Evaluating Newer Options to Replace Electric Heaters

Evaluating Newer Options to Replace Electric Heaters

Overview of Mobile Home HVAC Systems and Compatibility Considerations

The use of traditional electric heaters in mobile homes has been a common practice for many years, primarily due to their accessibility and straightforward installation. However, as the need for more efficient and environmentally friendly heating solutions grows, it becomes essential to evaluate the limitations and challenges posed by these conventional systems. Understanding these drawbacks can highlight the need to explore newer options that better align with modern energy standards and occupant comfort.


One of the primary limitations of traditional electric heaters is their inefficiency in energy consumption. Electric resistance heating is known for converting nearly all the electricity into heat, but this process does not account for how electricity is generated. In many regions, electricity production still relies heavily on fossil fuels, leading to higher carbon emissions. Filters in mobile homes should be replaced according to manufacturer recommendations mobile home hvac ultraviolet radiation. For mobile homeowners conscious of their environmental footprint, this presents a significant challenge as they seek ways to minimize their impact on climate change.


Another challenge associated with electric heaters is cost-effectiveness. Mobile homes often have less insulation than standard homes, which means that maintaining a comfortable temperature requires more energy output from an electric heater. This increased demand can result in high utility bills during colder months, placing a financial strain on residents who may already be budget-conscious.


Safety concerns also arise with traditional electric heaters. Older models can pose fire hazards if not properly maintained or if used incorrectly-issues such as overheating or faulty wiring are potential risks that cannot be overlooked. Mobile homes, due to their compact nature and construction materials, may be particularly vulnerable to fires sparked by malfunctioning heaters.


Moreover, electric heaters generally provide uneven heating across spaces within a mobile home. Unlike systems that distribute heat through ducts or radiant floor panels, portable or fixed electric units often result in hot spots near the unit itself while leaving other areas uncomfortably cold. This inconsistency can lead to discomfort for occupants and might require supplemental heating solutions that further increase energy consumption.


Given these limitations and challenges, evaluating newer options becomes imperative for those looking to replace traditional electric heaters in mobile homes. Modern alternatives such as ductless mini-split systems offer greater energy efficiency through heat pump technology while providing both heating and cooling capabilities throughout the year. Similarly, infrared heaters provide direct warmth without significantly impacting air quality or humidity levels inside the home.


Additionally, advancements in smart home technology allow residents to optimize their heating patterns using programmable thermostats or remote control via smartphone applications-features that promote energy savings and enhance user convenience.


In conclusion, while traditional electric heaters have served mobile homeowners adequately over past decades, their numerous drawbacks necessitate consideration of more sustainable and efficient replacements. By embracing newer technologies tailored specifically for small living spaces like mobile homes, residents can achieve improved comfort levels while reducing both environmental impact and operating costs-a win-win situation that aligns with contemporary living standards and values.

Steps for Selecting the Right WiFi Thermostat for Your Mobile Home —

In the quest for sustainable living and energy efficiency, evaluating newer options to replace electric heaters becomes a pivotal task. As homeowners and businesses alike seek to transition into more environmentally friendly practices, understanding the criteria for selecting new heating systems is essential. Among these criteria, efficiency, cost, and environmental impact stand out as key factors that influence decision-making.


Efficiency is often the first consideration when evaluating new heating options. The goal is to find a system that maximizes heat output while minimizing energy input. Traditional electric heaters are known for their straightforward conversion of electricity into heat; however, they can be inefficient in terms of overall energy usage compared to newer technologies. For instance, heat pumps offer a compelling alternative by transferring heat rather than generating it directly. This process can yield efficiencies up to three times higher than conventional electric heaters. Similarly, advancements in solar thermal systems provide opportunities to harness renewable energy sources effectively, further enhancing efficiency ratings.


Cost is another critical factor that cannot be overlooked. While initial installation costs may be high for some modern heating systems like geothermal heat pumps or advanced solar panels, long-term savings often justify the investment. It's essential to conduct a thorough cost-benefit analysis over the lifespan of the system. Considerations include not only upfront expenses but also ongoing operational costs such as maintenance and energy consumption. Incentives or rebates from governments for adopting green technologies can also alleviate some of the financial burdens and make newer options more attractive.


