site-built structures and the same architect-specified materials used in conventionally constructed buildings are used in modular construction projects. PMC can have as many stories as building codes allow. Unlike relocatable buildings, PMC structures are intended to remain in one location for the duration of their useful life.

Manufacturing considerations

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The entire process of modular construction places significance on the design stage. This is where practices such as Design for Manufacture and Assembly (DfMA) are used to ensure that assembly tolerances are controlled throughout manufacture and assembly on site. It is vital that there is enough allowance in the design to allow the assembly to take up any "slack" or misalignment of components. The use of advanced CAD systems, 3D printing and manufacturing control systems are important for modular construction to be successful. This is quite unlike on-site construction where the tradesman can often make the part to suit any particular installation.

  • Bulk materials
    Bulk materials
  • Walls attached to floor
    Walls attached to floor
  • Ceiling drywalled in spray booth
    Ceiling drywalled in spray booth
  • Roof set in place
    Roof set in place
  • Roof shingled and siding installed
    Roof shingled and siding installed
  • Ready for delivery to site
    Ready for delivery to site
  • Two-story modular dwelling
    Two-story modular dwelling
  • Pratt Modular Home in Tyler Texas
    Pratt Modular Home in Tyler Texas
  • Pratt Modular Home kitchen
    Pratt Modular Home kitchen
  • Pratt Modular Home in Tyler Texas
    Pratt Modular Home in Tyler Texas

Upfront production investment

[edit]

The development of factory facilities for modular homes requires significant upfront investment. To help address housing shortages in the 2010s, the United Kingdom Government (via Homes England) invested in modular housing initiatives. Several UK companies (for example, Ilke Homes, L&G Modular Homes, House by Urban Splash, Modulous, TopHat and Lighthouse) were established to develop modular homes as an alternative to traditionally-built residences, but failed as they could not book revenues quickly enough to cover the costs of establishing manufacturing facilities.

IIke Homes opened a factory in Knaresborough, Yorkshire in 2018, and Homes England invested £30m in November 2019,[5] and a further £30m in September 2021.[6] Despite a further fund-raising round, raising £100m in December 2022,[7][8] Ilke Homes went into administration on 30 June 2023,[9][10] with most of the company's 1,150 staff made redundant,[11] and debts of £320m,[12] including £68m owed to Homes England.[13]

In 2015 Legal & General launched a modular homes operation, L&G Modular Homes, opening a 550,000 sq ft factory in Sherburn-in-Elmet, near Selby in Yorkshire.[14] The company incurred large losses as it invested in its factory before earning any revenues; by 2019, it had lost over £100m.[15] Sales revenues from a Selby project, plus schemes in Kent and West Sussex, started to flow in 2022, by which time the business's total losses had grown to £174m.[16] Production was halted in May 2023, with L&G blaming local planning delays and the COVID-19 pandemic for its failure to grow its sales pipeline.[17][18] The enterprise incurred total losses over seven years of £295m.[19]

Market acceptance

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Raines Court is a multi-story modular housing block in Stoke Newington, London, one of the first two residential buildings in Britain of this type. (December 2005)

Some home buyers and some lending institutions resist consideration of modular homes as equivalent in value to site-built homes.[citation needed] While the homes themselves may be of equivalent quality, entrenched zoning regulations and psychological marketplace factors may create hurdles for buyers or builders of modular homes and should be considered as part of the decision-making process when exploring this type of home as a living and/or investment option. In the UK and Australia, modular homes have become accepted in some regional areas; however, they are not commonly built in major cities. Modular homes are becoming increasingly common in Japanese urban areas, due to improvements in design and quality, speed and compactness of onsite assembly, as well as due to lowering costs and ease of repair after earthquakes. Recent innovations allow modular buildings to be indistinguishable from site-built structures.[20] Surveys have shown that individuals can rarely tell the difference between a modular home and a site-built home.[21]

Modular homes vs. mobile homes

[edit]

Differences include the building codes that govern the construction, types of material used and how they are appraised by banks for lending purposes. Modular homes are built to either local or state building codes as opposed to manufactured homes, which are also built in a factory but are governed by a federal building code.[22] The codes that govern the construction of modular homes are exactly the same codes that govern the construction of site-constructed homes.[citation needed] In the United States, all modular homes are constructed according to the International Building Code (IBC), IRC, BOCA or the code that has been adopted by the local jurisdiction.[citation needed] In some states, such as California, mobile homes must still be registered yearly, like vehicles or standard trailers, with the Department of Motor Vehicles or other state agency. This is true even if the owners remove the axles and place it on a permanent foundation.[23]

Recognizing a mobile or manufactured home

[edit]

A mobile home should have a small metal tag on the outside of each section. If a tag cannot be located, details about the home can be found in the electrical panel box. This tag should also reveal a manufacturing date.[citation needed] Modular homes do not have metal tags on the outside but will have a dataplate installed inside the home, usually under the kitchen sink or in a closet. The dataplate will provide information such as the manufacturer, third party inspection agency, appliance information, and manufacture date.

Materials

[edit]

The materials used in modular buildings are of the same quality and durability as those used in traditional construction, preserving characteristics such as acoustic insulation and energy efficiency, as well as allowing for attractive and innovative designs thanks to their versatility.[24] Most commonly used are steel, wood and concrete.[25]

  • Steel: Because it is easily moldable, it allows for innovation in design and aesthetics.
  • Wood: Wood is an essential part of most modular buildings. Thanks to its lightness, it facilitates the work of assembling and moving the prefabricated modules.
  • Concrete: Concrete offers a solid structure that is ideal for the structural reinforcement of permanent modular buildings. It is increasingly being used as a base material in this type of building, thanks to its various characteristics such as fire resistance, energy savings, greater acoustic insulation, and durability.[26]

Wood-frame floors, walls and roof are often utilized. Some modular homes include brick or stone exteriors, granite counters and steeply pitched roofs. Modulars can be designed to sit on a perimeter foundation or basement. In contrast, mobile homes are constructed with a steel chassis that is integral to the integrity of the floor system. Modular buildings can be custom built to a client's specifications. Current designs include multi-story units, multi-family units and entire apartment complexes. The negative stereotype commonly associated with mobile homes has prompted some manufacturers to start using the term "off-site construction."

New modular offerings include other construction methods such as cross-laminated timber frames.[27]

Financing

[edit]

Mobile homes often require special lenders.[28]

Modular homes on the other hand are financed as site built homes with a construction loan

Standards and zoning considerations

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Typically, modular dwellings are built to local, state or council code, resulting in dwellings from a given manufacturing facility having differing construction standards depending on the final destination of the modules.[29] The most important zones that manufacturers have to take into consideration are local wind, heat, and snow load zones.[citation needed] For example, homes built for final assembly in a hurricane-prone, earthquake or flooding area may include additional bracing to meet local building codes. Steel and/or wood framing are common options for building a modular home.

Some US courts have ruled that zoning restrictions applicable to mobile homes do not apply to modular homes since modular homes are designed to have a permanent foundation.[citation needed] Additionally, in the US, valuation differences between modular homes and site-built homes are often negligible in real estate appraisal practice; modular homes can, in some market areas, (depending on local appraisal practices per Uniform Standards of Professional Appraisal Practice) be evaluated the same way as site-built dwellings of similar quality. In Australia, manufactured home parks are governed by additional legislation that does not apply to permanent modular homes. Possible developments in equivalence between modular and site-built housing types for the purposes of real estate appraisals, financing and zoning may increase the sales of modular homes over time.[30]

CLASP (Consortium of Local Authorities Special Programme)

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The Consortium of Local Authorities Special Programme (abbreviated and more commonly referred to as CLASP) was formed in England in 1957 to combine the resources of local authorities with the purpose of developing a prefabricated school building programme. Initially developed by Charles Herbert Aslin, the county architect for Hertfordshire, the system was used as a model for several other counties, most notably Nottinghamshire and Derbyshire. CLASP's popularity in these coal mining areas was in part because the system permitted fairly straightforward replacement of subsidence-damaged sections of building.

Building strength

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Modular Home being built in Vermont photo by Josh Vignona
Modular home in Vermont

Modular homes are designed to be stronger than traditional homes by, for example, replacing nails with screws, adding glue to joints, and using 8–10% more lumber than conventional housing.[31] This is to help the modules maintain their structural integrity as they are transported on trucks to the construction site. However, there are few studies on the response of modular buildings to transport and handling stresses. It is therefore presently difficult to predict transport induced damage.[1]

When FEMA studied the destruction wrought by Hurricane Andrew in Dade County Florida, they concluded that modular and masonry homes fared best compared to other construction.[32]

CE marking

[edit]

The CE mark is a construction norm that guarantees the user of mechanical resistance and strength of the structure. It is a label given by European community empowered authorities for end-to-end process mastering and traceability.[citation needed]

All manufacturing operations are being monitored and recorded:

  • Suppliers have to be known and certified,
  • Raw materials and goods being sourced are to be recorded by batch used,
  • Elementary products are recorded and their quality is monitored,
  • Assembly quality is managed and assessed on a step by step basis,
  • When a modular unit is finished, a whole set of tests are performed and if quality standards are met, a unique number and EC stamp is attached to and on the unit.

This ID and all the details are recorded in a database, At any time, the producer has to be able to answer and provide all the information from each step of the production of a single unit, The EC certification guaranties standards in terms of durability, resistance against wind and earthquakes.[citation needed]

Open modular building

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See also: Green building

The term Modularity can be perceived in different ways. It can even be extended to building P2P (peer-to-peer) applications; where a tailored use of the P2P technology is with the aid of a modular paradigm. Here, well-understood components with clean interfaces can be combined to implement arbitrarily complex functions in the hopes of further proliferating self-organising P2P technology. Open modular buildings are an excellent example of this. Modular building can also be open source and green. Bauwens, Kostakis and Pazaitis[33] elaborate on this kind of modularity. They link modularity to the construction of houses.