Environmental impact represents a growing concern as societies become more aware of climate change issues. Electric heaters typically rely on fossil-fuel-generated electricity, contributing significantly to carbon emissions and environmental degradation. In contrast, alternative heating options like biomass boilers or solar water heaters offer reduced carbon footprints due to their reliance on renewable resources or natural processes. By choosing systems with lower environmental impacts, individuals contribute positively toward global sustainability goals while also potentially improving indoor air quality.


When integrating these three criteria-efficiency, cost, and environmental impact-into decision-making processes, one must weigh personal needs against broader ecological responsibilities. It's crucial to recognize that there might not be a one-size-fits-all solution; rather, the best choice will depend on specific circumstances such as geographic location, budget constraints, and individual values regarding sustainability.


Ultimately, replacing electric heaters with newer heating options presents an opportunity not only for increased comfort and reduced energy bills but also for playing an active role in reducing humanity's carbon footprint. As technology continues to advance rapidly in this sector, staying informed about available innovations will empower consumers to make choices that are not only beneficial today but also sustainable for future generations.

Retrofitting legacy systems for energy efficiency

 Retrofitting legacy systems for energy efficiency

Retrofitting legacy systems for energy efficiency is an increasingly critical task as businesses and organizations seek sustainable solutions in a world that is rapidly moving towards greener practices.. The future trends and innovations in this area are not just about updating old systems but redefining how we think about energy usage, sustainability, and technology integration. The first major trend in system retrofits is the integration of smart technologies.

Posted by on 2024-12-28

Upgrading ductwork in mobile homes for better performance

 Upgrading ductwork in mobile homes for better performance

Upgrading ductwork in mobile homes can significantly enhance performance, comfort, and energy efficiency.. However, to truly maximize the benefits of such an upgrade, it's crucial to focus on maintenance practices that prolong the life of your ductwork.

Posted by on 2024-12-28

Installation Process: Connecting a WiFi Thermostat to a Mobile Home HVAC System

As the world continues to grapple with the effects of climate change and seeks more sustainable living solutions, the quest for efficient and eco-friendly heating alternatives becomes increasingly urgent. One promising option that has emerged is exploring heat pumps as a viable alternative for mobile homes, particularly in efforts to replace traditional electric heaters. Heat pumps offer an innovative approach to home heating by utilizing technology that can significantly reduce energy consumption and environmental impact.


Mobile homes, often characterized by their limited insulation and space constraints, have traditionally relied on electric heaters for warmth. While effective in providing immediate heat, these systems are notorious for high energy consumption and soaring utility bills. In contrast, heat pumps operate on a fundamentally different principle-transferring heat rather than generating it directly-which can lead to substantial energy savings.


The primary function of a heat pump is to extract existing heat from the outside environment-even in colder temperatures-and bring it indoors. This process is achieved through the use of refrigerant cycles that absorb ambient heat and compress it into a higher temperature before releasing it inside the home. During warmer months, this cycle can be reversed to provide air conditioning, making heat pumps a versatile year-round solution.


One of the most appealing aspects of installing heat pumps in mobile homes is their potential for improved efficiency. Modern models boast impressive coefficients of performance (COP), meaning they generate multiple units of heating or cooling per unit of electricity consumed. This efficiency translates into lower energy usage and reduced greenhouse gas emissions compared to conventional electric heaters.


Moreover, advances in technology have led to the development of ductless mini-split systems that are well-suited for mobile homes' unique spatial challenges. These systems eliminate the need for extensive ductwork, thus simplifying installation while maintaining effective climate control within compact living areas.


However, transitioning from electric heaters to heat pumps does come with its own set of considerations. Initial installation costs can be higher; therefore, prospective adopters must weigh long-term savings against upfront expenses. Additionally, geographic location plays a role in determining effectiveness-regions with extreme cold may require supplementary heating sources during harsh winters.


Despite these challenges, numerous incentives are available to encourage homeowners toward adopting greener technologies like heat pumps. Government programs offering rebates or tax credits can help offset initial costs while promoting widespread adoption among communities seeking sustainable alternatives.


In conclusion, exploring heat pumps as a viable alternative for mobile homes represents an exciting opportunity within broader efforts aimed at evaluating newer options replacing traditional electric heaters. By embracing this technology's promise-reduced energy consumption coupled with environmental benefits-mobile home residents stand poised not only save money but also contribute positively toward our planet's future sustainability endeavors. As awareness grows surrounding both ecological responsibility economic prudence alike so too will demand likely increase thus further solidifying place among preferred heating solutions today tomorrow alike .

Installation Process: Connecting a WiFi Thermostat to a Mobile Home HVAC System

Setting Up Remote Access: Configuring Apps and Devices for Control

In recent years, the demand for energy-efficient heating solutions has become increasingly urgent as both households and industries seek to reduce their carbon footprints and lower energy costs. Solar-powered heating solutions have emerged as a promising alternative, offering a sustainable path forward in the quest to replace traditional electric heaters. By harnessing the power of the sun, these systems not only provide a renewable source of energy but also significantly enhance overall energy efficiency.


The primary advantage of solar-powered heating systems lies in their utilization of an abundant and inexhaustible resource: sunlight. Unlike electric heaters that rely on fossil fuels or non-renewable electricity sources, solar thermal technology captures solar radiation to generate heat. This process is both clean and efficient, reducing greenhouse gas emissions and minimizing environmental impact. Moreover, once installed, solar heating systems typically require minimal maintenance and incur low operational costs compared to their electric counterparts.


One of the most significant contributions of solar-powered heating solutions is their ability to reduce reliance on grid electricity. During peak sunshine hours, these systems can operate independently by using stored thermal energy or through direct conversion from solar panels. This reduction in dependency not only alleviates pressure on electrical grids but also helps prevent price spikes associated with high electricity demand during cold seasons.


Furthermore, integrating solar heating with existing infrastructure can be relatively straightforward. Hybrid systems allow for seamless transition between solar energy and conventional power sources when necessary. Such adaptability ensures continuous availability of heat even in less sunny climates or during prolonged cloudy periods.


In addition to individual household benefits, widespread adoption of solar-powered heating solutions could contribute significantly to national energy goals by decreasing overall consumption levels and promoting sustainable practices at larger scales. Governments globally are already recognizing this potential; many have implemented incentives like tax rebates or subsidies aimed at encouraging homeowners and businesses alike towards embracing renewable technologies.


However, despite these advantages there remain challenges that need addressing before full-scale implementation becomes feasible everywhere-such as initial installation costs which may deter some consumers from making upfront investments required for setting up new systems altogether-but ongoing technological advancements promise reductions here too over time alongside increased efficiency rates themselves ultimately leading more people towards considering adopting them eventually regardless given enough support initially provided until then perhaps?


In conclusion then: transitioning away from electric heaters toward greener alternatives like those powered via our nearest star offers numerous opportunities worth exploring further if we hope achieve greater sustainability moving forwards together!

Energy Efficiency and Cost Savings with Remote Access in Mobile Homes

In recent years, the quest for energy-efficient and cost-effective heating solutions has led to significant innovations in radiant floor heating systems, particularly tailored for mobile home applications. As mobile homes often face unique challenges due to their construction and space limitations, exploring newer options to replace traditional electric heaters has become a focal point for both manufacturers and homeowners seeking enhanced comfort without exorbitant energy bills.


Radiant floor heating systems have emerged as an appealing alternative, harnessing the principle of heat transfer through radiation. By warming floors directly, these systems provide even heat distribution throughout the living space. This method contrasts sharply with conventional electric heaters that often create pockets of warmth near the unit while leaving other areas cool. The uniformity offered by radiant floor heating not only enhances comfort but also promotes better energy efficiency.


Recent innovations have focused on making radiant floor heating more adaptable for mobile home environments. One notable development is the introduction of ultra-thin electric mats that can be installed beneath various flooring types such as laminate, vinyl, or tile-all commonly found in mobile homes. These low-profile mats are designed to minimize disruption during installation while maximizing heat output. Moreover, they can be customized to fit specific room dimensions, allowing for precision in both coverage and energy usage.