This commons-based activity is geared towards modularity. The construction of modular buildings enables a community to share designs and tools related to all the different parts of house construction. A socially-oriented endeavour that deals with the external architecture of buildings and the internal dynamics of open source commons. People are thus provided with the tools to reconfigure the public sphere in the area where they live, especially in urban environments. There is a robust socializing element that is reminiscent of pre-industrial vernacular architecture and community-based building.[34]

Some organisations already provide modular housing. Such organisations are relevant as they allow for the online sharing of construction plans and tools. These plans can be then assembled, through either digital fabrication like 3D printing or even sourcing low-cost materials from local communities. It has been noticed that given how easy it is to use these low-cost materials are (for example: plywood), it can help increase the permeation of these open buildings to areas or communities that lack the know-how or abilities of conventional architectural or construction firms. Ergo, it allows for a fundamentally more standardised way of constructing houses and buildings. The overarching idea behind it remains key - to allow for easy access to user-friendly layouts which anyone can use to build in a more sustainable and affordable way.

Modularity in this sense is building a house from different standardised parts, like solving a jigsaw puzzle.

3D printing can be used to build the house.

The main standard is OpenStructures and its derivative Autarkytecture.[35]

Research and development

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Modular construction is the subject of continued research and development worldwide as the technology is applied to taller and taller buildings. Research and development is carried out by modular building companies and also research institutes such as the Modular Building Institute[36] and the Steel Construction Institute.[37]

See also

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  • Affordable housing
  • Alternative housing
  • Commercial modular construction
  • Construction 3D printing
  • Container home
  • Kit house
  • MAN steel house
  • Manufactured housing
  • Modern methods of construction
  • Modular design
  • Portable building
  • Prefabrication
  • Open-source architecture
  • Open source hardware
  • OpenStructures
  • Prefabricated home
  • Relocatable buildings
  • Recreational vehicles
  • Shipping container architecture
  • Stick-built home
  • Tiny house movement
  • Toter

References

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  1. ^ a b Lacey, Andrew William; Chen, Wensu; Hao, Hong; Bi, Kaiming (2018). "Structural Response of Modular Buildings – An Overview". Journal of Building Engineering. 16: 45–56. doi:10.1016/j.jobe.2017.12.008. hdl:20.500.11937/60087.
  2. ^ Lacey, Andrew William; Chen, Wensu; Hao, Hong; Bi, Kaiming (2019). "Review of bolted inter-module connections in modular steel buildings". Journal of Building Engineering. 23: 207–219. doi:10.1016/j.jobe.2019.01.035. S2CID 86540434.
  3. ^ "Halley VI Research Station – British Antarctic Survey". Bas.ac.uk. Retrieved 2016-05-03.
  4. ^ "Why Build Modular?". Modular.org. Retrieved 2016-05-03.
  5. ^ Morby, Aaron (4 November 2019). "Government pumps £30m into modular house builder". Construction Enquirer. Retrieved 14 March 2024.
  6. ^ Morby, Aaron (27 September 2021). "Ilke Homes raises £60m for top 10 house builder plan". Construction Enquirer. Retrieved 14 March 2024.
  7. ^ Morby, Aaron (6 December 2022). "Ilke Homes pulls off £100m record-breaking fund raise". Construction Enquirer. Retrieved 14 March 2024.
  8. ^ O'Connor, Rob (6 December 2022). "ilke Homes announces new £100m investment". Infrastructure Intelligence. Retrieved 14 March 2024.
  9. ^ Gardiner, Joey (30 June 2023). "Ilke Homes sinks into administration with most of firm's 1,100 staff set to lose their jobs". Building. Retrieved 14 March 2024.
  10. ^ Riding, James (30 June 2023). "Modular house builder Ilke Homes enters administration with majority of staff to be made redundant". Inside Housing. Retrieved 14 March 2024.
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Blue Whale of Catoosa

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Driving Directions in Tulsa County

Driving Directions From Harmon Security Group LLC. to Durham Supply Inc
Driving Directions From Tulsa to Durham Supply Inc
Driving Directions From Best Western Airport to Durham Supply Inc
Driving Directions From East Central High School to Durham Supply Inc
Driving Directions From Waffle House to Durham Supply Inc

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Driving Directions From The Tulsa Arts District to Durham Supply Inc
Driving Directions From Gathering Place to Durham Supply Inc
Driving Directions From Philbrook Museum of Art to Durham Supply Inc
Driving Directions From Gathering Place to Durham Supply Inc
Driving Directions From Route 66 Historical Village to Durham Supply Inc
Driving Directions From Route 66 Historical Village to Durham Supply Inc

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Reviews for Durham Supply Inc

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

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

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

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.

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