Another advancement is the integration of smart technology with radiant floor systems. Smart thermostats and sensors now allow homeowners to monitor and control their heating remotely via smartphone apps. This capability not only adds convenience but also encourages more responsible energy consumption by enabling users to adjust settings based on real-time data and personal schedules.


Additionally, hydronic radiant floor systems have gained traction as a viable option for those looking to further reduce electricity dependency. These systems circulate warm water through a network of pipes under the flooring surface. While traditionally associated with larger installations due to their complexity, recent engineering breakthroughs now allow compact designs suitable for mobile homes. By utilizing existing water heater infrastructure or integrating with solar water heating solutions, hydronic systems offer an environmentally friendly alternative with potentially lower operational costs over time.


Despite these promising advancements, it is essential for potential adopters to conduct thorough evaluations before transitioning from electric heaters to radiant floor systems. Factors such as initial installation costs-which can be higher than conventional methods-must be weighed against long-term savings on utility bills and increased home value due to improved energy efficiency standards.


In conclusion, innovations in radiant floor heating present compelling opportunities for upgrading mobile home climate control beyond traditional electric heaters. By embracing these newer technologies-characterized by enhanced adaptability, smart integrations, and eco-friendly options-homeowners can achieve greater comfort levels while contributing positively towards sustainable living practices. As research continues and technology evolves further, it is expected that these solutions will become increasingly accessible and popular within the mobile home sector.

Troubleshooting Common Issues with WiFi Thermostat Integration

In recent years, the quest for sustainable living has spurred a growing interest in alternative heating solutions for mobile homes. As environmental concerns and energy costs rise, many are reconsidering the traditional electric heaters that have long been the staple of mobile home heating systems. This essay explores several case studies where successful implementations of alternative heating options have not only improved efficiency but also enhanced comfort and reduced environmental footprints.


One of the most notable examples comes from a small community in Oregon that embraced solar thermal energy as a primary heating source. The project initially faced skepticism due to the region's reputation for overcast skies; however, by utilizing advanced solar collectors and efficient thermal storage systems, residents were able to harness enough solar energy even during cloudy periods. This system drastically reduced electricity consumption and provided consistent warmth throughout the winter months. Furthermore, the community reported significant savings on their utility bills, demonstrating both economic and environmental benefits.


Another compelling case study is found in Vermont, where a pilot program introduced biomass pellet stoves into several mobile homes. Biomass stoves utilize renewable resources such as wood pellets or chips and are known for their high efficiency and low emissions. Participants in this program experienced a substantial decrease in their reliance on electric heaters while enjoying enhanced indoor air quality due to cleaner combustion processes. The success of this initiative prompted further investments into local biomass production facilities, thereby supporting regional economies.


A third example highlights an innovative approach taken by a group of engineers and residents in Northern Michigan who designed and installed geothermal heat pump systems specifically tailored for mobile homes. These systems extract heat from the ground during winter months and can be reversed to provide cooling during summer. While initial installation costs were higher compared to other alternatives, the long-term savings on energy expenditures proved compelling. Residents noted not only cost reductions but also increased property values as these systems became more desirable features.


Each of these case studies underscores an important lesson: successful implementation of alternative heating solutions requires careful consideration of local conditions and community involvement. Tailoring solutions to fit specific needs-whether it's leveraging abundant natural resources like sun or biomass or investing in cutting-edge technology like geothermal-can lead to transformative outcomes.


In conclusion, replacing traditional electric heaters with alternative options in mobile homes presents a viable pathway towards sustainable living. By examining these case studies, it becomes evident that diverse approaches can yield significant benefits across different regions. As more communities adopt these innovative solutions, they pave the way for broader adoption of sustainable practices that contribute positively to both local environments and global climate goals.

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

[edit]
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

[edit]

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

[edit]
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

[edit]

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)

[edit]

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

[edit]
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

[edit]
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

[edit]

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

[edit]
  • 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

[edit]
  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.
  11. ^ Morby, Aaron (30 June 2023). "Ilke Homes falls into administration". Construction Enquirer. Retrieved 14 March 2024.
  12. ^ Prior, Grant (25 August 2023). "Ilke Homes went under owing £320m". Construction Enquirer. Retrieved 14 March 2024.
  13. ^ Willmore, James (14 February 2024). "Homes England to lose most of £68.8m it is owed from Ilke Homes following collapse". Inside Housing. Retrieved 14 March 2024.
  14. ^ Dale, Sharon (11 May 2020). "Head of Legal & General modular homes factory reveals plans for its future". Yorkshire Post. Retrieved 20 March 2024.
  15. ^ Morby, Aaron (30 November 2020). "L&G modular homes losses exceed £100m". Construction Enquirer. Retrieved 20 March 2024.
  16. ^ Morby, Aaron (3 October 2022). "L&G modular homes amassed loss deepens to £174m". Construction Enquirer. Retrieved 20 March 2024.
  17. ^ Prior, Grant (4 May 2023). "L&G halts production at modular homes factory". Construction Enquirer. Retrieved 20 March 2024.
  18. ^ Kollewe, Julia (4 May 2023). "Legal & General halts new production at modular homes factory near Leeds". The Guardian.
  19. ^ Morby, Aaron (6 November 2023). "L&G modular homes foray amassed £295m of losses". Construction Enquirer. Retrieved 20 March 2024.
  20. ^ fab, ukporta (19 August 2020). "prefabricated structures". ukportaprefab. Retrieved 4 September 2020.
  21. ^ "Factory-Built Construction and the American Homebuyer: Perceptions and Opportunities" (PDF). Huduser.gov. p. 9. Retrieved 2017-09-10.
  22. ^ Solutions, Dryside Property – Jennifer Mitchell and Magic Web. "Mobile homes vs Manufactured homes vs Modular homes". Drysideproperty.com. Retrieved 2018-03-09.
  23. ^ "HCD Manufactured and Mobile Homes". Hcd.ca.gov.
  24. ^ Métodos modernos de construcción (MMC): Fabricación modular. Upv.es. 2020-10-02 Retrieved 2022-09-08
  25. ^ A guide to the latest modular building construction materials. Hydrodiseno.com. 2021-12-14 Retrieved 2022-09-05
  26. ^ Construcción modular en hormigón: una tendencia al alza (PDF). Andece.org. p. 53. Retrieved 2022-07-06
  27. ^ "Prefabricated Housing Module Advances Wood Research at the University of British Columbia | 2017-05-15T00:00:00 | Perkins + Will News". Archived from the original on 2019-03-31. Retrieved 2019-03-31.
  28. ^ "HUD Financing Manufactured (Mobile) Homes". Portal.hud.gov. Archived from the original on 2016-05-03. Retrieved 2016-05-03.
  29. ^ "Australian Government modular home regulations". Austlii.edu.au. Retrieved 2007-10-21.
  30. ^ "Building Codes for Modular Homes". Modularhomesnetwork.com. Retrieved 2010-08-06.
  31. ^ "Disruptive Development: Modular Manufacturing In Multifamily Housing" (PDF). p. 35. Retrieved 10 September 2017.
  32. ^ "FIA 22, Mitigation Assessment Team Report: Hurricane Andrew in Florida (1993)". Fema.gov.
  33. ^ Bouwens, M., Kostakis, V., & Pazaitis, A. 2019. The Commons Manifesto. University of Westminster Press, London, pg. 24
  34. ^ Bouwens, M., Kostakis, V., & Pazaitis, A. 2019. The Commons Manifesto. University of Westminster Press, London, pg. 25
  35. ^ "Thomas Lommée & Christiane Hoegner - Autarkytecture | z33". Archived from the original on 2014-12-31. Retrieved 2015-01-01.
  36. ^ "Modular Building Institute". Modular.org.
  37. ^ "The Steel Construction Institute (SCI) UK Global Steel Expertise". Steel-sci.com.

34 - "Volumetric modular construction trend gaining groun d". https://www.aa.com.tr/en/corporate-news/volumetric-modular-construction-trend-gaining-ground/2357158 06.09.2021

 

Things To Do in Arapahoe County

Photo

Cherry Creek State Park

4.6 (9044)
Photo

Clock Tower Tours

4.1 (7)
Photo

Plains Conservation Center (Visitor Center)

4.6 (393)
Photo

Wings Over the Rockies Air & Space Museum

4.7 (5324)
Photo

Blue Grama Grass Park

4.4 (117)
Photo

Molly Brown House Museum

4.7 (2528)

Driving Directions in Arapahoe County

Driving Directions From Regal River Point to Royal Supply South
Driving Directions From King Soopers to Royal Supply South
Driving Directions From The Home Depot to Royal Supply South
Driving Directions From VRCC Veterinary Specialty and Emergency Hospital to Royal Supply South
Driving Directions From Tandy Leather South Denver - 151 to Royal Supply South

https://www.google.com/maps/dir/Lowe%27s+Home+Improvement/Royal+Supply+South/@39.62581,-105.013478,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJMbvTxDmAbIcRm_hEdvPzqUA!2m2!1d-105.013478!2d39.62581!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e0

https://www.google.com/maps/dir/Walgreens/Royal+Supply+South/@39.6246603,-105.0200245,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJ8zuXzzqAbIcRPsc0NxgBh7g!2m2!1d-105.0200245!2d39.6246603!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e2

https://www.google.com/maps/dir/St.+Nicks+Christmas+and+Collectibles/Royal+Supply+South/@39.6225114,-105.0155267,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJ0alPujCAbIcRjcf_zxYfiqw!2m2!1d-105.0155267!2d39.6225114!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e1

https://www.google.com/maps/dir/The+Home+Depot/Royal+Supply+South/@39.6230256,-105.0244932,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJuUU_myWAbIcRHSU8v3hT8ck!2m2!1d-105.0244932!2d39.6230256!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e3

https://www.google.com/maps/dir/King+Soopers/Royal+Supply+South/@39.6545686,-105.0511676,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sChIJUwi2ThmAa4cRIyDrqukys2c!2m2!1d-105.0511676!2d39.6545686!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e0

Driving Directions From Meow Wolf Denver | Convergence Station to Royal Supply South
Driving Directions From Denver Zoo to Royal Supply South
Driving Directions From Cherry Creek Dam to Royal Supply South
Driving Directions From History Colorado Center to Royal Supply South
Driving Directions From Four Mile Historic Park to Royal Supply South
Driving Directions From Cherry Creek Valley Ecological Park to Royal Supply South

https://www.google.com/maps/dir/Cherry+Creek+Dam/Royal+Supply+South/@39.6513192,-104.8547796,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.8547796!2d39.6513192!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e0

https://www.google.com/maps/dir/Big+Blue+Bear/Royal+Supply+South/@39.7436238,-104.9952912,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.9952912!2d39.7436238!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e2

https://www.google.com/maps/dir/Aurora+Reservoir/Royal+Supply+South/@39.6108004,-104.6771117,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.6771117!2d39.6108004!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e1

https://www.google.com/maps/dir/Aurora+History+Museum/Royal+Supply+South/@39.711213,-104.813431,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.813431!2d39.711213!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e3

https://www.google.com/maps/dir/Molly+Brown+House+Museum/Royal+Supply+South/@39.7375016,-104.9808374,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.9808374!2d39.7375016!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e0

https://www.google.com/maps/dir/Museum+of+Outdoor+Arts/Royal+Supply+South/@39.6020522,-104.8932659,14z/data=!3m1!4b1!4m14!4m13!1m5!1m1!1sunknown!2m2!1d-104.8932659!2d39.6020522!1m5!1m1!1sChIJ06br1RqAbIcRAjyWXdlXZaw!2m2!1d-105.0233105!2d39.6435918!3e2

Reviews for Royal Supply South

View GBP

Check our other pages :

Frequently Asked Questions

Energy-efficient alternatives to electric heaters include heat pumps, which can provide both heating and cooling, ductless mini-split systems that offer flexible installation and zoning options, and high-efficiency gas furnaces if natural gas is available.
Generally, newer heating options like heat pumps and ductless mini-splits have lower operating costs compared to traditional electric heaters due to their higher efficiency. Heat pumps can be up to 50% more efficient than baseboard or space heaters, leading to significant savings on energy bills over time.
Yes, considerations include ensuring structural support for outdoor units (in the case of heat pumps), proper insulation and sealing of the mobile home to maximize efficiency, potential need for electrical upgrades, and selecting appropriately sized equipment due to typically smaller living spaces in mobile homes.